PROTOCOL Translator MODBus User Manual

PROTOCOL Translator MODBus User Manual

Protocol Translator MODBus User Manual Page 2 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual Revision Table Rev Detail of Change 01 Initial issue 02 Format and style update. This document is in support of the Multitrode Translator. Version 1.0.9 Revision 02 This document is valid for MultiTrode Translator firmware version 1.09 or newer. Multitrode reserves the right to update this document without notification. MULTITRODE and MULTISMART are registered trademarks of MultiTrode Pty Ltd in Australia, USA and many countries worldwide. PUMPVIEW is a registered trademark of MultiTrode Pty Ltd in Australia. Design registration is pending for the MultiSmart Pump Controller Remote and Base Modules in Australia, USA and many countries worldwide. Patents pending in Australia, USA and many countries worldwide. 2007 MultiTrode Pty Ltd. This publication is protected by copyright. No part of this publication may be reproduced by any process, electronic or otherwise, without the express written permission of MultiTrode Pty Ltd. Although every attempt has been made to ensure the correctness of the information contained herein, no liability is accepted by Multitrode or its staff for any errata contained. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 3 of 28

Protocol Translator MODBus User Manual Page 4 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual Contents 1 Introduction...7 1.1 The MultiTrode Translator...7 2 Quick Installation Guide...8 3 MODBus Guide...10 3.1 Introducing MODBus Protocol...10 3.2 The Query-Response Cycle...10 3.3 The Query...10 3.4 The Response...11 3.4.1 RTU Mode...11 3.4.2 RTU Framing...11 3.4.3 How the Address Field is Handled...12 3.4.4 How the Function Field is Handled...12 3.4.5 Contents of the Data Field...13 3.4.6 Cyclic Redundancy Check [CRC]...13 3.5 MultiTrode Translator Interfaces...14 3.5.1 MultiTrode MonitorPro...14 3.5.2 MODBus Interface...14 3.5.3 Locally Generated Points...15 3.6 MODBus Commands...16 3.6.1 01 Read Coil Status...16 3.6.2 02 Read Input Status...17 3.6.3 03 Read Holding Registers...18 3.6.4 04 Read Input Registers...19 3.6.5 05 Force Single Coil...19 3.6.6 06 Preset Single Register...20 3.6.7 08 Diagnostics Function...21 3.6.8 15 (0F Hex) Force Multiple Coils...22 3.6.9 16 (10 Hex) Preset Multiple Registers...23 3.7 Mirror Input Status Mode...25 3.7.1 Configuring the MultiTrode Translator for Mirror Mode...25 4 Specifications...26 5 Full List of MODBUS Points...27 Figures Figure 1 Overview Connection Diagram...8 Figure 2 MODBus query cycle...10 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 5 of 28

Protocol Translator MODBus User Manual Page 6 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 1 Introduction Congratulations on the purchase of the advanced MultiTrode Translator. In order to gain maximum benefit from the use of the MultiTrode Translator it is recommended that a good understanding is developed of MODBus protocol. It is not the intention of this manual to cover this protocol in detail but only to explain its basic operation to assist with the functional installation of the unit. 1.1 The MultiTrode Translator The MultiTrode Translator gathers information from a MultiTrode MonitorPRO or Remote Reservoir Monitor by issuing continuous assembled status requests. This information is mapped to and stored in a pair of native databases (one for MODBus, one for DNP3) which can then be accessed by a Master using the appropriate protocol. Local inputs on the MultiTrode Translator are also placed into these databases. The Master may request control operations and/or point writes to control the MultiTrode device via the MultiTrode Translator. Control operations that relate to MultiTrode devices will be acknowledged immediately by the MultiTrode Translator and the appropriate MultiTrode command issued at the earliest possible time. The success or failure of a control operation is determined by subsequently reading status information for the relevant point. The MonitorPRO is a state-of-the-art pump station supervisor, which has been specifically designed to provide a high level of motor protection, capable of monitoring and protecting pumps by measuring pump currents and voltages. The MonitorPRO, in conjunction with the MT2/3PC Pump Controllers have many desirable features. Together they provide a complete pump station management system, which is not only more efficient than conventional systems, but also provides a smaller, more-cost-effective and more reliable solution. The MultiTrode Pump Controller (MTxPC) is an advanced microprocessor-based pump controller designed to control two or three pumps, depending on the model chosen. It is specifically designed for use in water and sewage pumping stations and provides automatic level control, pump alternation, pump protection logic and level alarms. These two products form the Remote Terminal Unit MultiTrode Translator, which is connected to a Master SCADA system via land line or radio. The existing SCADA system works by using MultiTrode s proprietary protocol working into special SCADA software. However, via the MultiTrode Translator all these MultiTrode points can be accessed via the MODBus protocol. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 7 of 28

Protocol Translator MODBus User Manual 2 Quick Installation Guide As the default setting of the MultiTrode Translator will meet most applications needs, the only necessity is to set the site address and desired protocol option of the unit to allow polling of the remote site by the SCADA or PLC controlling system. Connect the MultiTrode Translator as per diagram below. 10-30VDC Power Supply MonitorPro Protocol Translator Radio PC Figure 1 Overview Connection Diagram Using HyperTerminal or some similar terminal emulation program, send the word login to the MultiTrode Translator using [MB]Com. 2. The word login should be preceded with a 1 second silent period. The login command is lower case and strictly login without an enter. Default communication settings should be 9600bps, 1 Start bit, no Parity and 2 Stop bits. The MultiTrode Translator will display the Main Menu to HyperTerminal. From the Main Menu select option 1. MultiTrode Translator (MultiTrode - DNP / MODBus converter) v1.00. Main Menu. 1) MultiTrode Translator Address [1] Change the MultiTrode Translator s address to the address used by the Master to communicate with it. Page 8 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual Again from the Main Menu select option 2 MultiTrode Translator (MultiTrode - DNP / MODBus converter) v1.00. Main Menu. 1) MultiTrode Translator Address [1] 2) Configure COM ports. By selecting option 1) Next port, the com. Port desired for DNP3 operation can be configured. COM2 (RS-232) Port Configuration. 1) Next port 2) Protocol [MODBus Slave] 3) Baud rate [9600] Select option 2) Protocol to set desired protocol. Press Esc twice and close down HyperTerminal. Notice that the MT RX, MT TX, LEDs are polling. The MultiTrode units should now be available via the MultiTrode Translator by the Central Monitoring Facility [CMF]. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 9 of 28

Protocol Translator MODBus User Manual 3 MODBus Guide 3.1 Introducing MODBus Protocol The common language used by most controllers is the MODBus protocol. This protocol defines a message structure that controllers will recognize and use, regardless of the type of networks over which they communicate. It describes the process a controller uses to request access to another device, how it will respond to requests from the other devices, and how errors will be detected and reported. It establishes a common format for the layout and contents of message fields. The MODBus protocol provides an international standard that all controllers can use for passing messages. During communications on a MODBus network, the protocol determines how each controller will know its device address, recognize a message addressed to it, determine the kind of action to be taken, and extract any data or other information contained in the message. If a reply is required, the controller will construct the reply message and send it using MODBus protocol. The following sections describe the MODBus commands as used in the MultiTrode Translator. Commands not listed are not supported by the MultiTrode Translator and if requested, an error message will be returned to the Master. 3.2 The Query-Response Cycle RTU Device Address Function Code QUERY Eight Bit Data Bytes MASTER RTU CRC Error Check RTU Device Address Function Code SLAVE RTU Eight Bit Data Bytes RESPONSE CRC Error Check Figure 2 MODBus query cycle 3.3 The Query The function code in the query tells the addressed Slave device what kind of action to perform. The data bytes contain any additional information that the Slave will need to perform the function. For example, function code 03 will query the Slave to read holding registers and respond with their contents. The data field must contain the information which tells the Slave at what register to start, and how many registers to read. The error check field provides a method for the Slave to validate the integrity of the message contents. Page 10 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.4 The Response If the Slave makes a normal response, the function code in that response is an echo of the function code in the query the data bytes contain the data collected by the Slave, such as register values or status. If an error occurs, the function code is modified to indicate that the response is an error response, and the data bytes contain a code that describes the error. The error check field allows the Master to validate the integrity of the message. 3.4.1 RTU Mode When controllers are set up to communicate on a MODBus network using RTU (Remote Terminal Unit) mode, each eight-bit byte in a message contains two four-bit hexadecimal characters. The main advantage of this mode is that its greater character density allows better data throughput than ASCII for the same baud rate. Each message must be transmitted in a continuous stream. 3.4.1.1 Coding System Eight-bit binary, hexadecimal 0--9, A--F Two hexadecimal characters contained in each eight-bit field of the message 3.4.1.2 Bits per Byte 1 start bit 8 data bits, least significant bit sent first 1 bit for even/odd parity no bit for no parity 1 stop bit if parity is used 2 bits if no parity 3.4.1.3 Error Check Field Cyclical Redundancy Check (CRC) 3.4.2 RTU Framing In RTU mode, messages start with a silent interval period of at least 3.5 characters. This is most easily implemented as a multiple of character times at the baud rate that is being used on the network (shown as T1-T2-T3-T4 in the figure below). The first field then transmitted is the device address. The allowable characters transmitted for all fields are hexadecimal 0--9, A--F Networked devices monitor the network bus continuously, including during the silent intervals. When the first field (the address field) is received, each device decodes it to find out if it is the addressed device. Following the last transmitted character, a similar interval of at least a period of 3.5 characters marks the end of the message. A new message can begin after this interval. The entire message frame must be transmitted as a continuous stream. If a silent interval period of more than 1.6 characters occurs before completion of the frame, the receiving device flushes the incomplete message and assumes that the next byte will be the address field of a new message. Similarly, if a new message begins earlier than a period of 8.6 characters following a previous message, the receiving device will consider it a continuation of the previous message. This will set an error, as the value in the final CRC field will not be valid for the combined messages. A typical message frame is shown below. START Address Function Data CRC Check END T1-T2-T3-T4 8-bits 8-bits n x 8-bits 16-bits T1-T2-T3-T4 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 11 of 28

Protocol Translator MODBus User Manual 3.4.3 How the Address Field is Handled The address field of a message frame contains 1 byte or 8-bits for MODBus RTU protocol. Valid Slave device addresses are in the range of 0--247 decimal. The individual Slave devices are assigned addresses in the range of 1--247. A Master addresses a Slave by placing the Slave address in the address field of the message. When the Slave sends it s response, it places it s own address in this address field of the response to let the Master know which Slave is responding. Address 0 is used for the broadcast address, which all Slave devices recognize. When MODBus protocol is used on higher level networks, broadcasts may not be allowed or may be replaced by other methods. 3.4.4 How the Function Field is Handled The function code field of a message frame contains 1 byte or eight bits for MODBus RTU protocol. Valid codes are in the range of 1-- 255 decimal. Of these 255 possible function codes only 9 codes are used by the MultiTrode Translator. When a message is sent from a Master to a Slave device the function code field tells the Slave what kind of action to perform. Examples are: read the ON/OFF states of a group of discrete coils or inputs, read the data contents of a group of registers or write to designated coils or registers. When the Slave responds to the Master, it uses the function code field to indicate either a normal (errorfree) response or that some kind of error occurred (called an exception response). For a normal response, the Slave simply echoes the original function code. For an exception response, the Slave returns a code that is equivalent to the original function code with it s most significant bit set to a logic 1. For example, a message from Master to Slave to read a group of holding registers would have the following function code: 0000 0011 (Hexadecimal 03) If the Slave device takes the requested action without error, it returns the same code in it s response. If an exception occurs, it returns: 1000 0011 (Hexadecimal 83) In addition to it s modification of the function code for an exception response, the Slave places a unique code into the data field of the response message. This tells the Master what kind of error occurred, or the reason for the exception. There are several error codes defined in MODBus but the MultiTrode Translator only returns two. These are: 01-02 - Illegal function (function code not recognised or supported) Illegal data address (referencing a point number that does not exist) The Master device s application program has the responsibility of handling exception responses. Typical processes are to post subsequent retries of the message, to try diagnostic messages to the Slave, and to notify operators. Page 12 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.4.5 Contents of the Data Field The data field is constructed using sets of two hexadecimal digits, in the range of 00 to FF hexadecimal. These can be made from a pair of ASCII characters, or from one RTU character, according to the network s serial transmission mode. The data field of messages sent from a Master to Slave devices contains additional information, which the Slave must use to take the action defined by the function code. This can include items like discrete and register addresses, the quantity of items to be handled, and the count of actual data bytes in the field. For example, if the Master requests a Slave to read a group of holding registers (function code 03), the data field specifies the starting register and how many registers are to be read. If the Master writes to a group of registers in the Slave (function code 11 hexadecimal), the data field specifies the starting register, how many registers to write, the count of data bytes to follow in the data field, and the data to be written into the registers. If no error occurs, the data field of a response from a Slave to a Master contains the data requested. If an error occurs, the field contains an exception code that the Master application can use to determine the next action to be taken. The data field can be non-existent (of zero length) in certain kinds of messages. 3.4.6 Cyclic Redundancy Check [CRC] In RTU mode, messages include an error-checking field that is based on a CRC method. The CRC field checks the contents of the entire message. It is applied regardless of any parity check method used for the individual characters of the message. The CRC field is two bytes, containing a 16-bit binary value. The CRC value is calculated by the transmitting device, which appends the CRC to the message. The receiving device recalculates a CRC during receipt of the message, and compares the calculated value to the actual value it received in the CRC field. If the two values are not equal, an error result is assumed and corrective action may be taken. When the CRC is appended to the message, the low-order byte is appended first, followed by the highorder byte. The CRC generation algorithm is given in the table below. Step 1 Step 2 Step 3 Step 4 Step 5 Step 6 Step 7 Load a 16-bit register with FFFF hex (all l s). Call this the CRC register. Exclusive OR the first eight-bit byte of the message with the low order byte of the 16-bit CRC register, putting the result in the CRC register. Shift the CRC register one bit to the right (toward the LSB), zero-filling the MSB. Extract and examine the LSB. If the LSB is 0, repeat Step 3 (another shift). If the LSB is 1, Exclusive OR the CRC register with the polynomial value A001 hex (1010 0000 0000 0001). Repeat Steps 3 and 4 until eight shifts have been performed. When this is done, a complete eight-bit byte will have been processed. Repeat Steps 2... 5 for the next eight-bit byte of the message. Continue doing this until all bytes have been processed. The final content of the CRC register is the CRC value. When the CRC is placed into the message, it s upper and lower bytes must be swapped. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 13 of 28

Protocol Translator MODBus User Manual 3.5 MultiTrode Translator Interfaces This section outlines the design of the MultiTrode Translator firmware. The MultiTrode Translator acts as a protocol converter for MultiTrode MonitorPro devices to MODBus by maintaining a database image in MODBus format. This database is accessible to the MODBus Masters through RS232 and/or FSK ports, using MODBus RTU function set. 3.5.1 MultiTrode MonitorPro Connection to the MultiTrode MonitorPRO is via a dedicated RS-232 port. All information is retrieved using the Assembled Status Request Command. Once collected, this information is separated into four data types commonly used by MODBus for storage: Coils: Input Status: Holding Registers: Read/write single bit values (digital outputs) (0xxxx references) Read only single bit values (digital inputs) (1xxxx references) Read/write 16-bit values (analog outputs, configuration, modifiable registers) (4xxxx references) Input Registers: Read only 16-bit values (analog inputs, non-modifiable registers) (3xxxx references) When a MODBus coil or holding register is modified, the associated MultiTrode command is sent to the MonitorPRO using MultiTrode protocol. The status of some of these coils and holding registers is available in an Assembled Status Response. For MODBus points where status is not available, the last written value is returned instead. 3.5.2 MODBus Interface MODBus access is available via the second RS-232 port or the FSK port. The device will behave as a Slave and service the following Master function requests using the MODBus RTU protocol: Function Description 01 Read Coil Status 02 Read Input Status 03 Read Holding Registers 04 Read Input Registers 05 Force Single Coil 06 Preset Single Register 15 Force Multiple Coils 16 Force Multiple Registers 08 Diagnostic Loop Back Any other function codes in a request will result in a code 01 (Illegal Function) response. There is a separate MODBus driver installed on each com port (except the one assigned to the Monitor PRO) functioning independently allowing simultaneous access via multiple ports. Page 14 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.5.3 Locally Generated Points The MultiTrode Translator generates some of its own data via its analogue and digital inputs. These points are depicted in the MODBus Point Map: 3.5.3.1 Digital Inputs Six digital inputs are available and appear as Input Status points (948 to 953). These inputs are individually configurable as normal or latched. 3.5.3.2 Normal Mode: In normal mode the Input Status Point reflects the instantaneous value of the digital input. 3.5.3.3 Latched Mode: In latched mode, a transition from 0 to 1 sets the Input Status Point to 1. A transition from 1 to 0 has no effect and the Input Status Point remains in the 1 state. As this Input Status Point is latched it needs to be reset before it can resume it function. Each input has an associated clear latch Output Coil. Writing a 1 to this coil sets the Input Status Point to the instantaneous value of the digital input. Additionally, each digital input has an associated 32-bit accumulator that occupies a pair of holding registers (16 to 27). Writing zero to both of the holding registers of the pair will reset the accumulator. 3.5.3.4 Analogue Inputs Two analogue inputs appear as input registers. Each analogue input has an associated 16-bit byte that occupies an input registers (302 & 303). The values returned are pre-scaled. The pre-scaling of the analog inputs is done in the MultiTrode Translator Configuration Menu. See the MultiTrode Translator Installation Manual for further details on how to set up the pre-scaling. 3.5.3.5 MultiTrode Translator status Loss of communication between the MultiTrode Translator and MultiTrode MonitorPRO is reflected as a 1 in an Input Status Point 956. A stale data indicator is available as an Input Status Point 957. This is cleared whenever new information arrives from the MonitorPRO. A timer is also started at this point and runs for a configurable period. When it expires, the stale data indicator is set. See the MultiTrode Translator Installation Manual for further details on setting the stale data timer period. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 15 of 28

Protocol Translator MODBus User Manual 3.6 MODBus Commands 3.6.1 01 Read Coil Status Reads the ON/OFF status of discrete outputs coils (0xxxx references) in the Slave. Broadcast is not supported. When a read request is received the data is retrieved immediately from the MultiTrode Translator s database and returned to the Master. 3.6.1.1 Query The query message specifies the starting coil and quantity of coils to be read. Coils are addressed starting at zero, i.e. coils 1--16 are addressed as 0--15. Following is an example of a query to read coils 20--56 from Slave device 17: Field Name Example (Hex) Slave Address 11 Function 01 Starting Address Hi 00 Starting Address Lo 13 Number of Points Hi 00 Number of Points Lo 25 Error Check (LRC or CRC) -- 3.6.1.2 Response The coil status in the response message is packed as one coil per bit of the data field. Status is indicated as: 1 = ON; 0 = OFF. The LSB of the first data byte contains the first coil addressed in the query. The other coils follow toward the high order end of this byte, and from low order to high order in subsequent bytes. If the returned coil quantity is not a multiple of eight, the remaining bits in the final data byte will be padded with zeros (toward the high order end of the byte). The Byte Count field specifies the quantity of complete bytes of data. Following is an example of a response to the above query: Field Name Example (Hex) Slave Address 11 Function 01 Byte Count 05 Data (Coils 27--20) Data (Coils 35--28) Data (Coils 43--36) Data (Coils 51--44) Data (Coils 56--52) Error Check (LRC or CRC) -- CD 6B B2 0E 1B The status of coils 27--20 is shown as the byte value CD hex, or binary 1100 1101. Coil 27 is the MSB of this byte, and coil 20 is the LSB. Left to right, the status of coils 27--20 is ON-ON-OFF-OFF-ON-ON- OFF-ON. By convention, bits within a byte are shown with the MSB to the left, and the LSB to the right. Thus the coils in the first byte are 27--20, from left to right. The next byte has coils 35--28, left to right. As the bits are transmitted serially, they flow from LSB to MSB: 20--27, 28--35, and so on. In the last data byte, the status of coils 56--52 is shown as the byte value lb hex, or binary 0001 1011. Coil 56 is in the fourth bit position from the left, and coil 52 is the LSB of this byte. The status of coils 56-- 52 is: ON-ON-OFF-ON-ON. Note: The three remaining bits (toward the high-order end) are zero-filled. Page 16 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.6.2 02 Read Input Status Reads the ON/OFF status of discrete inputs (1xxxx references) in the Slave. Broadcast is not supported. When a read request is received the data is retrieved immediately from the MultiTrode Translator s database and returned to the Master. 3.6.2.1 Query The query message specifies the starting input and quantity of inputs to be read. Inputs are addressed starting at zero, i.e. inputs 1--16 are addressed as 0--15. Following is an example of a request to read inputs 10197--10218 from Slave device 17: Field Name Example (Hex) Slave Address 11 Function 02 Starting Address Hi 00 Starting Address Lo Number of Points Hi 00 Number of Points Lo 16 Error Check (LRC or CRC) -- C4 3.6.2.2 Response The input status in the response message is packed as one input per bit of the data field. Status is indicated as: 1 = ON; 0 = OFF. The LSB of the first data byte contains the first input addressed in the query. The other inputs follow toward the high order end of this byte, and from low order to high order in subsequent bytes. If the returned input quantity is not a multiple of eight, the remaining bits in the final data byte will be padded with zeros (toward the high-order end of the byte). The Byte Count field specifies the quantity of complete bytes of data. Following is an example of a response to the query: Field Name Example (Hex) Slave Address 11 Function 02 Byte Count 03 Data (Inputs 10204 -- 10197) Data (Inputs 10212 10205) Data (Inputs 10218 -- 10213) 35 Error Check (LRC or CRC) -- AC DB The status of inputs 10204--10197 is shown as the byte value AC hex, or binary 1010 1100. Input 10204 is the MSB of this byte, and input 10197 is the LSB. Left to right, the status of inputs 10204--10197 is ON-OFF-ON-OFF-ON-ON-OFF-OFF The status of inputs 10218--10213 is shown as the byte value 35 hex, or binary 0011 0101. Input 10218 is in the third bit position from the left, and input 10213 is the LSB. The status of inputs 10218--10213 is: ON-ON-OFF-ON-OFF-ON. Note: The two remaining bits (toward the high order end) are zero-filled. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 17 of 28

Protocol Translator MODBus User Manual 3.6.3 03 Read Holding Registers Read the binary contents of holding registers (4xxxx references) in the Slave. Broadcast is not supported. When a read request is received the data is retrieved immediately from the MultiTrode Translator s database and returned to the Master. 3.6.3.1 Query The query message specifies the starting register and quantity of registers to be read. Registers are addressed starting at zero, i.e. registers 1--16 are addressed as 0--15. Following is an example of a request to read registers 40108--40110 from Slave device 17: Field Name Example (Hex) Slave Address 11 Function 03 Starting Address Hi 00 Starting Address Lo Number of Points Hi 00 Number of Points Lo 03 Error Check (LRC or CRC) -- 6B 3.6.3.2 Response The register data in the response message are packed as two bytes per register; with the binary contents right justified within each byte. For each register, the first byte contains the high order bits and the second contains the low order bits. Following is an example of a response to the query: Field Name Example (Hex) Slave Address 11 Function 03 Byte Count 06 Data Hi (Register 40108) 02 Data Lo (Register 40108) Data Hi (Register 40109) 00 Data Lo (Register 40109) 00 Data Hi (Register 40110) 00 Data Lo (Register 40110) 64 Error Check (LRC or CRC) -- 2B The contents of register 40108 are shown as the two byte values of 02 2B hex, or 555 decimal. The contents of registers 40109--40110 are 00 00 and 00 64 hex, or 0 and 100 decimal respectively. Page 18 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.6.4 04 Read Input Registers Reads the binary content of input registers (3xxxx references) in the Slave. Broadcast is not supported. When a read request is received the data is retrieved immediately from the MultiTrode Translator s database and returned to the Master. 3.6.4.1 Query The query message specifies the starting register and quantity of registers to be read. Registers are addressed starting at zero, i.e. registers 1--16 are addressed as 0--15. Following is an example of a request to read register 30009 from Slave device 17: Field Name Example (Hex) Slave Address 11 Function 04 Starting Address Hi 00 Starting Address Lo 08 Number of Points Hi 00 Number of Points Lo 01 Error Check (LRC or CRC) -- 3.6.4.2 Response The register data in the response message are packed as two bytes per register, with the binary contents right-justified within each byte. For each register, the first byte contains the high-order bits and the second contains the low-order bits. Following is an example of a response to the query: Field Name Example (Hex) Slave Address 11 Function 04 Byte Count 02 Data Hi (Register 30009) 00 Data Lo (Register 30009) Error Check (LRC or CRC) -- 0A The contents of register 30009 are shown as the two byte values of 00 OA hex, or 10 decimal. 3.6.5 05 Force Single Coil Forces a single coil in the Slave unit (0xxxx reference) to either ON or OFF. When broadcast, the function forces the same coil reference in all attached Slaves. When a force command is received, the MultiTrode Translator will update its database and pass a command through to the MonitorPRO via the command queue. The command queue is a MultiTrode Translator buffer area to queue commands to the MonitorPRO. The MultiTrode Translator then issues this command to the MonitorPRO at the next opportunity. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 19 of 28

Protocol Translator MODBus User Manual 3.6.5.1 Query The query message specifies the coil reference to be forced. Coils are addressed starting at zero, i.e. coil 1 is addressed as 0. The requested ON/OFF state is specified by a constant in the query data field. A value of FF 00 hex requests the coil to be ON. A value of 00 00 requests it to be OFF. All other values are illegal and will not affect the coil. Following is an example of a request to force coil 173 ON in Slave device 17: Field Name Example (Hex) Slave Address 11 Function 05 Coil Address Hi 00 Coil Address Lo Force Data Hi Force Data Lo 00 Error Check (LRC or CRC) -- AC FF 3.6.5.2 Response The normal response is an echo of the query, returned after the coil state has been forced. Following is an example of a response to the query: Field Name Example (Hex) Slave Address 11 Function 05 Coil Address Hi 00 Coil Address Lo Force Data Hi Force Data Lo 00 Error Check (LRC or CRC) -- AC FF 3.6.6 06 Preset Single Register Presets a value into a single holding register (4xxxx reference) in the addressed Slave unit. When broadcast, the function presets have the same register reference in all attached Slaves. When a Preset command is received, the MultiTrode Translator will update its database and passes a command through to the MonitorPRO via the command queue. The command queue is a MultiTrode Translator buffer area to queue commands to the MonitorPRO. The MultiTrode Translator then issues this command to the MonitorPRO at the next opportunity. Page 20 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.6.6.1 Query The query message specifies the register reference to be preset. Registers are addressed starting at zero, i.e. register 1 is addressed as 0. Following is an example of a request to preset register 40002 to 00 03 hex in Slave device 17: Field Name Example (Hex) Slave Address 11 Function 06 Register Address Hi 00 Register Address Lo 01 Preset Data Hi 00 Preset Data Lo 03 Error Check (LRC or CRC) -- 3.6.6.2 Response The normal response is an echo of the query, returned after the register contents have been preset. Following is an example of a response to the query: Field Name Example (Hex) Slave Address 11 Function 06 Register Address Hi 00 Register Address Lo 01 Preset Data Hi 00 Preset Data Lo 03 Error Check (LRC or CRC) -- 3.6.7 08 Diagnostics Function MODBus function 08 provides a test for checking the communication system between the Master and Slave. Only the Return Query Data diagnostic function is supported. This means that any data sent to the Slave will be echoed to the Master without any actions. 3.6.7.1 Query Here is an example of a request to Slave device 17 to Return Query Data. This uses a sub-function code of zero (00 00 hex in the two-byte field). The data to be returned is sent in the two-byte data field (A5 37 hex). Field Name Example (Hex) Slave Address 11 Function 08 Sub-function Hi 00 Sub-function Lo 00 Data Hi Data Lo 37 Error Check (LRC or CRC) -- A5 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 21 of 28

Protocol Translator MODBus User Manual 3.6.7.2 Response The normal response to the Return Query Data request is to loop-back the same data. The function code and sub-function code are also echoed. Field Name Example (Hex) Slave Address 11 Function 08 Sub-function Hi 00 Sub-function Lo 00 Data Hi Data Lo 37 Error Check (LRC or CRC) -- A5 The data fields in responses to other kinds of queries could contain error counts or other information requested by the sub-function code. 3.6.8 15 (0F Hex) Force Multiple Coils This command forces each coil (0xxxx reference) in a sequence of coils to either ON or OFF When broadcast, the function forces the same coil references in all attached Slaves. When a force command is received, the MultiTrode Translator will update its database and sends a command through to the MonitorPRO via the command queue. The command queue is a MultiTrode Translator buffer area to queue a command to the MonitorPRO. The MultiTrode Translator then issues this command to the MonitorPRO at the next opportunity. 3.6.8.1 Query The query message specifies the coil references to be forced. Coils are addressed starting at zero, i.e. coil 1 is addressed as 0. The requested ON/OFF states are specified by contents of the query data field. A logical 1 in a bit position of the field requests the corresponding coil to be ON. A logical 0 requests it to be OFF. The following shows an example of a request to force a series of ten coils starting at coil 20 in Slave device 17. The query data contents are two bytes: CD 01 hex (1100 1101 0000 0001 binary). The binary bits correspond to the coils in the following way: Query data: 1 1 0 0 1 1 0 1 0 0 0 0 0 0 0 1 Coil: 27 26 25 24 23 22 21 20 - - - - - - 29 28 The first byte transmitted (CD hex) addresses coils 27--20, with the least significant bit addressing the lowest coil (20) in this set. Page 22 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual The next byte transmitted (01 hex) addresses coils 29 and 28, with the least significant bit addressing the lowest coil (28) in this set. Unused bits in the last data byte should be zero-filled. Field Name Example (Hex) Slave Address 11 Function Coil Address Hi 00 Coil Address Lo 13 Quantity of Coils Hi 00 Quantity of Coils Lo Byte Count 02 Force Data Hi (Coils 27 20) Force Data Hi (Coils 29 28) 01 Error Check (LRC or CRC) -- 0F 0A CD 3.6.8.2 Response The normal response returns the Slave address, function code, starting address, and quantity of coils forced. Here is an example of a response to the query shown above: Field Name Example (Hex) Slave Address 11 Function Coil Address Hi 00 Coil Address Lo 13 Quantity of Coils Hi 00 Quantity of Coils Lo Error Check (LRC or CRC) -- 0F 0A 3.6.9 16 (10 Hex) Preset Multiple Registers Presets are a sequence of values into holding registers (4xxxx references) in a Slave unit. When broadcast, the function presets are the same register references in all attached Slaves. When a Preset command is received, the MultiTrode Translator will update its database and pushes a command through to the MonitorPRO via the command queue. The command queue is a MultiTrode Translator buffer area to queue a command to the MonitorPRO. The MultiTrode Translator then issues this command to the MonitorPRO at the next opportunity. 3.6.9.1 Query The query message specifies the register references to be preset. Registers are addressed starting at zero-register, i.e. register 1 is addressed as 0. The requested preset values are specified in the query data field. Data is packed as two bytes per register. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 23 of 28

Protocol Translator MODBus User Manual Here is an example of a request to preset two registers starting at 40002 to 00 OA and 01 02 hex, in Slave device 17: Field Name Example (Hex) Slave Address 11 Function 10 Starting Address Hi 00 Starting Address Lo 01 Number of Registers Hi 00 Number of Registers Lo 02 Byte Count 04 Data Hi 00 Data Lo Data Hi 01 Data Lo 02 Error Check (LRC or CRC) -- 0A 3.6.9.2 Response The normal response returns the Slave address, function code, starting address, and quantity of registers preset. Here is an example of a response to the query shown above. Field Name Example (Hex) Slave Address 11 Function 10 Starting Address Hi 00 Starting Address Lo 01 Number of Registers Hi 00 Number of Registers Lo 02 Error Check (LRC or CRC) -- Page 24 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 3.7 Mirror Input Status Mode An option exists to allow all of the Input Status points to be mirrored to a block of Input Registers (16 status points to each register). Normally, digital inputs will appear as MODBus Input Status Points and 16-bit values as MODBus Input Registers. However, when using a SCADA or PLC Master Control system, it is sometimes desirable to minimise the tag count so as to lower licence costs. To this end the MultiTrode Translator has the ability to mirror Input Status Points into the Input Registers. By default this feature is off, but if enabled, the Input Status Points will also appear in a configurable block of Input Registers. For example if the feature is enabled and the base register set to 1000, then a single byte read of Input Register 1000 will return Digital Status Points 1 to 16. This allows 957 Digital Input Points to be read using only 59 registers. Some extra effort is needed within the Master control system to split each register into its component digital points once they have been retrieved, but this involves the use of internal tags. 3.7.1 Configuring the MultiTrode Translator for Mirror Mode For more details on configuring the MultiTrode Translator, see the MultiTrode Translator Installation Manual. The following steps give a quick configuration guide when using a terminal emulation program such as HyperTerminal. Login to the MultiTrode Translator by entering login. In the Main Menu select option 5) MODBus Parameters. In the Database Menu select option 1 MODBus Database Configuration. 1) Mirror 'Input Status' into 'Input Registers' [Yes]. 2) Base Register For Mirrored Block [312]. ESC) Back. In the Database Menu select option 2 and set the base address to a number higher than the existing number of Input Registers (311), remembering that this register number is zero based. MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 25 of 28

Protocol Translator MODBus User Manual 4 Specifications Dimensions: 118H x 45W x 135D - DIN Rail mounted Supply: Inputs: Communications Ports: Modem: Typically: 100mA at 12VDC. Minimum supply voltage 8V DC. Maximum supply voltage 38V DC. Supply is fused at 250mA (self-resetting fuse). 6 x digital: Voltage free input contacts. Cable length should not exceed 50m. ESD and EMC protected. -ve line is common ground. Maximum input frequency of 100Hz (10 milliseconds) 2 x analog: 0 to 22mA input. Input resistance 220 Ohms. 10bit ADC accuracy, linearity ±1lsb (0.025%). ADC value scaleable via configuration menu. External supply range 12 to 48VDC. ESD and EMC protected. -ve line is common ground. 2 x RS232 Asynchronous:- 9 pin male D type connector with TD, RD, RTS, CTS, DTR and DSR. 1 x Radio port to Bell 202, FSK - 1200 baud(fixed) Audio output: adjustable via trimpot to 400mVp-p Audio input sensitivity: 10-500mVp-p Squelch input: 5-30VDC common ground Press To Talk (PTT): Open drain 200mA at 40VDC Indicators: 9 status LEDS EMC: C-Tick and CE compliant AS/NZS3548 (C-Tick) CISPR 24:1997; EN55024:1998 EN61000-4-2:1995, Including Amendment A1 EN61000-4-3:1995, Including Amendment 1:1998 EN61000-4-4:1995. IEC61000-4-5:1995. IEC61000-4-6:1995, Including Amendment A1 IEC61000-4-8:1993 IEC61000-4-11:1994. Environmental: Temperature Humidity -10 C to 60 C 0 to 95% non- condensing Page 26 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Protocol Translator MODBus User Manual 5 Full List of MODBUS Points Following is the full list of MODBus points that can be retrieved from a station, using the MultiTrode Translator. Note: A number of points are reserved for future MultiTrode use. MultiTrode Pty Ltd Head Office Ph: +61 7 3340 7000 Fx: +61 7 3340 7077 E-mail: sales@multitrode.com.au Visit www.multitrode.com for the latest information MultiTrode Inc USA Ph: +1 561 994 8090 Fx: +1 561 994 6282 E-mail: sales@multitrode.net MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc Page 27 of 28

Protocol Translator MODBus User Manual Page 28 of 28 MultiTrode_MTT_MODBus_Manual_v1-0-9_R02.doc

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 01 00 00 This bit will be high if there is any fault on pump 1 and low otherwise Status_quick[2] 7 02 00 01 This bit will be high if there is any fault on pump 1 that is unacknowledged (i.e. fault not present AND Status_quick[2] 6 unacknowledged) and low otherwise 03 00 02 This bit will be high if there is any fault on pump 2 and low otherwise Status_quick[2] 5 04 00 03 This bit will be high if there is any fault on pump 2 that is unacknowledged (i.e. fault not present AND Status_quick[2] 4 unacknowledged) and low otherwise 05 00 04 This bit will be high if there is any fault on pump 3 and low otherwise Status_quick[2] 3 06 00 05 This bit will be high if there is any fault on pump 3 that is unacknowledged (i.e. fault not present AND Status_quick[2] 2 unacknowledged) and low otherwise 07 00 06 This bit will be high if there is any fault on pump 4 and low otherwise Status_quick[2] 1 08 00 07 This bit will be high if there is any fault on pump 4 that is unacknowledged (i.e. fault not present AND Status_quick[2] 0 unacknowledged) and low otherwise 09 00 08 This bit will be high if there is any fault on pump 5 and low otherwise Status_quick[3] 7 10 00 09 This bit will be high if there is any fault on pump 5 that is unacknowledged (i.e. fault not present AND Status_quick[3] 6 unacknowledged) and low otherwise 11 00 10 This bit will be high if there is any fault on pump 6 and low otherwise Status_quick[3] 5 12 00 11 This bit will be high if there is any fault on pump 6 that is unacknowledged (i.e. fault not present AND Status_quick[3] 4 unacknowledged) and low otherwise 13 00 12 This bit will be high if there is any fault on pump 7 and low otherwise Status_quick[3] 3 14 00 13 This bit will be high if there is any fault on pump 7 that is unacknowledged (i.e. fault not present AND Status_quick[3] 2 unacknowledged) and low otherwise 15 00 14 This bit will be high if there is any fault on pump 8 and low otherwise Status_quick[3] 1 16 00 15 This bit will be high if there is any fault on pump 8 that is unacknowledged (i.e. fault not present AND Status_quick[3] 0 unacknowledged) and low otherwise 17 01 00 This bit will be high if there is any fault on pump 9 and low otherwise Status_quick[4] 7 18 01 01 This bit will be high if there is any fault on pump 9 that is unacknowledged (i.e. fault not present AND Status_quick[4] 6 unacknowledged) and low otherwise 19 01 02 This bit will be high if pump 1 is available and low otherwise Status_quick[4] 5 20 01 03 This bit will be high if pump 2 is available and low otherwise Status_quick[4] 4 21 01 04 This bit will be high if pump 3 is available and low otherwise Status_quick[4] 3 22 01 05 This bit will be high if pump 4 is available and low otherwise Status_quick[4] 2 23 01 06 This bit will be high if pump 5 is available and low otherwise Status_quick[4] 1 24 01 07 This bit will be high if pump 6 is available and low otherwise Status_quick[4] 0 25 01 08 This bit will be high if pump 7 is available and low otherwise Status_quick[5] 7 26 01 09 This bit will be high if pump 8 is available and low otherwise Status_quick[5] 6 27 01 10 This bit will be high if pump 9 is available and low otherwise Status_quick[5] 5 28 01 11 This bit will be high if there is any fault on the Master MonitorPRO and low otherwise Status_quick[5] 4 29 01 12 This bit will be high if there is any fault on Slave 1 MonitorPRO and low otherwise Status_quick[5] 3 30 01 13 This bit will be high if there is any fault on Slave 2 MonitorPRO and low otherwise Status_quick[5] 2 31 01 14 This bit will be high if there is any change to the fault status and low otherwise Status_quick[5] 1 32 01 15 This bit will be high if there is any change to any of the digital inputs or outputs or analogue inputs and low otherwise Status_quick[5] 0 33 02 00 This bit is high if pump 1 is running and low otherwise Status_quick[6] 7 34 02 01 This bit is high if pump 1 is available and low otherwise Status_quick[6] 6 Page 1 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 35 02 02 If index 34=0 and index 35=0 then pump 1 is in auto mode. If index 34=0 and index 35=1 then pump 1 is off. If index 34=1 and index 35=0 then pump 1 is off. If index 34=1 and index 35=1 then pump 1 is in manual mode Status_quick[6] 5 36 02 03 See above. Status_quick[6] 4 37 02 04 This bit is high if pump 2 is running and low otherwise Status_quick[6] 3 38 02 05 This bit is high if pump 2 is available and low otherwise Status_quick[6] 2 39 02 06 If index 38=0 and index 39=0 then pump 2 is in auto mode. Status_quick[6] 1 If index 38=0 and index 39=1 then pump 2 is off. If index 38=1 and index 39=0 then pump 2 is off. If index 38=1 and index 39=1 then pump 2 is in manual mode 40 02 07 See above. Status_quick[6] 0 41 02 08 This bit is high if pump 3 is running and low otherwise Status_quick[7] 7 42 02 09 This bit is high if pump 3 is available and low otherwise Status_quick[7] 6 43 02 10 If index 42=0 and index 43=0 then pump 3 is in auto mode. Status_quick[7] 5 If index 42=0 and index 43=1 then pump 3 is off. If index 42=1 and index 43=0 then pump 3 is off. If index 42=1 and index 43=1 then pump 3 is in manual mode 44 02 11 See above. Status_quick[7] 4 45 02 12 This bit is high if pump 4 is running and low otherwise Status_quick[7] 3 46 02 13 This bit is high if pump 4 is available and low otherwise Status_quick[7] 2 47 02 14 If index 46=0 and index 47=0 then pump 4 is in auto mode. Status_quick[7] 1 If index 46=0 and index 47=1 then pump 4 is off. If index 46=1 and index 47=0 then pump 4 is off. If index 46=1 and index 47=1 then pump 4 is in manual mode 48 02 15 See above. Status_quick[7] 0 49 03 00 This bit is high if pump 5 is running and low otherwise Status_quick[8] 7 50 03 01 This bit is high if pump 5 is available and low otherwise Status_quick[8] 6 51 03 02 If index 50=0 and index 51=0 then pump 5 is in auto mode. Status_quick[8] 5 If index 50=0 and index 51=1 then pump 5 is off. If index 50=1 and index 51=0 then pump 5 is off. If index 50=1 and index 51=1 then pump 5 is in manual mode 52 03 03 See above. Status_quick[8] 4 53 03 04 This bit is high if pump 6 is running and low otherwise Status_quick[8] 3 54 03 05 This bit is high if pump 6 is available and low otherwise Status_quick[8] 2 55 03 06 If index 54=0 and index 55=0 then pump 6 is in auto mode. Status_quick[8] 1 If index 54=0 and index 55=1 then pump 6 is off. If index 54=1 and index 55=0 then pump 6 is off. If index 54=1 and index 55=1 then pump 6 is in manual mode 56 03 07 See above. Status_quick[8] 0 57 03 08 This bit is high if pump 7 is running and low otherwise Status_quick[9] 7 58 03 09 This bit is high if pump 7 is available and low otherwise Status_quick[9] 6 Page 2 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 59 03 10 If index 58=0 and index 59=0 then pump 7 is in auto mode. If index 58=0 and index 59=1 then pump 7 is off. If index 58=1 and index 59=0 then pump 7 is off. If index 58=1 and index 59=1 then pump 7 is in manual mode Status_quick[9] 5 60 03 11 See above. Status_quick[9] 4 61 03 12 This bit is high if pump 8 is running and low otherwise Status_quick[9] 3 62 03 13 This bit is high if pump 8 is available and low otherwise Status_quick[9] 2 63 03 14 If index 62=0 and index 63=0 then pump 8 is in auto mode. Status_quick[9] 1 If index 62=0 and index 63=1 then pump 8 is off. If index 62=1 and index 63=0 then pump 8 is off. If index 62=1 and index 63=1 then pump 8 is in manual mode 64 03 15 See above. Status_quick[9] 0 65 04 00 This bit is high if pump 9 is running and low otherwise Status_quick[10] 7 66 04 01 This bit is high if pump 9 is available and low otherwise Status_quick[10] 6 67 04 02 If index 66=0 and index 67=0 then pump 9 is in auto mode. Status_quick[10] 5 If index 66=0 and index 67=1 then pump 9 is off. If index 66=1 and index 67=0 then pump 9 is off. If index 66=1 and index 67=1 then pump 9 is in manual mode 68 04 03 See above. Status_quick[10] 4 69 04 04 Reserved Status_quick[10] 3 70 04 05 Reserved Status_quick[10] 2 71 04 06 Reserved Status_quick[10] 1 72 04 07 Reserved Status_quick[10] 0 73 04 08 Alarm 1 status_dig 7 74 04 09 Alarm 2 status_dig 6 75 04 10 Common Alarm status_dig 5 76 04 11 Datalog Full Flag status_dig 4 77 04 12 Spare status_dig 3 78 04 13 Spare status_dig 2 79 04 14 Spare status_dig 1 80 04 15 Spare status_dig 0 81 05 00 This bit will be high if a critical fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 7 82 05 01 This bit will be high if a non-critical fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 6 83 05 02 This bit will be high if a delay fail fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 5 84 05 03 This bit will be high if a seal fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 4 85 05 04 This bit will be high if a flygt seal fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 3 86 05 05 This bit will be high if a flygt thermistor fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 2 87 05 06 If the maximum starts per hour on pump 1 has been exceeded then this bit is high and low otherw status_xpc_pump_present[0] 1 88 05 07 This bit will be high if a thermistor fault is PRESENT on pump 1 and low otherwise status_xpc_pump_present[0] 0 89 05 08 This bit will be high if a critical fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 7 90 05 09 This bit will be high if a non-critical fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 6 91 05 10 This bit will be high if a delay fail fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 5 92 05 11 This bit will be high if a seal fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 4 93 05 12 This bit will be high if a flygt seal fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 3 Page 3 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 94 05 13 This bit will be high if a flygt thermistor fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 2 95 05 14 If the maximum starts per hour on pump 2 has been exceeded then this bit is high and low otherw status_xpc_pump_present[1] 1 96 05 15 This bit will be high if a thermistor fault is PRESENT on pump 2 and low otherwise status_xpc_pump_present[1] 0 97 06 00 This bit will be high if a critical fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 7 98 06 01 This bit will be high if a non-critical fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 6 99 06 02 This bit will be high if a delay fail fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 5 100 06 03 This bit will be high if a seal fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 4 101 06 04 This bit will be high if a flygt seal fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 3 102 06 05 This bit will be high if a flygt thermistor fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 2 103 06 06 If the maximum starts per hour on pump 3 has been exceeded then this bit is high and low otherw status_xpc_pump_present[2] 1 104 06 07 This bit will be high if a thermistor fault is PRESENT on pump 3 and low otherwise status_xpc_pump_present[2] 0 105 06 08 This bit will be high if a critical fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 7 106 06 09 This bit will be high if a non-critical fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 6 107 06 10 This bit will be high if a delay fail fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 5 108 06 11 This bit will be high if a seal fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 4 109 06 12 This bit will be high if a flygt seal fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 3 110 06 13 This bit will be high if a flygt thermistor fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 2 111 06 14 If the maximum starts per hour on pump 4 has been exceeded then this bit is high and low otherw status_xpc_pump_present[3] 1 112 06 15 This bit will be high if a thermistor fault is PRESENT on pump 4 and low otherwise status_xpc_pump_present[3] 0 113 07 00 This bit will be high if a critical fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 7 114 07 01 This bit will be high if a non-critical fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 6 115 07 02 This bit will be high if a delay fail fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 5 116 07 03 This bit will be high if a seal fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 4 117 07 04 This bit will be high if a flygt seal fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 3 118 07 05 This bit will be high if a flygt thermistor fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 2 119 07 06 If the maximum starts per hour on pump 5 has been exceeded then this bit is high and low otherw status_xpc_pump_present[4] 1 120 07 07 This bit will be high if a thermistor fault is PRESENT on pump 5 and low otherwise status_xpc_pump_present[4] 0 121 07 08 This bit will be high if a critical fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 7 122 07 09 This bit will be high if a non-critical fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 6 123 07 10 This bit will be high if a delay fail fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 5 124 07 11 This bit will be high if a seal fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 4 125 07 12 This bit will be high if a flygt seal fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 3 126 07 13 This bit will be high if a flygt thermistor fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 2 127 07 14 If the maximum starts per hour on pump 6 has been exceeded then this bit is high and low otherw status_xpc_pump_present[5] 1 128 07 15 This bit will be high if a thermistor fault is PRESENT on pump 6 and low otherwise status_xpc_pump_present[5] 0 129 08 00 This bit will be high if a critical fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 7 130 08 01 This bit will be high if a non-critical fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 6 131 08 02 This bit will be high if a delay fail fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 5 132 08 03 This bit will be high if a seal fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 4 133 08 04 This bit will be high if a flygt seal fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 3 134 08 05 This bit will be high if a flygt thermistor fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 2 135 08 06 If the maximum starts per hour on pump 7 has been exceeded then this bit is high and low otherw status_xpc_pump_present[6] 1 136 08 07 This bit will be high if a thermistor fault is PRESENT on pump 7 and low otherwise status_xpc_pump_present[6] 0 137 08 08 This bit will be high if a critical fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 7 Page 4 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 138 08 09 This bit will be high if a non-critical fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 6 139 08 10 This bit will be high if a delay fail fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 5 140 08 11 This bit will be high if a seal fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 4 141 08 12 This bit will be high if a flygt seal fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 3 142 08 13 This bit will be high if a flygt thermistor fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 2 143 08 14 If the maximum starts per hour on pump 8 has been exceeded then this bit is high and low otherw status_xpc_pump_present[7] 1 144 08 15 This bit will be high if a thermistor fault is PRESENT on pump 8 and low otherwise status_xpc_pump_present[7] 0 145 09 00 This bit will be high if a critical fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 7 146 09 01 This bit will be high if a non-critical fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 6 147 09 02 This bit will be high if a delay fail fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 5 148 09 03 This bit will be high if a seal fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 4 149 09 04 This bit will be high if a flygt seal fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 3 150 09 05 This bit will be high if a flygt thermistor fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 2 151 09 06 If the maximum starts per hour on pump 9 has been exceeded then this bit is high and low otherw status_xpc_pump_present[8] 1 152 09 07 This bit will be high if a thermistor fault is PRESENT on pump 9 and low otherwise status_xpc_pump_present[8] 0 153 09 08 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 1 and low otherwise status_xpc_pump_unackd[0] 7 154 09 09 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 1 and low otherwise 155 09 10 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 1 and low otherwise 156 09 11 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 1 and low otherwise 157 09 12 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 1 and low otherwise 158 09 13 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 1 and low otherwise status_xpc_pump_unackd[0] 6 status_xpc_pump_unackd[0] 5 status_xpc_pump_unackd[0] 4 status_xpc_pump_unackd[0] 3 status_xpc_pump_unackd[0] 2 159 09 14 Reserved status_xpc_pump_unackd[0] 1 160 09 15 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[0] 0 acknowledged) on pump 1 and low otherwise 161 10 00 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[1] 7 acknowledged) on pump 2 and low otherwise 162 10 01 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[1] 6 acknowledged) on pump 2 and low otherwise 163 10 02 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[1] 5 acknowledged) on pump 2 and low otherwise 164 10 03 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged status_xpc_pump_unackd[1] 4 on pump 2 and low otherwise 165 10 04 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[1] 3 acknowledged) on pump 2 and low otherwise 166 10 05 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[1] 2 acknowledged) on pump 2 and low otherwise 167 10 06 Reserved status_xpc_pump_unackd[1] 1 Page 5 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 168 10 07 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 2 and low otherwise 169 10 08 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 3 and low otherwise 170 10 09 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 3 and low otherwise 171 10 10 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 3 and low otherwise 172 10 11 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 3 and low otherwise 173 10 12 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 3 and low otherwise 174 10 13 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 3 and low otherwise status_xpc_pump_unackd[1] 0 status_xpc_pump_unackd[2] 7 status_xpc_pump_unackd[2] 6 status_xpc_pump_unackd[2] 5 status_xpc_pump_unackd[2] 4 status_xpc_pump_unackd[2] 3 status_xpc_pump_unackd[2] 2 175 10 14 Reserved status_xpc_pump_unackd[2] 1 176 10 15 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[2] 0 acknowledged) on pump 3 and low otherwise 177 11 00 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 4 and low otherwise 178 11 01 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 4 and low otherwise 179 11 02 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 4 and low otherwise 180 11 03 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 4 and low otherwise 181 11 04 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 4 and low otherwise 182 11 05 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 4 and low otherwise status_xpc_pump_unackd[3] 7 status_xpc_pump_unackd[3] 6 status_xpc_pump_unackd[3] 5 status_xpc_pump_unackd[3] 4 status_xpc_pump_unackd[3] 3 status_xpc_pump_unackd[3] 2 183 11 06 Reserved status_xpc_pump_unackd[3] 1 184 11 07 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[3] 0 acknowledged) on pump 4 and low otherwise 185 11 08 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 5 and low otherwise 186 11 09 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 5 and low otherwise 187 11 10 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 5 and low otherwise 188 11 11 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 5 and low otherwise 189 11 12 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 5 and low otherwise 190 11 13 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 5 and low otherwise status_xpc_pump_unackd[4] 7 status_xpc_pump_unackd[4] 6 status_xpc_pump_unackd[4] 5 status_xpc_pump_unackd[4] 4 status_xpc_pump_unackd[4] 3 status_xpc_pump_unackd[4] 2 Page 6 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 191 11 14 Reserved status_xpc_pump_unackd[4] 1 192 11 15 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[4] 0 acknowledged) on pump 5 and low otherwise 193 12 00 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 6 and low otherwise 194 12 01 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 6 and low otherwise 195 12 02 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 6 and low otherwise 196 12 03 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 6 and low otherwise 197 12 04 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 6 and low otherwise 198 12 05 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 6 and low otherwise status_xpc_pump_unackd[5] 7 status_xpc_pump_unackd[5] 6 status_xpc_pump_unackd[5] 5 status_xpc_pump_unackd[5] 4 status_xpc_pump_unackd[5] 3 status_xpc_pump_unackd[5] 2 199 12 06 Reserved status_xpc_pump_unackd[5] 1 200 12 07 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[5] 0 acknowledged) on pump 6 and low otherwise 201 12 08 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 7 and low otherwise 202 12 09 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 7 and low otherwise 203 12 10 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 7 and low otherwise 204 12 11 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 7 and low otherwise 205 12 12 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 7 and low otherwise 206 12 13 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 7 and low otherwise status_xpc_pump_unackd[6] 7 status_xpc_pump_unackd[6] 6 status_xpc_pump_unackd[6] 5 status_xpc_pump_unackd[6] 4 status_xpc_pump_unackd[6] 3 status_xpc_pump_unackd[6] 2 207 12 14 Reserved status_xpc_pump_unackd[6] 1 208 12 15 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[6] 0 acknowledged) on pump 7 and low otherwise 209 13 00 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 8 and low otherwise 210 13 01 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 8 and low otherwise 211 13 02 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 8 and low otherwise 212 13 03 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 8 and low otherwise 213 13 04 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 8 and low otherwise status_xpc_pump_unackd[7] 7 status_xpc_pump_unackd[7] 6 status_xpc_pump_unackd[7] 5 status_xpc_pump_unackd[7] 4 status_xpc_pump_unackd[7] 3 Page 7 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 214 13 05 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 8 and low otherwise status_xpc_pump_unackd[7] 2 215 13 06 Reserved status_xpc_pump_unackd[7] 1 216 13 07 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[7] 0 acknowledged) on pump 8 and low otherwise 217 13 08 This bit will be high if a critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 9 and low otherwise 218 13 09 This bit will be high if a non-critical fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 9 and low otherwise 219 13 10 This bit will be high if a delay fail fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 9 and low otherwise 220 13 11 This bit will be high if a seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged on pump 9 and low otherwise 221 13 12 This bit will be high if a flygt seal fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 9 and low otherwise 222 13 13 This bit will be high if a flygt thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been acknowledged) on pump 9 and low otherwise status_xpc_pump_unackd[8] 7 status_xpc_pump_unackd[8] 6 status_xpc_pump_unackd[8] 5 status_xpc_pump_unackd[8] 4 status_xpc_pump_unackd[8] 3 status_xpc_pump_unackd[8] 2 223 13 14 Reserved status_xpc_pump_unackd[8] 1 224 13 15 This bit will be high if a thermistor fault is UNACKNOWLEDGED (Fault is NOT present but has NOT been status_xpc_pump_unackd[8] 0 acknowledged) on pump 9 and low otherwise 225 14 00 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to any fault shown below being PRESEN 226 14 01 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an under current fault being PRESEN 227 14 02 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an over current fault being PRESENT an 228 14 03 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a thermal alarm fault being PRESENT an 229 14 04 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a phase fail fault being PRESENT and low otherwise 230 14 05 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a phase rotation alarm fault bein PRESENT 231 14 06 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an earth fault being PRESENT and is lo otherwise 232 14 07 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an insulation test fault being PRESEN 233 14 08 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a low flow fault being PRESENT and is lo otherwise 234 14 09 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an analog input 2 fault being PRESEN 235 14 10 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an analog input 1 fault being PRESEN 236 14 11 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 6 fault being PRESENT an status_rtu_pump_present[0][0] 7 status_rtu_pump_present[0][0] 6 status_rtu_pump_present[0][0] 5 status_rtu_pump_present[0][0] 4 status_rtu_pump_present[0][0] 3 status_rtu_pump_present[0][0] 2 status_rtu_pump_present[0][0] 1 status_rtu_pump_present[0][0] 0 status_rtu_pump_present[0][1] 7 status_rtu_pump_present[0][1] 6 status_rtu_pump_present[0][1] 5 status_rtu_pump_present[0][1] 4 Page 8 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 237 14 12 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 5 fault being PRESENT an 238 14 13 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 4 fault being PRESENT an 239 14 14 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 3 fault being PRESENT an 240 14 15 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 2 fault being PRESENT an 241 15 00 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 1 fault being PRESENT an 242 15 01 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 3 fault being PRESEN 243 15 02 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 2 fault being PRESEN 244 15 03 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 1 fault being PRESEN status_rtu_pump_present[0][1] 3 status_rtu_pump_present[0][1] 2 status_rtu_pump_present[0][1] 1 status_rtu_pump_present[0][1] 0 status_rtu_pump_present[0][2] 7 status_rtu_pump_present[0][2] 6 status_rtu_pump_present[0][2] 5 status_rtu_pump_present[0][2] 4 245 15 04 Reserved status_rtu_pump_present[0][2] 3 246 15 05 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[0][2] 2 247 15 06 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a low flow warning fault being PRESEN status_rtu_pump_present[0][2] 1 248 15 07 Reserved status_rtu_pump_present[0][2] 0 249 15 08 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to any fault shown below being PRESEN status_rtu_pump_present[1][0] 7 250 15 09 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an under current fault being PRESEN 251 15 10 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an over current fault being PRESENT an 252 15 11 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a thermal alarm fault being PRESENT an 253 15 12 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a phase fail fault being PRESENT and low otherwise 254 15 13 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a phase rotation alarm fault bein PRESENT 255 15 14 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an earth fault being PRESENT and is lo otherwise 256 15 15 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an insulation test fault being PRESEN 257 16 00 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a low flow fault being PRESENT and is lo otherwise 258 16 01 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an analog input 2 fault being PRESEN 259 16 02 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an analog input 1 fault being PRESEN status_rtu_pump_present[1][0] 6 status_rtu_pump_present[1][0] 5 status_rtu_pump_present[1][0] 4 status_rtu_pump_present[1][0] 3 status_rtu_pump_present[1][0] 2 status_rtu_pump_present[1][0] 1 status_rtu_pump_present[1][0] 0 status_rtu_pump_present[1][1] 7 status_rtu_pump_present[1][1] 6 status_rtu_pump_present[1][1] 5 Page 9 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 260 16 03 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 6 fault being PRESENT an 261 16 04 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 5 fault being PRESENT an 262 16 05 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 4 fault being PRESENT an 263 16 06 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 3 fault being PRESENT an 264 16 07 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 2 fault being PRESENT an 265 16 08 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 1 fault being PRESENT an 266 16 09 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 3 fault being PRESEN 267 16 10 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 2 fault being PRESEN 268 16 11 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 1 fault being PRESEN status_rtu_pump_present[1][1] 4 status_rtu_pump_present[1][1] 3 status_rtu_pump_present[1][1] 2 status_rtu_pump_present[1][1] 1 status_rtu_pump_present[1][1] 0 status_rtu_pump_present[1][2] 7 status_rtu_pump_present[1][2] 6 status_rtu_pump_present[1][2] 5 status_rtu_pump_present[1][2] 4 269 16 12 Reserved status_rtu_pump_present[1][2] 3 270 16 13 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[1][2] 2 271 16 14 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a low flow warning fault being PRESEN status_rtu_pump_present[1][2] 1 272 16 15 Reserved status_rtu_pump_present[1][2] 0 273 17 00 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to any fault shown below being PRESEN status_rtu_pump_present[2][0] 7 274 17 01 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an under current fault being PRESEN 275 17 02 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an over current fault being PRESENT an 276 17 03 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a thermal alarm fault being PRESENT an 277 17 04 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a phase fail fault being PRESENT and low otherwise 278 17 05 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a phase rotation alarm fault bein PRESENT 279 17 06 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an earth fault being PRESENT and is lo otherwise 280 17 07 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an insulation test fault being PRESEN 281 17 08 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a low flow fault being PRESENT and is lo otherwise 282 17 09 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an analog input 2 fault being PRESEN status_rtu_pump_present[2][0] 6 status_rtu_pump_present[2][0] 5 status_rtu_pump_present[2][0] 4 status_rtu_pump_present[2][0] 3 status_rtu_pump_present[2][0] 2 status_rtu_pump_present[2][0] 1 status_rtu_pump_present[2][0] 0 status_rtu_pump_present[2][1] 7 status_rtu_pump_present[2][1] 6 Page 10 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 283 17 10 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an analog input 1 fault being PRESEN 284 17 11 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 6 fault being PRESENT an 285 17 12 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 5 fault being PRESENT an 286 17 13 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 4 fault being PRESENT an 287 17 14 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 3 fault being PRESENT an 288 17 15 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 2 fault being PRESENT an 289 18 00 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 1 fault being PRESENT an 290 18 01 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 3 fault being PRESEN 291 18 02 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 2 fault being PRESEN 292 18 03 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 1 fault being PRESEN status_rtu_pump_present[2][1] 5 status_rtu_pump_present[2][1] 4 status_rtu_pump_present[2][1] 3 status_rtu_pump_present[2][1] 2 status_rtu_pump_present[2][1] 1 status_rtu_pump_present[2][1] 0 status_rtu_pump_present[2][2] 7 status_rtu_pump_present[2][2] 6 status_rtu_pump_present[2][2] 5 status_rtu_pump_present[2][2] 4 293 18 04 Reserved status_rtu_pump_present[2][2] 3 294 18 05 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[2][2] 2 295 18 06 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a low flow warning fault being PRESEN status_rtu_pump_present[2][2] 1 296 18 07 Reserved status_rtu_pump_present[2][2] 0 297 18 08 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to any fault shown below being PRESEN status_rtu_pump_present[3][0] 7 298 18 09 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an under current fault being PRESEN 299 18 10 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an over current fault being PRESENT an 300 18 11 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a thermal alarm fault being PRESENT an 301 18 12 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a phase fail fault being PRESENT and low otherwise 302 18 13 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a phase rotation alarm fault bein PRESENT 303 18 14 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an earth fault being PRESENT and is lo otherwise 304 18 15 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an insulation test fault being PRESEN 305 19 00 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a low flow fault being PRESENT and is lo otherwise status_rtu_pump_present[3][0] 6 status_rtu_pump_present[3][0] 5 status_rtu_pump_present[3][0] 4 status_rtu_pump_present[3][0] 3 status_rtu_pump_present[3][0] 2 status_rtu_pump_present[3][0] 1 status_rtu_pump_present[3][0] 0 status_rtu_pump_present[3][1] 7 Page 11 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 306 19 01 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an analog input 2 fault being PRESEN 307 19 02 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an analog input 1 fault being PRESEN 308 19 03 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 6 fault being PRESENT an 309 19 04 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 5 fault being PRESENT an 310 19 05 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 4 fault being PRESENT an 311 19 06 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 3 fault being PRESENT an 312 19 07 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 2 fault being PRESENT an 313 19 08 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 1 fault being PRESENT an 314 19 09 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 3 fault being PRESEN 315 19 10 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 2 fault being PRESEN 316 19 11 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 1 fault being PRESEN status_rtu_pump_present[3][1] 6 status_rtu_pump_present[3][1] 5 status_rtu_pump_present[3][1] 4 status_rtu_pump_present[3][1] 3 status_rtu_pump_present[3][1] 2 status_rtu_pump_present[3][1] 1 status_rtu_pump_present[3][1] 0 status_rtu_pump_present[3][2] 7 status_rtu_pump_present[3][2] 6 status_rtu_pump_present[3][2] 5 status_rtu_pump_present[3][2] 4 317 19 12 Reserved status_rtu_pump_present[3][2] 3 318 19 13 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[3][2] 2 319 19 14 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a low flow warning fault being PRESEN status_rtu_pump_present[3][2] 1 320 19 15 Reserved status_rtu_pump_present[3][2] 0 321 20 00 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to any fault shown below being PRESEN status_rtu_pump_present[4][0] 7 322 20 01 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an under current fault being PRESEN 323 20 02 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an over current fault being PRESENT an 324 20 03 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a thermal alarm fault being PRESENT an 325 20 04 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a phase fail fault being PRESENT and low otherwise 326 20 05 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a phase rotation alarm fault bein PRESENT 327 20 06 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an earth fault being PRESENT and is lo otherwise 328 20 07 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an insulation test fault being PRESEN status_rtu_pump_present[4][0] 6 status_rtu_pump_present[4][0] 5 status_rtu_pump_present[4][0] 4 status_rtu_pump_present[4][0] 3 status_rtu_pump_present[4][0] 2 status_rtu_pump_present[4][0] 1 status_rtu_pump_present[4][0] 0 Page 12 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 329 20 08 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a low flow fault being PRESENT and is lo otherwise 330 20 09 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an analog input 2 fault being PRESEN 331 20 10 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an analog input 1 fault being PRESEN 332 20 11 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 6 fault being PRESENT an 333 20 12 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 5 fault being PRESENT an 334 20 13 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 4 fault being PRESENT an 335 20 14 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 3 fault being PRESENT an 336 20 15 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 2 fault being PRESENT an 337 21 00 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 1 fault being PRESENT an 338 21 01 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 3 fault being PRESEN 339 21 02 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 2 fault being PRESEN 340 21 03 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 1 fault being PRESEN status_rtu_pump_present[4][1] 7 status_rtu_pump_present[4][1] 6 status_rtu_pump_present[4][1] 5 status_rtu_pump_present[4][1] 4 status_rtu_pump_present[4][1] 3 status_rtu_pump_present[4][1] 2 status_rtu_pump_present[4][1] 1 status_rtu_pump_present[4][1] 0 status_rtu_pump_present[4][2] 7 status_rtu_pump_present[4][2] 6 status_rtu_pump_present[4][2] 5 status_rtu_pump_present[4][2] 4 341 21 04 Reserved status_rtu_pump_present[4][2] 3 342 21 05 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[4][2] 2 343 21 06 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a low flow warning fault being PRESEN status_rtu_pump_present[4][2] 1 344 21 07 Reserved status_rtu_pump_present[4][2] 0 345 21 08 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to any fault shown below being PRESEN status_rtu_pump_present[5][0] 7 346 21 09 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an under current fault being PRESEN 347 21 10 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an over current fault being PRESENT an 348 21 11 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a thermal alarm fault being PRESENT an 349 21 12 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a phase fail fault being PRESENT and low otherwise 350 21 13 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a phase rotation alarm fault bein PRESENT 351 21 14 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an earth fault being PRESENT and is lo otherwise status_rtu_pump_present[5][0] 6 status_rtu_pump_present[5][0] 5 status_rtu_pump_present[5][0] 4 status_rtu_pump_present[5][0] 3 status_rtu_pump_present[5][0] 2 status_rtu_pump_present[5][0] 1 Page 13 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 352 21 15 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an insulation test fault being PRESEN 353 22 00 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a low flow fault being PRESENT and is lo otherwise 354 22 01 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an analog input 2 fault being PRESEN 355 22 02 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an analog input 1 fault being PRESEN 356 22 03 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 6 fault being PRESENT an 357 22 04 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 5 fault being PRESENT an 358 22 05 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 4 fault being PRESENT an 359 22 06 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 3 fault being PRESENT an 360 22 07 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 2 fault being PRESENT an 361 22 08 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 1 fault being PRESENT an 362 22 09 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 3 fault being PRESEN 363 22 10 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 2 fault being PRESEN 364 22 11 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 1 fault being PRESEN status_rtu_pump_present[5][0] 0 status_rtu_pump_present[5][1] 7 status_rtu_pump_present[5][1] 6 status_rtu_pump_present[5][1] 5 status_rtu_pump_present[5][1] 4 status_rtu_pump_present[5][1] 3 status_rtu_pump_present[5][1] 2 status_rtu_pump_present[5][1] 1 status_rtu_pump_present[5][1] 0 status_rtu_pump_present[5][2] 7 status_rtu_pump_present[5][2] 6 status_rtu_pump_present[5][2] 5 status_rtu_pump_present[5][2] 4 365 22 12 Reserved status_rtu_pump_present[5][2] 3 366 22 13 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[5][2] 2 367 22 14 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a low flow warning fault being PRESEN status_rtu_pump_present[5][2] 1 368 22 15 Reserved status_rtu_pump_present[5][2] 0 369 23 00 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to any fault shown below being PRESEN status_rtu_pump_present[6][0] 7 370 23 01 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an under current fault being PRESEN 371 23 02 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an over current fault being PRESENT an 372 23 03 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a thermal alarm fault being PRESENT an 373 23 04 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a phase fail fault being PRESENT and low otherwise 374 23 05 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a phase rotation alarm fault bein PRESENT status_rtu_pump_present[6][0] 6 status_rtu_pump_present[6][0] 5 status_rtu_pump_present[6][0] 4 status_rtu_pump_present[6][0] 3 status_rtu_pump_present[6][0] 2 Page 14 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 375 23 06 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an earth fault being PRESENT and is lo otherwise 376 23 07 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an insulation test fault being PRESEN 377 23 08 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a low flow fault being PRESENT and is lo otherwise 378 23 09 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an analog input 2 fault being PRESEN 379 23 10 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an analog input 1 fault being PRESEN 380 23 11 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 6 fault being PRESENT an 381 23 12 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 5 fault being PRESENT an 382 23 13 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 4 fault being PRESENT an 383 23 14 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 3 fault being PRESENT an 384 23 15 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 2 fault being PRESENT an 385 24 00 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 1 fault being PRESENT an 386 24 01 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 3 fault being PRESEN 387 24 02 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 2 fault being PRESEN 388 24 03 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 1 fault being PRESEN status_rtu_pump_present[6][0] 1 status_rtu_pump_present[6][0] 0 status_rtu_pump_present[6][1] 7 status_rtu_pump_present[6][1] 6 status_rtu_pump_present[6][1] 5 status_rtu_pump_present[6][1] 4 status_rtu_pump_present[6][1] 3 status_rtu_pump_present[6][1] 2 status_rtu_pump_present[6][1] 1 status_rtu_pump_present[6][1] 0 status_rtu_pump_present[6][2] 7 status_rtu_pump_present[6][2] 6 status_rtu_pump_present[6][2] 5 status_rtu_pump_present[6][2] 4 389 24 04 Reserved status_rtu_pump_present[6][2] 3 390 24 05 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[6][2] 2 391 24 06 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a low flow warning fault being PRESEN status_rtu_pump_present[6][2] 1 392 24 07 Reserved status_rtu_pump_present[6][2] 0 393 24 08 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to any fault shown below being PRESEN status_rtu_pump_present[7][0] 7 394 24 09 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an under current fault being PRESEN 395 24 10 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an over current fault being PRESENT an 396 24 11 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a thermal alarm fault being PRESENT an 397 24 12 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a phase fail fault being PRESENT and low otherwise status_rtu_pump_present[7][0] 6 status_rtu_pump_present[7][0] 5 status_rtu_pump_present[7][0] 4 status_rtu_pump_present[7][0] 3 Page 15 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 398 24 13 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a phase rotation alarm fault bein PRESENT 399 24 14 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an earth fault being PRESENT and is lo otherwise 400 24 15 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an insulation test fault being PRESEN 401 25 00 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a low flow fault being PRESENT and is lo otherwise 402 25 01 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an analog input 2 fault being PRESEN 403 25 02 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an analog input 1 fault being PRESEN 404 25 03 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 6 fault being PRESENT an 405 25 04 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 5 fault being PRESENT an 406 25 05 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 4 fault being PRESENT an 407 25 06 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 3 fault being PRESENT an 408 25 07 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 2 fault being PRESENT an 409 25 08 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 1 fault being PRESENT an 410 25 09 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 3 fault being PRESEN 411 25 10 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 2 fault being PRESEN 412 25 11 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 1 fault being PRESEN status_rtu_pump_present[7][0] 2 status_rtu_pump_present[7][0] 1 status_rtu_pump_present[7][0] 0 status_rtu_pump_present[7][1] 7 status_rtu_pump_present[7][1] 6 status_rtu_pump_present[7][1] 5 status_rtu_pump_present[7][1] 4 status_rtu_pump_present[7][1] 3 status_rtu_pump_present[7][1] 2 status_rtu_pump_present[7][1] 1 status_rtu_pump_present[7][1] 0 status_rtu_pump_present[7][2] 7 status_rtu_pump_present[7][2] 6 status_rtu_pump_present[7][2] 5 status_rtu_pump_present[7][2] 4 413 25 12 Reserved status_rtu_pump_present[7][2] 3 414 25 13 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[7][2] 2 415 25 14 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a low flow warning fault being PRESEN status_rtu_pump_present[7][2] 1 416 25 15 Reserved status_rtu_pump_present[7][2] 0 417 26 00 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to any fault shown below being PRESEN status_rtu_pump_present[8][0] 7 418 26 01 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an under current fault being PRESEN 419 26 02 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an over current fault being PRESENT an 420 26 03 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a thermal alarm fault being PRESENT an status_rtu_pump_present[8][0] 6 status_rtu_pump_present[8][0] 5 status_rtu_pump_present[8][0] 4 Page 16 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 421 26 04 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a phase fail fault being PRESENT and low otherwise 422 26 05 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a phase rotation alarm fault bein PRESENT 423 26 06 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an earth fault being PRESENT and is lo otherwise 424 26 07 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an insulation test fault being PRESEN 425 26 08 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a low flow fault being PRESENT and is lo otherwise 426 26 09 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an analog input 2 fault being PRESEN 427 26 10 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an analog input 1 fault being PRESEN 428 26 11 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 6 fault being PRESENT an 429 26 12 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 5 fault being PRESENT an 430 26 13 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 4 fault being PRESENT an 431 26 14 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 3 fault being PRESENT an 432 26 15 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 2 fault being PRESENT an 433 27 00 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 1 fault being PRESENT an 434 27 01 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 3 fault being PRESEN 435 27 02 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 2 fault being PRESEN 436 27 03 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 1 fault being PRESEN status_rtu_pump_present[8][0] 3 status_rtu_pump_present[8][0] 2 status_rtu_pump_present[8][0] 1 status_rtu_pump_present[8][0] 0 status_rtu_pump_present[8][1] 7 status_rtu_pump_present[8][1] 6 status_rtu_pump_present[8][1] 5 status_rtu_pump_present[8][1] 4 status_rtu_pump_present[8][1] 3 status_rtu_pump_present[8][1] 2 status_rtu_pump_present[8][1] 1 status_rtu_pump_present[8][1] 0 status_rtu_pump_present[8][2] 7 status_rtu_pump_present[8][2] 6 status_rtu_pump_present[8][2] 5 status_rtu_pump_present[8][2] 4 437 27 04 Reserved status_rtu_pump_present[8][2] 3 438 27 05 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a SCADA lockout fault being PRESEN status_rtu_pump_present[8][2] 2 439 27 06 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a low flow warning fault being PRESEN status_rtu_pump_present[8][2] 1 440 27 07 Reserved status_rtu_pump_present[8][2] 0 441 27 08 Reserved status_rtu_pump_unackd[0][0] 7 442 27 09 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an under current fault which has bee status_rtu_pump_unackd[0][0] 6 443 27 10 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an over current fault which has bee status_rtu_pump_unackd[0][0] 5 Page 17 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 444 27 11 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a thermal alarm fault which has bee 445 27 12 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a phase fail fault which has bee 446 27 13 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a phase rotation alarm fault which has been 447 27 14 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an earth fault which has bee 448 27 15 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an insulation test fault which has bee 449 28 00 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a low flow fault which has bee 450 28 01 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an analog input 2 fault which has bee 451 28 02 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to an analog input 1 fault which has bee 452 28 03 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 6 fault which has bee 453 28 04 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 5 fault which has bee 454 28 05 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 4 fault which has bee 455 28 06 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 3 fault which has bee 456 28 07 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 2 fault which has bee 457 28 08 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital input 1 fault which has bee 458 28 09 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 3 fault which has bee 459 28 10 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 2 fault which has bee 460 28 11 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a digital output 1 fault which has bee status_rtu_pump_unackd[0][0] 4 status_rtu_pump_unackd[0][0] 3 status_rtu_pump_unackd[0][0] 2 status_rtu_pump_unackd[0][0] 1 status_rtu_pump_unackd[0][0] 0 status_rtu_pump_unackd[0][1] 7 status_rtu_pump_unackd[0][1] 6 status_rtu_pump_unackd[0][1] 5 status_rtu_pump_unackd[0][1] 4 status_rtu_pump_unackd[0][1] 3 status_rtu_pump_unackd[0][1] 2 status_rtu_pump_unackd[0][1] 1 status_rtu_pump_unackd[0][1] 0 status_rtu_pump_unackd[0][2] 7 status_rtu_pump_unackd[0][2] 6 status_rtu_pump_unackd[0][2] 5 status_rtu_pump_unackd[0][2] 4 461 28 12 Reserved status_rtu_pump_unackd[0][2] 3 462 28 13 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[0][2] 2 463 28 14 This bit will be high if the Master MonitorPRO has a faulted pump 1 due to a low flow warning fault which has bee status_rtu_pump_unackd[0][2] 1 464 28 15 Reserved status_rtu_pump_unackd[0][2] 0 465 29 00 Reserved status_rtu_pump_unackd[1][0] 7 466 29 01 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an under current fault which has bee status_rtu_pump_unackd[1][0] 6 Page 18 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 467 29 02 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an over current fault which has bee 468 29 03 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a thermal alarm fault which has bee 469 29 04 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a phase fail fault which has bee 470 29 05 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a phase rotation alarm fault which has been 471 29 06 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an earth fault which has bee 472 29 07 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an insulation test fault which has bee 473 29 08 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a low flow fault which has bee 474 29 09 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an analog input 2 fault which has bee 475 29 10 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to an analog input 1 fault which has bee 476 29 11 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 6 fault which has bee 477 29 12 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 5 fault which has bee 478 29 13 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 4 fault which has bee 479 29 14 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 3 fault which has bee 480 29 15 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 2 fault which has bee 481 30 00 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital input 1 fault which has bee 482 30 01 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 3 fault which has bee 483 30 02 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 2 fault which has bee 484 30 03 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a digital output 1 fault which has bee status_rtu_pump_unackd[1][0] 5 status_rtu_pump_unackd[1][0] 4 status_rtu_pump_unackd[1][0] 3 status_rtu_pump_unackd[1][0] 2 status_rtu_pump_unackd[1][0] 1 status_rtu_pump_unackd[1][0] 0 status_rtu_pump_unackd[1][1] 7 status_rtu_pump_unackd[1][1] 6 status_rtu_pump_unackd[1][1] 5 status_rtu_pump_unackd[1][1] 4 status_rtu_pump_unackd[1][1] 3 status_rtu_pump_unackd[1][1] 2 status_rtu_pump_unackd[1][1] 1 status_rtu_pump_unackd[1][1] 0 status_rtu_pump_unackd[1][2] 7 status_rtu_pump_unackd[1][2] 6 status_rtu_pump_unackd[1][2] 5 status_rtu_pump_unackd[1][2] 4 485 30 04 Reserved status_rtu_pump_unackd[1][2] 3 486 30 05 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[1][2] 2 487 30 06 This bit will be high if the Master MonitorPRO has a faulted pump 2 due to a low flow warning fault which has bee status_rtu_pump_unackd[1][2] 1 488 30 07 Reserved status_rtu_pump_unackd[1][2] 0 489 30 08 Reserved status_rtu_pump_unackd[2][0] 7 Page 19 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 490 30 09 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an under current fault which has bee 491 30 10 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an over current fault which has bee 492 30 11 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a thermal alarm fault which has bee 493 30 12 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a phase fail fault which has bee 494 30 13 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a phase rotation alarm fault which has been 495 30 14 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an earth fault which has bee 496 30 15 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an insulation test fault which has bee 497 31 00 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a low flow fault which has bee 498 31 01 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an analog input 2 fault which has bee 499 31 02 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to an analog input 1 fault which has bee 500 31 03 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 6 fault which has bee 501 31 04 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 5 fault which has bee 502 31 05 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 4 fault which has bee 503 31 06 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 3 fault which has bee 504 31 07 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 2 fault which has bee 505 31 08 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital input 1 fault which has bee 506 31 09 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 3 fault which has bee 507 31 10 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 2 fault which has bee 508 31 11 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a digital output 1 fault which has bee status_rtu_pump_unackd[2][0] 6 status_rtu_pump_unackd[2][0] 5 status_rtu_pump_unackd[2][0] 4 status_rtu_pump_unackd[2][0] 3 status_rtu_pump_unackd[2][0] 2 status_rtu_pump_unackd[2][0] 1 status_rtu_pump_unackd[2][0] 0 status_rtu_pump_unackd[2][1] 7 status_rtu_pump_unackd[2][1] 6 status_rtu_pump_unackd[2][1] 5 status_rtu_pump_unackd[2][1] 4 status_rtu_pump_unackd[2][1] 3 status_rtu_pump_unackd[2][1] 2 status_rtu_pump_unackd[2][1] 1 status_rtu_pump_unackd[2][1] 0 status_rtu_pump_unackd[2][2] 7 status_rtu_pump_unackd[2][2] 6 status_rtu_pump_unackd[2][2] 5 status_rtu_pump_unackd[2][2] 4 509 31 12 Reserved status_rtu_pump_unackd[2][2] 3 510 31 13 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[2][2] 2 511 31 14 This bit will be high if the Master MonitorPRO has a faulted pump 3 due to a low flow warning fault which has bee status_rtu_pump_unackd[2][2] 1 Page 20 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 512 31 15 Reserved status_rtu_pump_unackd[2][2] 0 513 32 00 Reserved status_rtu_pump_unackd[3][0] 7 514 32 01 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an under current fault which has bee status_rtu_pump_unackd[3][0] 6 515 32 02 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an over current fault which has bee 516 32 03 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a thermal alarm fault which has bee 517 32 04 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a phase fail fault which has bee 518 32 05 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a phase rotation alarm fault which has been 519 32 06 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an earth fault which has bee 520 32 07 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an insulation test fault which has bee 521 32 08 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a low flow fault which has bee 522 32 09 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an analog input 2 fault which has bee 523 32 10 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to an analog input 1 fault which has bee 524 32 11 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 6 fault which has bee 525 32 12 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 5 fault which has bee 526 32 13 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 4 fault which has bee 527 32 14 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 3 fault which has bee 528 32 15 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 2 fault which has bee 529 33 00 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital input 1 fault which has bee 530 33 01 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 3 fault which has bee 531 33 02 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 2 fault which has bee 532 33 03 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a digital output 1 fault which has bee status_rtu_pump_unackd[3][0] 5 status_rtu_pump_unackd[3][0] 4 status_rtu_pump_unackd[3][0] 3 status_rtu_pump_unackd[3][0] 2 status_rtu_pump_unackd[3][0] 1 status_rtu_pump_unackd[3][0] 0 status_rtu_pump_unackd[3][1] 7 status_rtu_pump_unackd[3][1] 6 status_rtu_pump_unackd[3][1] 5 status_rtu_pump_unackd[3][1] 4 status_rtu_pump_unackd[3][1] 3 status_rtu_pump_unackd[3][1] 2 status_rtu_pump_unackd[3][1] 1 status_rtu_pump_unackd[3][1] 0 status_rtu_pump_unackd[3][2] 7 status_rtu_pump_unackd[3][2] 6 status_rtu_pump_unackd[3][2] 5 status_rtu_pump_unackd[3][2] 4 533 33 04 Reserved status_rtu_pump_unackd[3][2] 3 534 33 05 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[3][2] 2 Page 21 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 535 33 06 This bit will be high if the Master MonitorPRO has a faulted pump 4 due to a low flow warning fault which has bee status_rtu_pump_unackd[3][2] 1 536 33 07 Reserved status_rtu_pump_unackd[3][2] 0 537 33 08 Reserved status_rtu_pump_unackd[4][0] 7 538 33 09 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an under current fault which has bee status_rtu_pump_unackd[4][0] 6 539 33 10 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an over current fault which has bee 540 33 11 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a thermal alarm fault which has bee 541 33 12 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a phase fail fault which has bee 542 33 13 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a phase rotation alarm fault which has been 543 33 14 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an earth fault which has bee status_rtu_pump_unackd[4][0] 5 status_rtu_pump_unackd[4][0] 4 status_rtu_pump_unackd[4][0] 3 status_rtu_pump_unackd[4][0] 2 status_rtu_pump_unackd[4][0] 1 544 33 15 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an insulation test fault which has bee status_rtu_pump_unackd[4][0] 0 545 34 00 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a low flow fault which has bee status_rtu_pump_unackd[4][1] 7 546 34 01 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an analog input 2 fault which has bee status_rtu_pump_unackd[4][1] 6 547 34 02 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to an analog input 1 fault which has bee status_rtu_pump_unackd[4][1] 5 548 34 03 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 6 fault which has bee status_rtu_pump_unackd[4][1] 4 549 34 04 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 5 fault which has bee status_rtu_pump_unackd[4][1] 3 550 34 05 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 4 fault which has bee status_rtu_pump_unackd[4][1] 2 551 34 06 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 3 fault which has bee status_rtu_pump_unackd[4][1] 1 552 34 07 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 2 fault which has bee status_rtu_pump_unackd[4][1] 0 553 34 08 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital input 1 fault which has bee status_rtu_pump_unackd[4][2] 7 554 34 09 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 3 fault which has bee status_rtu_pump_unackd[4][2] 6 555 34 10 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 2 fault which has bee status_rtu_pump_unackd[4][2] 5 556 34 11 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a digital output 1 fault which has bee status_rtu_pump_unackd[4][2] 4 557 34 12 Reserved status_rtu_pump_unackd[4][2] 3 Page 22 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 558 34 13 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a SCADA lockout fault which has bee 559 34 14 This bit will be high if the Master MonitorPRO has a faulted pump 5 due to a low flow warning fault which has bee status_rtu_pump_unackd[4][2] 2 status_rtu_pump_unackd[4][2] 1 560 34 15 Reserved status_rtu_pump_unackd[4][2] 0 561 35 00 Reserved status_rtu_pump_unackd[5][0] 7 562 35 01 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an under current fault which has bee status_rtu_pump_unackd[5][0] 6 563 35 02 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an over current fault which has bee 564 35 03 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a thermal alarm fault which has bee 565 35 04 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a phase fail fault which has bee 566 35 05 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a phase rotation alarm fault which has been 567 35 06 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an earth fault which has bee 568 35 07 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an insulation test fault which has bee 569 35 08 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a low flow fault which has bee 570 35 09 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an analog input 2 fault which has bee 571 35 10 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to an analog input 1 fault which has bee 572 35 11 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 6 fault which has bee 573 35 12 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 5 fault which has bee 574 35 13 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 4 fault which has bee 575 35 14 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 3 fault which has bee 576 35 15 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 2 fault which has bee 577 36 00 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital input 1 fault which has bee 578 36 01 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 3 fault which has bee 579 36 02 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 2 fault which has bee status_rtu_pump_unackd[5][0] 5 status_rtu_pump_unackd[5][0] 4 status_rtu_pump_unackd[5][0] 3 status_rtu_pump_unackd[5][0] 2 status_rtu_pump_unackd[5][0] 1 status_rtu_pump_unackd[5][0] 0 status_rtu_pump_unackd[5][1] 7 status_rtu_pump_unackd[5][1] 6 status_rtu_pump_unackd[5][1] 5 status_rtu_pump_unackd[5][1] 4 status_rtu_pump_unackd[5][1] 3 status_rtu_pump_unackd[5][1] 2 status_rtu_pump_unackd[5][1] 1 status_rtu_pump_unackd[5][1] 0 status_rtu_pump_unackd[5][2] 7 status_rtu_pump_unackd[5][2] 6 status_rtu_pump_unackd[5][2] 5 Page 23 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 580 36 03 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a digital output 1 fault which has bee status_rtu_pump_unackd[5][2] 4 581 36 04 Reserved status_rtu_pump_unackd[5][2] 3 582 36 05 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[5][2] 2 583 36 06 This bit will be high if the Master MonitorPRO has a faulted pump 6 due to a low flow warning fault which has bee status_rtu_pump_unackd[5][2] 1 584 36 07 Reserved status_rtu_pump_unackd[5][2] 0 585 36 08 Reserved status_rtu_pump_unackd[6][0] 7 586 36 09 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an under current fault which has bee status_rtu_pump_unackd[6][0] 6 587 36 10 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an over current fault which has bee 588 36 11 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a thermal alarm fault which has bee 589 36 12 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a phase fail fault which has bee 590 36 13 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a phase rotation alarm fault which has been 591 36 14 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an earth fault which has bee 592 36 15 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an insulation test fault which has bee 593 37 00 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a low flow fault which has bee 594 37 01 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an analog input 2 fault which has bee 595 37 02 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to an analog input 1 fault which has bee 596 37 03 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 6 fault which has bee 597 37 04 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 5 fault which has bee 598 37 05 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 4 fault which has bee 599 37 06 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 3 fault which has bee 600 37 07 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 2 fault which has bee 601 37 08 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital input 1 fault which has bee 602 37 09 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 3 fault which has bee status_rtu_pump_unackd[6][0] 5 status_rtu_pump_unackd[6][0] 4 status_rtu_pump_unackd[6][0] 3 status_rtu_pump_unackd[6][0] 2 status_rtu_pump_unackd[6][0] 1 status_rtu_pump_unackd[6][0] 0 status_rtu_pump_unackd[6][1] 7 status_rtu_pump_unackd[6][1] 6 status_rtu_pump_unackd[6][1] 5 status_rtu_pump_unackd[6][1] 4 status_rtu_pump_unackd[6][1] 3 status_rtu_pump_unackd[6][1] 2 status_rtu_pump_unackd[6][1] 1 status_rtu_pump_unackd[6][1] 0 status_rtu_pump_unackd[6][2] 7 status_rtu_pump_unackd[6][2] 6 Page 24 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 603 37 10 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 2 fault which has bee 604 37 11 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a digital output 1 fault which has bee status_rtu_pump_unackd[6][2] 5 status_rtu_pump_unackd[6][2] 4 605 37 12 Reserved status_rtu_pump_unackd[6][2] 3 606 37 13 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[6][2] 2 607 37 14 This bit will be high if the Master MonitorPRO has a faulted pump 7 due to a low flow warning fault which has bee status_rtu_pump_unackd[6][2] 1 608 37 15 Reserved status_rtu_pump_unackd[6][2] 0 609 38 00 Reserved status_rtu_pump_unackd[7][0] 7 610 38 01 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an under current fault which has bee status_rtu_pump_unackd[7][0] 6 611 38 02 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an over current fault which has bee 612 38 03 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a thermal alarm fault which has bee 613 38 04 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a phase fail fault which has bee 614 38 05 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a phase rotation alarm fault which has been 615 38 06 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an earth fault which has bee 616 38 07 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an insulation test fault which has bee 617 38 08 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a low flow fault which has bee 618 38 09 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an analog input 2 fault which has bee 619 38 10 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to an analog input 1 fault which has bee 620 38 11 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 6 fault which has bee 621 38 12 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 5 fault which has bee 622 38 13 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 4 fault which has bee 623 38 14 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 3 fault which has bee 624 38 15 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 2 fault which has bee 625 39 00 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital input 1 fault which has bee status_rtu_pump_unackd[7][0] 5 status_rtu_pump_unackd[7][0] 4 status_rtu_pump_unackd[7][0] 3 status_rtu_pump_unackd[7][0] 2 status_rtu_pump_unackd[7][0] 1 status_rtu_pump_unackd[7][0] 0 status_rtu_pump_unackd[7][1] 7 status_rtu_pump_unackd[7][1] 6 status_rtu_pump_unackd[7][1] 5 status_rtu_pump_unackd[7][1] 4 status_rtu_pump_unackd[7][1] 3 status_rtu_pump_unackd[7][1] 2 status_rtu_pump_unackd[7][1] 1 status_rtu_pump_unackd[7][1] 0 status_rtu_pump_unackd[7][2] 7 Page 25 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 626 39 01 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 3 fault which has bee 627 39 02 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 2 fault which has bee 628 39 03 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a digital output 1 fault which has bee status_rtu_pump_unackd[7][2] 6 status_rtu_pump_unackd[7][2] 5 status_rtu_pump_unackd[7][2] 4 629 39 04 Reserved status_rtu_pump_unackd[7][2] 3 630 39 05 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[7][2] 2 631 39 06 This bit will be high if the Master MonitorPRO has a faulted pump 8 due to a low flow warning fault which has bee status_rtu_pump_unackd[7][2] 1 632 39 07 Reserved status_rtu_pump_unackd[7][2] 0 633 39 08 Reserved status_rtu_pump_unackd[8][0] 7 634 39 09 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an under current fault which has bee status_rtu_pump_unackd[8][0] 6 635 39 10 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an over current fault which has bee 636 39 11 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a thermal alarm fault which has bee 637 39 12 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a phase fail fault which has bee 638 39 13 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a phase rotation alarm fault which has been 639 39 14 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an earth fault which has bee 640 39 15 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an insulation test fault which has bee 641 40 00 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a low flow fault which has bee 642 40 01 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an analog input 2 fault which has bee 643 40 02 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to an analog input 1 fault which has bee 644 40 03 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 6 fault which has bee 645 40 04 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 5 fault which has bee 646 40 05 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 4 fault which has bee 647 40 06 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 3 fault which has bee 648 40 07 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 2 fault which has bee status_rtu_pump_unackd[8][0] 5 status_rtu_pump_unackd[8][0] 4 status_rtu_pump_unackd[8][0] 3 status_rtu_pump_unackd[8][0] 2 status_rtu_pump_unackd[8][0] 1 status_rtu_pump_unackd[8][0] 0 status_rtu_pump_unackd[8][1] 7 status_rtu_pump_unackd[8][1] 6 status_rtu_pump_unackd[8][1] 5 status_rtu_pump_unackd[8][1] 4 status_rtu_pump_unackd[8][1] 3 status_rtu_pump_unackd[8][1] 2 status_rtu_pump_unackd[8][1] 1 status_rtu_pump_unackd[8][1] 0 Page 26 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 649 40 08 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital input 1 fault which has bee 650 40 09 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 3 fault which has bee 651 40 10 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 2 fault which has bee 652 40 11 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a digital output 1 fault which has bee status_rtu_pump_unackd[8][2] 7 status_rtu_pump_unackd[8][2] 6 status_rtu_pump_unackd[8][2] 5 status_rtu_pump_unackd[8][2] 4 653 40 12 Reserved status_rtu_pump_unackd[8][2] 3 654 40 13 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a SCADA lockout fault which has bee status_rtu_pump_unackd[8][2] 2 655 40 14 This bit will be high if the Master MonitorPRO has a faulted pump 9 due to a low flow warning fault which has bee status_rtu_pump_unackd[8][2] 1 656 40 15 Reserved status_rtu_pump_unackd[8][2] 0 657 41 00 Reserved status_rtu_cntrlr_present[0] 7 658 41 01 Alarm present on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates battery power h status_rtu_cntrlr_present[0] 6 failed 659 41 02 Alarm present on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates communications h failed between the master MonitorPRO and the other slave units status_rtu_cntrlr_present[0] 5 660 41 03 Reserved status_rtu_cntrlr_present[0] 4 661 41 04 Alarm present on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates an under voltage h status_rtu_cntrlr_present[0] 3 been detected by the master MonitorPRO 662 41 05 Alarm present on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates an over voltage h been detected by the master MonitorPRO status_rtu_cntrlr_present[0] 2 663 41 06 Level 2 alarm present on MonitorPRO status_rtu_cntrlr_present[0] 1 664 41 07 Level 1 alarm present on MonitorPRO status_rtu_cntrlr_present[0] 0 665 41 08 Reserved status_rtu_cntrlr_present[1] 7 666 41 09 Reserved status_rtu_cntrlr_present[1] 6 667 41 10 Reserved status_rtu_cntrlr_present[1] 5 668 41 11 Reserved status_rtu_cntrlr_present[1] 4 669 41 12 Reserved status_rtu_cntrlr_present[1] 3 670 41 13 Reserved status_rtu_cntrlr_present[1] 2 671 41 14 Reserved status_rtu_cntrlr_present[1] 1 672 41 15 Reserved status_rtu_cntrlr_present[1] 0 673 42 00 Reserved status_rtu_cntrlr_present[2] 7 674 42 01 Reserved status_rtu_cntrlr_present[2] 6 675 42 02 Reserved status_rtu_cntrlr_present[2] 5 676 42 03 Reserved status_rtu_cntrlr_present[2] 4 677 42 04 Reserved status_rtu_cntrlr_present[2] 3 678 42 05 Reserved status_rtu_cntrlr_present[2] 2 679 42 06 Reserved status_rtu_cntrlr_present[2] 1 680 42 07 Reserved status_rtu_cntrlr_present[2] 0 681 42 08 Reserved status_rtu_cntrlr_unackd[0] 7 Page 27 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 682 42 09 Alarm UNACKNOWLEDGED on MonitorPRO. This alarm is activated by the master MonitorPRO and indicate battery power fault is clear but has not been acknowledged status_rtu_cntrlr_unackd[0] 6 683 42 10 Alarm UNACKNOWLEDGED on MonitorPRO. This alarm is activated by the master MonitorPRO and indicate status_rtu_cntrlr_unackd[0] 5 communications has been restored but has not been acknowledged 684 42 11 Reserved status_rtu_cntrlr_unackd[0] 4 685 42 12 Alarm UNACKNOWLEDGED on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates th status_rtu_cntrlr_unackd[0] 3 under voltage fault is clear but has not been acknowledged 686 42 13 Alarm UNACKNOWLEDGED on MonitorPRO. This alarm is activated by the master MonitorPRO and indicates th status_rtu_cntrlr_unackd[0] 2 over voltage fault is clear but has not been acknowledged 687 42 14 status_rtu_cntrlr_unackd[0] 1 Level 2 alarm on MonitorPRO is UNACKNOWLEDGED (fault is NOT present but has NOT been acknowledged) 688 42 15 Level 1 alarm on MonitorPRO is UNACKNOWLEDGED (fault is NOT present but has NOT been acknowledged) status_rtu_cntrlr_unackd[0] 0 689 43 00 Reserved status_rtu_cntrlr_unackd[1] 7 690 43 01 Reserved status_rtu_cntrlr_unackd[1] 6 691 43 02 Reserved status_rtu_cntrlr_unackd[1] 5 692 43 03 Reserved status_rtu_cntrlr_unackd[1] 4 693 43 04 Reserved status_rtu_cntrlr_unackd[1] 3 694 43 05 Reserved status_rtu_cntrlr_unackd[1] 2 695 43 06 Reserved status_rtu_cntrlr_unackd[1] 1 696 43 07 Reserved status_rtu_cntrlr_unackd[1] 0 697 43 08 Reserved status_rtu_cntrlr_unackd[2] 7 698 43 09 Reserved status_rtu_cntrlr_unackd[2] 6 699 43 10 Reserved status_rtu_cntrlr_unackd[2] 5 700 43 11 Reserved status_rtu_cntrlr_unackd[2] 4 701 43 12 Reserved status_rtu_cntrlr_unackd[2] 3 702 43 13 Reserved status_rtu_cntrlr_unackd[2] 2 703 43 14 Reserved status_rtu_cntrlr_unackd[2] 1 704 43 15 Reserved status_rtu_cntrlr_unackd[2] 0 705 44 00 This bit is high if digital input 6 from master MonitorPRO is active and low otherwise status_dig[0][0] 7 706 44 01 This bit is high if digital input 5 from master MonitorPRO is active and low otherwise status_dig[0][0] 6 707 44 02 This bit is high if digital input 4 from master MonitorPRO is active and low otherwise status_dig[0][0] 5 708 44 03 This bit is high if digital input 3 from master MonitorPRO is active and low otherwise status_dig[0][0] 4 709 44 04 This bit is high if digital input 2 from master MonitorPRO is active and low otherwise status_dig[0][0] 3 710 44 05 This bit is high if digital input 1 from master MonitorPRO is active and low otherwise status_dig[0][0] 2 711 44 06 This bit is high if digital output 3 from master MonitorPRO is active and low otherwise status_dig[0][0] 1 712 44 07 This bit is high if digital output 2 from master MonitorPRO is active and low otherwise status_dig[0][0] 0 713 44 08 This bit is high if digital output 1 from master MonitorPRO is active and low otherwise status_dig[0][1] 7 714 44 09 Reserved status_dig[0][1] 6 715 44 10 Reserved status_dig[0][1] 5 716 44 11 Reserved status_dig[0][1] 4 717 44 12 Reserved status_dig[0][1] 3 718 44 13 Reserved status_dig[0][1] 2 719 44 14 Reserved status_dig[0][1] 1 Page 28 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 720 44 15 Reserved status_dig[0][1] 0 721 45 00 Reserved status_dig[0][2] 7 722 45 01 Reserved status_dig[0][2] 6 723 45 02 Reserved status_dig[0][2] 5 724 45 03 Reserved status_dig[0][2] 4 725 45 04 Reserved status_dig[0][2] 3 726 45 05 Reserved status_dig[0][2] 2 727 45 06 Reserved status_dig[0][2] 1 728 45 07 Reserved status_dig[0][2] 0 729 45 08 Reserved status_dig[1][0] 7 730 45 09 Reserved status_dig[1][0] 6 731 45 10 Reserved status_dig[1][0] 5 732 45 11 Reserved status_dig[1][0] 4 733 45 12 Reserved status_dig[1][0] 3 734 45 13 Reserved status_dig[1][0] 2 735 45 14 Reserved status_dig[1][0] 1 736 45 15 Reserved status_dig[1][0] 0 737 46 00 Reserved status_dig[1][1] 7 738 46 01 Reserved status_dig[1][1] 6 739 46 02 Reserved status_dig[1][1] 5 740 46 03 Reserved status_dig[1][1] 4 741 46 04 Reserved status_dig[1][1] 3 742 46 05 Reserved status_dig[1][1] 2 743 46 06 Reserved status_dig[1][1] 1 744 46 07 Reserved status_dig[1][1] 0 745 46 08 Reserved status_dig[1][2] 7 746 46 09 Reserved status_dig[1][2] 6 747 46 10 Reserved status_dig[1][2] 5 748 46 11 Reserved status_dig[1][2] 4 749 46 12 Reserved status_dig[1][2] 3 750 46 13 Reserved status_dig[1][2] 2 751 46 14 Reserved status_dig[1][2] 1 752 46 15 Reserved status_dig[1][2] 0 753 47 00 Reserved status_dig[2][0] 7 754 47 01 Reserved status_dig[2][0] 6 755 47 02 Reserved status_dig[2][0] 5 756 47 03 Reserved status_dig[2][0] 4 757 47 04 Reserved status_dig[2][0] 3 758 47 05 Reserved status_dig[2][0] 2 759 47 06 Reserved status_dig[2][0] 1 760 47 07 Reserved status_dig[2][0] 0 761 47 08 Reserved status_dig[2][1] 7 762 47 09 Reserved status_dig[2][1] 6 763 47 10 Reserved status_dig[2][1] 5 Page 29 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 764 47 11 Reserved status_dig[2][1] 4 765 47 12 Reserved status_dig[2][1] 3 766 47 13 Reserved status_dig[2][1] 2 767 47 14 Reserved status_dig[2][1] 1 768 47 15 Reserved status_dig[2][1] 0 769 48 00 Reserved status_dig[2][2] 7 770 48 01 Reserved status_dig[2][2] 6 771 48 02 Reserved status_dig[2][2] 5 772 48 03 Reserved status_dig[2][2] 4 773 48 04 Reserved status_dig[2][2] 3 774 48 05 Reserved status_dig[2][2] 2 775 48 06 Reserved status_dig[2][2] 1 776 48 07 Reserved status_dig[2][2] 0 777 48 08 Reserved status_unackd_pump_counters[0] 7 778 48 09 Reserved status_unackd_pump_counters[0] 6 779 48 10 Reserved status_unackd_pump_counters[0] 5 780 48 11 Reserved status_unackd_pump_counters[0] 4 781 48 12 Reserved status_unackd_pump_counters[0] 3 782 48 13 Reserved status_unackd_pump_counters[0] 2 783 48 14 Reserved status_unackd_pump_counters[0] 1 784 48 15 Reserved status_unackd_pump_counters[0] 0 785 49 00 Reserved status_unackd_pump_counters[1] 7 786 49 01 Reserved status_unackd_pump_counters[1] 6 787 49 02 Reserved status_unackd_pump_counters[1] 5 788 49 03 Reserved status_unackd_pump_counters[1] 4 789 49 04 Reserved status_unackd_pump_counters[1] 3 790 49 05 Reserved status_unackd_pump_counters[1] 2 791 49 06 Reserved status_unackd_pump_counters[1] 1 792 49 07 Reserved status_unackd_pump_counters[1] 0 793 49 08 Reserved status_unackd_pump_counters[2] 7 794 49 09 Reserved status_unackd_pump_counters[2] 6 795 49 10 Reserved status_unackd_pump_counters[2] 5 796 49 11 Reserved status_unackd_pump_counters[2] 4 797 49 12 Reserved status_unackd_pump_counters[2] 3 798 49 13 Reserved status_unackd_pump_counters[2] 2 799 49 14 Reserved status_unackd_pump_counters[2] 1 800 49 15 Reserved status_unackd_pump_counters[2] 0 801 50 00 Reserved status_unackd_pump_counters[3] 7 802 50 01 Reserved status_unackd_pump_counters[3] 6 803 50 02 Reserved status_unackd_pump_counters[3] 5 804 50 03 Reserved status_unackd_pump_counters[3] 4 805 50 04 Reserved status_unackd_pump_counters[3] 3 806 50 05 Reserved status_unackd_pump_counters[3] 2 807 50 06 Reserved status_unackd_pump_counters[3] 1 Page 30 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 808 50 07 Reserved status_unackd_pump_counters[3] 0 809 50 08 Reserved status_unackd_pump_counters[4] 7 810 50 09 Reserved status_unackd_pump_counters[4] 6 811 50 10 Reserved status_unackd_pump_counters[4] 5 812 50 11 Reserved status_unackd_pump_counters[4] 4 813 50 12 Reserved status_unackd_pump_counters[4] 3 814 50 13 Reserved status_unackd_pump_counters[4] 2 815 50 14 Reserved status_unackd_pump_counters[4] 1 816 50 15 Reserved status_unackd_pump_counters[4] 0 817 51 00 Reserved status_unackd_pump_counters[5] 7 818 51 01 Reserved status_unackd_pump_counters[5] 6 819 51 02 Reserved status_unackd_pump_counters[5] 5 820 51 03 Reserved status_unackd_pump_counters[5] 4 821 51 04 Reserved status_unackd_pump_counters[5] 3 822 51 05 Reserved status_unackd_pump_counters[5] 2 823 51 06 Reserved status_unackd_pump_counters[5] 1 824 51 07 Reserved status_unackd_pump_counters[5] 0 825 51 08 Reserved status_unackd_pump_counters[6] 7 826 51 09 Reserved status_unackd_pump_counters[6] 6 827 51 10 Reserved status_unackd_pump_counters[6] 5 828 51 11 Reserved status_unackd_pump_counters[6] 4 829 51 12 Reserved status_unackd_pump_counters[6] 3 830 51 13 Reserved status_unackd_pump_counters[6] 2 831 51 14 Reserved status_unackd_pump_counters[6] 1 832 51 15 Reserved status_unackd_pump_counters[6] 0 833 52 00 Reserved status_unackd_pump_counters[7] 7 834 52 01 Reserved status_unackd_pump_counters[7] 6 835 52 02 Reserved status_unackd_pump_counters[7] 5 836 52 03 Reserved status_unackd_pump_counters[7] 4 837 52 04 Reserved status_unackd_pump_counters[7] 3 838 52 05 Reserved status_unackd_pump_counters[7] 2 839 52 06 Reserved status_unackd_pump_counters[7] 1 840 52 07 Reserved status_unackd_pump_counters[7] 0 841 52 08 Reserved status_unackd_pump_counters[8] 7 842 52 09 Reserved status_unackd_pump_counters[8] 6 843 52 10 Reserved status_unackd_pump_counters[8] 5 844 52 11 Reserved status_unackd_pump_counters[8] 4 845 52 12 Reserved status_unackd_pump_counters[8] 3 846 52 13 Reserved status_unackd_pump_counters[8] 2 847 52 14 Reserved status_unackd_pump_counters[8] 1 848 52 15 Reserved status_unackd_pump_counters[8] 0 849 53 00 Reserved status_unackd_rtu_counter 7 850 53 01 Reserved status_unackd_rtu_counter 6 851 53 02 Reserved status_unackd_rtu_counter 5 Page 31 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 852 53 03 Reserved status_unackd_rtu_counter 4 853 53 04 Reserved status_unackd_rtu_counter 3 854 53 05 Reserved status_unackd_rtu_counter 2 855 53 06 Reserved status_unackd_rtu_counter 1 856 53 07 Reserved status_unackd_rtu_counter 0 857 53 08 Reserved status_rtu_comms_fail[0] 7 858 53 09 Reserved status_rtu_comms_fail[0] 6 859 53 10 Reserved status_rtu_comms_fail[0] 5 860 53 11 Reserved status_rtu_comms_fail[0] 4 861 53 12 Reserved status_rtu_comms_fail[0] 3 862 53 13 Reserved status_rtu_comms_fail[0] 2 863 53 14 Reserved status_rtu_comms_fail[0] 1 864 53 15 Reserved status_rtu_comms_fail[0] 0 865 54 00 Reserved status_rtu_comms_fail[1] 0 866 54 01 Reserved status_rtu_comms_fail[2] 0 867 54 02 Overflow fault present from master MonitorPRO Status_rtu_cntrlr_present2[0] 1 868 54 03 Reserved Status_rtu_cntrlr_present2[0] 0 869 54 04 Reserved Status_rtu_cntrlr_present2[1] 1 870 54 05 Reserved Status_rtu_cntrlr_present2[1] 0 871 54 06 Reserved Status_rtu_cntrlr_present2[2] 1 872 54 07 Reserved Status_rtu_cntrlr_present2[2] 0 873 54 08 Reserved Status_rtu_cntrlr_unackd2[0] 1 874 54 09 Reserved Status_rtu_cntrlr_unackd2[0] 0 875 54 10 Reserved Status_rtu_cntrlr_unackd2[1] 1 876 54 11 Reserved Status_rtu_cntrlr_unackd2[1] 0 877 54 12 Reserved Status_rtu_cntrlr_unackd2[2] 1 878 54 13 Reserved Status_rtu_cntrlr_unackd2[2] 0 879 54 14 Status from master pump controller: Status of sensor probe input 10 (bottom probe) MTxPCCtrlStatus[0][2] 7 880 54 15 Status from master pump controller: Status of sensor probe input 9 MTxPCCtrlStatus[0][2] 6 881 55 00 Status from master pump controller: Status of sensor probe input 8 MTxPCCtrlStatus[0][2] 5 882 55 01 Status from master pump controller: Status of sensor probe input 7 MTxPCCtrlStatus[0][2] 4 883 55 02 Status from master pump controller: Status of sensor probe input 6 MTxPCCtrlStatus[0][2] 3 884 55 03 Status from master pump controller: Status of sensor probe input 5 MTxPCCtrlStatus[0][2] 2 885 55 04 Status from master pump controller: Status of sensor probe input 4 MTxPCCtrlStatus[0][2] 1 886 55 05 Status from master pump controller: Status of sensor probe input 3 MTxPCCtrlStatus[0][2] 0 887 55 06 Status from master pump controller: Status of sensor probe input 2 MTxPCCtrlStatus[0][3] 1 888 55 07 Status from master pump controller: Status of sensor probe input 1 (top probe) MTxPCCtrlStatus[0][3] 0 889 55 08 Status from master pump controller: Status of digital output 1 MTxPCCtrlStatus[0][7] 0 890 55 09 Status from master pump controller: Status of digital output 2 MTxPCCtrlStatus[0][7] 1 891 55 10 Status from master pump controller: Status of digital output 3 MTxPCCtrlStatus[0][7] 2 892 55 11 Status from master pump controller: Status of digital output 4 MTxPCCtrlStatus[0][7] 3 893 55 12 Status from master pump controller: Status of digital output 5 MTxPCCtrlStatus[0][7] 4 894 55 13 Status from master pump controller: Alarm 1 PRESENT MTxPCCtrlStatus[0][8] 0 895 55 14 Status from master pump controller: Alarm 1 UNACKNOWLEDGED MTxPCCtrlStatus[0][8] 1 Page 32 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 896 55 15 Status from master pump controller: Alarm 1 Muted MTxPCCtrlStatus[0][8] 2 897 56 00 Status from master pump controller: Alarm 2 PRESENT MTxPCCtrlStatus[0][8] 3 898 56 01 Status from master pump controller: Alarm 2 UNACKNOWLEDGED MTxPCCtrlStatus[0][8] 4 899 56 02 Status from master pump controller: Alarm 2 Muted MTxPCCtrlStatus[0][8] 5 900 56 03 Status from master pump controller: Leak level status MTxPCCtrlStatus[0][9] 4 901 56 04 Status from master pump controller: Special input status MTxPCCtrlStatus[0][9] 5 902 56 05 Status from slave 1 controller: Status of sensor probe input 10 (bottom probe) MTxPCCtrlStatus[1][2] 7 903 56 06 Status from slave 1 controller: Status of sensor probe input 9 MTxPCCtrlStatus[1][2] 6 904 56 07 Status from slave 1 controller: Status of sensor probe input 8 MTxPCCtrlStatus[1][2] 5 905 56 08 Status from slave 1 controller: Status of sensor probe input 7 MTxPCCtrlStatus[1][2] 4 906 56 09 Status from slave 1 controller: Status of sensor probe input 6 MTxPCCtrlStatus[1][2] 3 907 56 10 Status from slave 1 controller: Status of sensor probe input 5 MTxPCCtrlStatus[1][2] 2 908 56 11 Status from slave 1 controller: Status of sensor probe input 4 MTxPCCtrlStatus[1][2] 1 909 56 12 Status from slave 1 controller: Status of sensor probe input 3 MTxPCCtrlStatus[1][2] 0 910 56 13 Status from slave 1 controller: Status of sensor probe input 2 MTxPCCtrlStatus[1][3] 1 911 56 14 Status from slave 1 controller: Status of sensor probe input 1 (top probe) MTxPCCtrlStatus[1][3] 0 912 56 15 Status from slave 1 controller: Status of digital output 1 MTxPCCtrlStatus[1][7] 0 913 57 00 Status from slave 1 controller: Status of digital output 2 MTxPCCtrlStatus[1][7] 1 914 57 01 Status from slave 1 controller: Status of digital output 3 MTxPCCtrlStatus[1][7] 2 915 57 02 Status from slave 1 controller: Status of digital output 4 MTxPCCtrlStatus[1][7] 3 916 57 03 Status from slave 1 controller: Status of digital output 5 MTxPCCtrlStatus[1][7] 4 917 57 04 Status from slave 1 controller: Alarm 1 PRESENT MTxPCCtrlStatus[1][8] 0 918 57 05 Status from slave 1 controller: Alarm 1 UNACKNOWLEDGED MTxPCCtrlStatus[1][8] 1 919 57 06 Status from slave 1 controller: Alarm 1 Muted MTxPCCtrlStatus[1][8] 2 920 57 07 Status from slave 1 controller: Alarm 2 PRESENT MTxPCCtrlStatus[1][8] 3 921 57 08 Status from slave 1 controller: Alarm 2 UNACKNOWLEDGED MTxPCCtrlStatus[1][8] 4 922 57 09 Status from slave 1 controller: Alarm 2 Muted MTxPCCtrlStatus[1][8] 5 923 57 10 Status from slave 1 controller: Leak level status MTxPCCtrlStatus[1][9] 4 924 57 11 Status from slave 1 controller: Special input status MTxPCCtrlStatus[1][9] 5 925 57 12 Status from slave 2 controller: Status of sensor probe input 10 (bottom probe) MTxPCCtrlStatus[2][2] 7 926 57 13 Status from slave 2 controller: Status of sensor probe input 9 MTxPCCtrlStatus[2][2] 6 927 57 14 Status from slave 2 controller: Status of sensor probe input 8 MTxPCCtrlStatus[2][2] 5 928 57 15 Status from slave 2 controller: Status of sensor probe input 7 MTxPCCtrlStatus[2][2] 4 929 58 00 Status from slave 2 controller: Status of sensor probe input 6 MTxPCCtrlStatus[2][2] 3 930 58 01 Status from slave 2 controller: Status of sensor probe input 5 MTxPCCtrlStatus[2][2] 2 931 58 02 Status from slave 2 controller: Status of sensor probe input 4 MTxPCCtrlStatus[2][2] 1 932 58 03 Status from slave 2 controller: Status of sensor probe input 3 MTxPCCtrlStatus[2][2] 0 933 58 04 Status from slave 2 controller: Status of sensor probe input 2 MTxPCCtrlStatus[2][3] 1 934 58 05 Status from slave 2 controller: Status of sensor probe input 1 (top probe) MTxPCCtrlStatus[2][3] 0 935 58 06 Status from slave 2 controller: Status of digital output 1 MTxPCCtrlStatus[2][7] 0 936 58 07 Status from slave 2 controller: Status of digital output 2 MTxPCCtrlStatus[2][7] 1 937 58 08 Status from slave 2 controller: Status of digital output 3 MTxPCCtrlStatus[2][7] 2 938 58 09 Status from slave 2 controller: Status of digital output 4 MTxPCCtrlStatus[2][7] 3 939 58 10 Status from slave 2 controller: Status of digital output 5 MTxPCCtrlStatus[2][7] 4 Page 33 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 940 58 11 Status from slave 2 controller: Alarm 1 PRESENT MTxPCCtrlStatus[2][8] 0 941 58 12 Status from slave 2 controller: Alarm 1 UNACKNOWLEDGED MTxPCCtrlStatus[2][8] 1 942 58 13 Status from slave 2 controller: Alarm 1 Muted MTxPCCtrlStatus[2][8] 2 943 58 14 Status from slave 2 controller: Alarm 2 PRESENT MTxPCCtrlStatus[2][8] 3 944 58 15 Status from slave 2 controller: Alarm 2 UNACKNOWLEDGED MTxPCCtrlStatus[2][8] 4 945 59 00 Status from slave 2 controller: Alarm 2 Muted MTxPCCtrlStatus[2][8] 5 946 59 01 Status from slave 2 controller: Leak level status MTxPCCtrlStatus[2][9] 4 947 59 02 Status from slave 2 controller: Special input status MTxPCCtrlStatus[2][9] 5 948 59 03 This input represents the local digital input 1 of the Procon V N/A 949 59 04 This input represents the local digital input 2 of the Procon V N/A 950 59 05 This input represents the local digital input 3 of the Procon V N/A 951 59 06 This input represents the local digital input 4 of the Procon V N/A 952 59 07 This input represents the local digital input 5 of the Procon V N/A 953 59 08 This input represents the local digital input 6 of the Procon V N/A 954 59 09 Reserved N/A 955 59 10 Reserved N/A 956 59 11 This bit is high if communication is lost between the Procon V and the master MonitorPRO and low otherwise N/A 957 59 12 This bit is high if the information is older than a selectable amount of time and low otherwise. The selectable period of time for stale data, is configurable under the Procon V configuration menu. 958 59 13 Master Telemetry Input AC Status_mit_ekim[21] 0 959 59 14 Master Telemetry Input AN Status_mit_ekim[21] 1 960 59 15 Master Telemetry Input AD Status_mit_ekim[21] 2 961 60 00 Master Telemetry Input AS Status_mit_ekim[21] 3 962 60 01 Master Telemetry Input BC Status_mit_ekim[21] 4 963 60 02 Master Telemetry Input BN Status_mit_ekim[21] 5 964 60 03 Master Telemetry Input BD Status_mit_ekim[21] 6 965 60 04 Master Telemetry Input BS Status_mit_ekim[21] 7 966 60 05 Master Telemetry Input CC Status_mit_ekim[22] 0 967 60 06 Master Telemetry Input CN Status_mit_ekim[22] 1 968 60 07 Master Telemetry Input CD Status_mit_ekim[22] 2 969 60 08 Master Telemetry Input CS Status_mit_ekim[22] 3 970 60 09 Master Telemetry Input PL Status_mit_ekim[22] 4 971 60 10 Master Telemetry Input PF Status_mit_ekim[22] 5 972 60 11 Master Telemetry Input PS Status_mit_ekim[22] 6 973 60 12 Master Telemetry Input KL Status_mit_ekim[22] 7 974 60 13 Slave 1 Telemetry Input AC Status_mit_ekim[23] 0 975 60 14 Slave 1 Telemetry Input AN Status_mit_ekim[23] 1 976 60 15 Slave 1 Telemetry Input AD Status_mit_ekim[23] 2 977 61 00 Slave 1 Telemetry Input AS Status_mit_ekim[23] 3 978 61 01 Slave 1 Telemetry Input BC Status_mit_ekim[23] 4 979 61 02 Slave 1 Telemetry Input BN Status_mit_ekim[23] 5 980 61 03 Slave 1 Telemetry Input BD Status_mit_ekim[23] 6 981 61 04 Slave 1 Telemetry Input BS Status_mit_ekim[23] 7 N/A Page 34 Input Status

Input Status: Single bit digital (read only) * The mirrored input register offest needs to be added to the configured "Mirror Base" of the Procon V to get actual register number. Index Mirrored Input Register Description Multitrode Cross-Reference Offset * Bit Variable Bit 982 61 05 Slave 1 Telemetry Input CC Status_mit_ekim[24] 0 983 61 06 Slave 1 Telemetry Input CN Status_mit_ekim[24] 1 984 61 07 Slave 1 Telemetry Input CD Status_mit_ekim[24] 2 985 61 08 Slave 1 Telemetry Input CS Status_mit_ekim[24] 3 986 61 09 Slave 1 Telemetry Input PL Status_mit_ekim[24] 4 987 61 10 Slave 1 Telemetry Input PF Status_mit_ekim[24] 5 988 61 11 Slave 1 Telemetry Input PS Status_mit_ekim[24] 6 989 61 12 Slave 1 Telemetry Input KL Status_mit_ekim[24] 7 990 61 13 Slave 2 Telemetry Input AC Status_mit_ekim[25] 0 991 61 14 Slave 2 Telemetry Input AN Status_mit_ekim[25] 1 992 61 15 Slave 2 Telemetry Input AD Status_mit_ekim[25] 2 993 62 00 Slave 2 Telemetry Input AS Status_mit_ekim[25] 3 994 62 01 Slave 2 Telemetry Input BC Status_mit_ekim[25] 4 995 62 02 Slave 2 Telemetry Input BN Status_mit_ekim[25] 5 996 62 03 Slave 2 Telemetry Input BD Status_mit_ekim[25] 6 997 62 04 Slave 2 Telemetry Input BS Status_mit_ekim[25] 7 998 62 05 Slave 2 Telemetry Input CC Status_mit_ekim[26] 0 999 62 06 Slave 2 Telemetry Input CN Status_mit_ekim[26] 1 1000 62 07 Slave 2 Telemetry Input CD Status_mit_ekim[26] 2 1001 62 08 Slave 2 Telemetry Input CS Status_mit_ekim[26] 3 1002 62 09 Slave 2 Telemetry Input PL Status_mit_ekim[26] 4 1003 62 10 Slave 2 Telemetry Input PF Status_mit_ekim[26] 5 1004 62 11 Slave 2 Telemetry Input PS Status_mit_ekim[26] 6 1005 62 12 Slave 2 Telemetry Input KL Status_mit_ekim[26] 7 1006 62 13 Spare Status_mit_ekim[27] 0 1007 62 14 Spare Status_mit_ekim[27] 1 1008 62 15 Spare Status_mit_ekim[27] 2 1009 63 00 Spare Status_mit_ekim[27] 3 1010 63 01 Spare Status_mit_ekim[27] 4 1011 63 02 Spare Status_mit_ekim[27] 5 1012 63 03 Spare Status_mit_ekim[27] 6 1013 63 04 Spare Status_mit_ekim[27] 7 1014 63 05 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1015 63 06 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1016 63 07 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1017 63 08 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1018 63 09 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1019 63 10 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1020 63 11 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1021 63 12 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1022 63 13 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1023 63 14 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A 1024 63 15 Not used (exists to make number of input statuses divisible by 16 - see release notes v1.05) N/A Page 35 Input Status

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 1 This control relates to the master MonitorPRO. When read, this control reflects the status of Binary Input 712 (Obj 01, Index 712). Turning the control on will energise relay 1. Turning the control off will de-energise relay 1. 0x3C 0x00 0x3C 0x3C 0x11 0x3C 2 This control relates to the master MonitorPRO. When read, this control reflects the status of Binary Input 711 (Obj 01, Index 711). Turning the control on will energise relay 2. Turning the control off will de-energise relay 2. 0x3C 0x02 0x3C 0x3C 0x22 0x3C 3 This control relates to the master MonitorPRO. When read, this control reflects the status of Binary Input 710 (Obj 01, Index 710). Turning the control on will energise relay 3. Turning the control off will de-energise relay 3. 0x3C 0x03 0x3C 0x3C 0x33 0x3C 4 This control relates to the master pump controller. When read, this control reflects the status of Binary Input 888 (Obj 01, Index 888). Turning the control on will energise relay 1. Turning the control off will de-energise relay 1. 5 This control relates to the master pump controller. When read, this control reflects the status of Binary Input 889 (Obj 01, Index 889). Turning the control on will energise relay 2. Turning the control off will de-energise relay 2. 6 This control relates to the master pump controller. When read, this control reflects the status of Binary Input 890 (Obj 01, Index 890). Turning the control on will energise relay 3. Turning the control off will de-energise relay 3. 7 This control relates to the master pump controller. When read, this control reflects the status of Binary Input 891 (Obj 01, Index 891). Turning the control on will energise relay 4. Turning the control off will de-energise relay 4. 8 This control relates to the master pump controller. When read, this control reflects the status of Binary Input 892 (Obj 01, Index 892). Turning the control on will energise relay 5. Turning the control off will de-energise relay 5. 0x80 [A] 0x00 0x00 0x80 0x80 [A] 0x00 0x00 0x80 0x80 [A] 0x02 0x00 0x80 0x80 [A] 0x02 0x02 0x80 0x80 [A] 0x04 0x00 0x80 0x80 [A] 0x04 0x04 0x80 0x80 [A] 0x08 0x00 0x80 0x80 [A] 0x08 0x08 0x80 0x80 [A] 0x10 0x00 0x80 0x80 [A] 0x10 0x10 0x80 9 Reserved 0x80 [B] 0x00 0x00 0x80 0x80 [B] 0x00 0x00 0x80 10 Reserved 0x80 [B] 0x02 0x00 0x80 0x80 [B] 0x02 0x02 0x80 11 Reserved 0x80 [B] 0x04 0x00 0x80 0x80 [B] 0x04 0x04 0x80 12 Reserved 0x80 [B] 0x08 0x00 0x80 0x80 [B] 0x08 0x08 0x80 13 Reserved 0x80 [B] 0x10 0x00 0x80 0x80 [B] 0x10 0x10 0x80 14 Reserved 0x80 [C] 0x00 0x00 0x80 0x80 [C] 0x00 0x00 0x80 15 Reserved 0x80 [C] 0x02 0x00 0x80 0x80 [C] 0x02 0x02 0x80 16 Reserved 0x80 [C] 0x04 0x00 0x80 0x80 [C] 0x04 0x04 0x80 17 Reserved 0x80 [C] 0x08 0x00 0x80 0x80 [C] 0x08 0x08 0x80 Page 36 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 18 Reserved 0x80 [C] 0x10 0x00 0x80 0x80 [C] 0x10 0x10 0x80 19 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 1 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 45 below). 20 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 2 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 46 below). 21 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 3 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 47 below). 22 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 4 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 48 below). 23 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 5 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 49 below). 24 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 6 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 50 below). 25 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 7 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 51 below). 26 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 8 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 52 below). 27 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will fault pump 9 of group 1. Turning the control off will remove the pump fault condition but not reset the indication on the unit. ie. The fault will be unacknowleged (to reset the indication see binary output 53 below). 0x83 [A] 0x00 0x00 0x83 0x83 [A] 0x00 0x01 0x83 0x83 [A] 0x01 0x00 0x83 0x83 [A] 0x01 0x01 0x83 0x83 [A] 0x02 0x00 0x83 0x83 [A] 0x02 0x01 0x83 0x83 [A] 0x03 0x00 0x83 0x83 [A] 0x03 0x01 0x83 0x83 [A] 0x04 0x00 0x83 0x83 [A] 0x04 0x01 0x83 0x83 [A] 0x05 0x00 0x83 0x83 [A] 0x05 0x01 0x83 0x83 [A] 0x06 0x00 0x83 0x83 [A] 0x06 0x01 0x83 0x83 [A] 0x07 0x00 0x83 0x83 [A] 0x07 0x01 0x83 0x83 [A] 0x08 0x00 0x83 0x83 [A] 0x08 0x01 0x83 28 Reserved 0x83 [B] 0x00 0x00 0x83 0x83 [B] 0x00 0x01 0x83 29 Reserved 0x83 [B] 0x01 0x00 0x83 0x83 [B] 0x01 0x01 0x83 30 Reserved 0x83 [B] 0x02 0x00 0x83 0x83 [B] 0x02 0x01 0x83 31 Reserved 0x83 [B] 0x03 0x00 0x83 0x83 [B] 0x03 0x01 0x83 Page 37 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 32 Reserved 0x83 [B] 0x04 0x00 0x83 0x83 [B] 0x04 0x01 0x83 33 Reserved 0x83 [B] 0x05 0x00 0x83 0x83 [B] 0x05 0x01 0x83 34 Reserved 0x83 [B] 0x06 0x00 0x83 0x83 [B] 0x06 0x01 0x83 35 Reserved 0x83 [B] 0x07 0x00 0x83 0x83 [B] 0x07 0x01 0x83 36 Reserved 0x83 [B] 0x08 0x00 0x83 0x83 [B] 0x08 0x01 0x83 37 Reserved 0x83 [C] 0x00 0x00 0x83 0x83 [C] 0x00 0x01 0x83 38 Reserved 0x83 [C] 0x01 0x00 0x83 0x83 [C] 0x01 0x01 0x83 39 Reserved 0x83 [C] 0x02 0x00 0x83 0x83 [C] 0x02 0x01 0x83 40 Reserved 0x83 [C] 0x03 0x00 0x83 0x83 [C] 0x03 0x01 0x83 41 Reserved 0x83 [C] 0x04 0x00 0x83 0x83 [C] 0x04 0x01 0x83 42 Reserved 0x83 [C] 0x05 0x00 0x83 0x83 [C] 0x05 0x01 0x83 43 Reserved 0x83 [C] 0x06 0x00 0x83 0x83 [C] 0x06 0x01 0x83 44 Reserved 0x83 [C] 0x07 0x00 0x83 0x83 [C] 0x07 0x01 0x83 45 Reserved 0x83 [C] 0x08 0x00 0x83 0x83 [C] 0x08 0x01 0x83 46 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 1 fault. Turning the control off has no action. No Action 0x85 [A] 0x00 0x85 47 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 2 fault. Turning the control off has no action. No Action 0x85 [A] 0x01 0x85 48 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 3 fault. Turning the control off has no action. No Action 0x85 [A] 0x02 0x85 49 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 4 fault. Turning the control off has no action. No Action 0x85 [A] 0x03 0x85 50 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 5 fault. Turning the control off has no action. No Action 0x85 [A] 0x04 0x85 51 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 6 fault. Turning the control off has no action. No Action 0x85 [A] 0x05 0x85 52 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 7 fault. Turning the control off has no action. No Action 0x85 [A] 0x06 0x85 53 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 8 fault. Turning the control off has no action. No Action 0x85 [A] 0x07 0x85 54 This control relates to the first group of pumps only. When read, the last control attempt is returned (0 = off, 1 = on). Turning the control on will acknowledge pump 9 fault. Turning the control off has no action. No Action 0x85 [A] 0x08 0x85 55 Reserved No Action 0x85 [B] 0x00 0x85 Page 38 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 56 Reserved No Action 0x85 [B] 0x01 0x85 57 Reserved No Action 0x85 [B] 0x02 0x85 58 Reserved No Action 0x85 [B] 0x03 0x85 59 Reserved No Action 0x85 [B] 0x04 0x85 60 Reserved No Action 0x85 [B] 0x05 0x85 61 Reserved No Action 0x85 [B] 0x06 0x85 62 Reserved No Action 0x85 [B] 0x07 0x85 63 Reserved No Action 0x85 [B] 0x08 0x85 64 Reserved No Action 0x85 [C] 0x00 0x85 65 Reserved No Action 0x85 [C] 0x01 0x85 66 Reserved No Action 0x85 [C] 0x02 0x85 67 Reserved No Action 0x85 [C] 0x03 0x85 68 Reserved No Action 0x85 [C] 0x04 0x85 69 Reserved No Action 0x85 [C] 0x05 0x85 70 Reserved No Action 0x85 [C] 0x06 0x85 71 Reserved No Action 0x85 [C] 0x07 0x85 72 Reserved No Action 0x85 [C] 0x08 0x85 73 Turning the control on will cause pump 1 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x00 0x01 0x86 74 Turning the control on will cause pump 1 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x00 0x00 0x86 75 Turning the control on will cause pump 1 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 76 Turning the control on will cause pump 2 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 77 Turning the control on will cause pump 2 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 78 Turning the control on will cause pump 2 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 79 Turning the control on will cause pump 3 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 80 Turning the control on will cause pump 3 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x00 0x03 0x86 No action 0x86 [A] 0x01 0x01 0x86 No action 0x86 [A] 0x01 0x00 0x86 No action 0x86 [A] 0x01 0x03 0x86 No action 0x86 [A] 0x02 0x01 0x86 No action 0x86 [A] 0x02 0x00 0x86 81 Turning the control on will cause pump 3 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 82 Turning the control on will cause pump 4 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x02 0x03 0x86 No action 0x86 [A] 0x03 0x01 0x86 Page 39 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 83 Turning the control on will cause pump 4 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x03 0x00 0x86 84 Turning the control on will cause pump 4 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 85 Turning the control on will cause pump 5 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 86 Turning the control on will cause pump 5 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x03 0x03 0x86 No action 0x86 [A] 0x04 0x01 0x86 No action 0x86 [A] 0x04 0x00 0x86 87 Turning the control on will cause pump 5 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 88 Turning the control on will cause pump 6 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 89 Turning the control on will cause pump 6 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x04 0x03 0x86 No action 0x86 [A] 0x05 0x01 0x86 No action 0x86 [A] 0x05 0x00 0x86 90 Turning the control on will cause pump 6 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 91 Turning the control on will cause pump 7 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 92 Turning the control on will cause pump 7 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x05 0x03 0x86 No action 0x86 [A] 0x06 0x01 0x86 No action 0x86 [A] 0x06 0x00 0x86 93 Turning the control on will cause pump 7 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 94 Turning the control on will cause pump 8 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 95 Turning the control on will cause pump 8 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x06 0x03 0x86 No action 0x86 [A] 0x07 0x01 0x86 No action 0x86 [A] 0x07 0x00 0x86 96 Turning the control on will cause pump 8 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). 97 Turning the control on will cause pump 9 to switch OFF and the OFF LED will flash on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x07 0x03 0x86 No action 0x86 [A] 0x08 0x01 0x86 Page 40 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 98 Turning the control on will cause pump 9 to switch to AUTO mode and the AUTO mode LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x08 0x00 0x86 99 Turning the control on will cause pump 9 to switch to MANUAL mode and the MANUAL/HAND LED will illuminate on the unit. Turning the control off has no action. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x86 [A] 0x08 0x03 0x86 100 Reserved No action 0x86 [B] 0x00 0x01 0x86 101 Reserved No action 0x86 [B] 0x00 0x00 0x86 102 Reserved No action 0x86 [B] 0x00 0x03 0x86 103 Reserved No action 0x86 [B] 0x01 0x01 0x86 104 Reserved No action 0x86 [B] 0x01 0x00 0x86 105 Reserved No action 0x86 [B] 0x01 0x03 0x86 106 Reserved No action 0x86 [B] 0x02 0x01 0x86 107 Reserved No action 0x86 [B] 0x02 0x00 0x86 108 Reserved No action 0x86 [B] 0x02 0x03 0x86 109 Reserved No action 0x86 [B] 0x03 0x01 0x86 110 Reserved No action 0x86 [B] 0x03 0x00 0x86 111 Reserved No action 0x86 [B] 0x03 0x03 0x86 112 Reserved No action 0x86 [B] 0x04 0x01 0x86 113 Reserved No action 0x86 [B] 0x04 0x00 0x86 114 Reserved No action 0x86 [B] 0x04 0x03 0x86 115 Reserved No action 0x86 [B] 0x05 0x01 0x86 116 Reserved No action 0x86 [B] 0x05 0x00 0x86 117 Reserved No action 0x86 [B] 0x05 0x03 0x86 118 Reserved No action 0x86 [B] 0x06 0x01 0x86 119 Reserved No action 0x86 [B] 0x06 0x00 0x86 120 Reserved No action 0x86 [B] 0x06 0x03 0x86 121 Reserved No action 0x86 [B] 0x07 0x01 0x86 122 Reserved No action 0x86 [B] 0x07 0x00 0x86 123 Reserved No action 0x86 [B] 0x07 0x03 0x86 124 Reserved No action 0x86 [B] 0x08 0x01 0x86 125 Reserved No action 0x86 [B] 0x08 0x00 0x86 126 Reserved No action 0x86 [B] 0x08 0x03 0x86 127 Reserved No action 0x86 [C] 0x00 0x01 0x86 128 Reserved No action 0x86 [C] 0x00 0x00 0x86 129 Reserved No action 0x86 [C] 0x00 0x03 0x86 130 Reserved No action 0x86 [C] 0x01 0x01 0x86 131 Reserved No action 0x86 [C] 0x01 0x00 0x86 132 Reserved No action 0x86 [C] 0x01 0x03 0x86 133 Reserved No action 0x86 [C] 0x02 0x01 0x86 134 Reserved No action 0x86 [C] 0x02 0x00 0x86 135 Reserved No action 0x86 [C] 0x02 0x03 0x86 Page 41 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 136 Reserved No action 0x86 [C] 0x03 0x01 0x86 137 Reserved No action 0x86 [C] 0x03 0x00 0x86 138 Reserved No action 0x86 [C] 0x03 0x03 0x86 139 Reserved No action 0x86 [C] 0x04 0x01 0x86 140 Reserved No action 0x86 [C] 0x04 0x00 0x86 141 Reserved No action 0x86 [C] 0x04 0x03 0x86 142 Reserved No action 0x86 [C] 0x05 0x01 0x86 143 Reserved No action 0x86 [C] 0x05 0x00 0x86 144 Reserved No action 0x86 [C] 0x05 0x03 0x86 145 Reserved No action 0x86 [C] 0x06 0x01 0x86 146 Reserved No action 0x86 [C] 0x06 0x00 0x86 147 Reserved No action 0x86 [C] 0x06 0x03 0x86 148 Reserved No action 0x86 [C] 0x07 0x01 0x86 149 Reserved No action 0x86 [C] 0x07 0x00 0x86 150 Reserved No action 0x86 [C] 0x07 0x03 0x86 151 Reserved No action 0x86 [C] 0x08 0x01 0x86 152 Reserved No action 0x86 [C] 0x08 0x00 0x86 153 Reserved No action 0x86 [C] 0x08 0x03 0x86 154 Turning the control on will cause group 1 units to be placed into PEAK LEVEL mode. Turning the control off w return the group back to normal control. When read, the last control attempt is returned (0 = off, 1 = on). 0x87 [A] 0x00 0x87 0x87 [A] 0x00 0x87 155 Reserved 0x87 [B] 0x00 0x87 0x87 [A] 0x00 0x87 156 Reserved 0x87 [C] 0x00 0x87 0x87 [A] 0x00 0x87 157 Turning the control on will cause all pumps in group 1 to be switched OFF (set in HOLD OUT mode) and the available LED will flash. Turning the control off will remove the HOLD OUT condition and return all pumps to normal operation. When read, the last control attempt is returned (0 = off, 1 = on). 0x88 [A] 0x00 0x88 0x88 [A] 0x00 0x88 158 Reserved 0x88 [B] 0x00 0x88 0x88 [A] 0x00 0x88 159 Reserved 0x88 [C] 0x00 0x88 0x88 [A] 0x00 0x88 160 Turning the control on will cause one pump in group 1 to start. The pump to start will be the "next to start" pum in the set sequence. For the pump to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 161 Turning the control on will cause two pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 162 Turning the control on will cause three pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x89 [A] 0x00 0x89 No action 0x89 [A] 0x02 0x89 No action 0x89 [A] 0x03 0x89 Page 42 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 163 Turning the control on will cause four pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 164 Turning the control on will cause five pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 165 Turning the control on will cause six pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 166 Turning the control on will cause seven pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 167 Turning the control on will cause eight pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 168 Turning the control on will cause nine pumps in group 1 to start. The pumps to start will be the "next to start" pumps in the set sequence. For the pumps to start, the deactivation level has to be covered and the pumps will stop once the deactivation level has been cleared. Turning the control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). No action 0x89 [A] 0x04 0x89 No action 0x89 [A] 0x05 0x89 No action 0x89 [A] 0x06 0x89 No action 0x89 [A] 0x07 0x89 No action 0x89 [A] 0x08 0x89 No action 0x89 [A] 0x09 0x89 169 Reserved No action 0x89 [B] 0x00 0x89 170 Reserved No action 0x89 [B] 0x02 0x89 171 Reserved No action 0x89 [B] 0x03 0x89 172 Reserved No action 0x89 [B] 0x04 0x89 173 Reserved No action 0x89 [B] 0x05 0x89 174 Reserved No action 0x89 [B] 0x06 0x89 175 Reserved No action 0x89 [B] 0x07 0x89 176 Reserved No action 0x89 [B] 0x08 0x89 177 Reserved No action 0x89 [B] 0x09 0x89 178 Reserved No action 0x89 [C] 0x00 0x89 179 Reserved No action 0x89 [C] 0x02 0x89 180 Reserved No action 0x89 [C] 0x03 0x89 181 Reserved No action 0x89 [C] 0x04 0x89 182 Reserved No action 0x89 [C] 0x05 0x89 183 Reserved No action 0x89 [C] 0x06 0x89 184 Reserved No action 0x89 [C] 0x07 0x89 185 Reserved No action 0x89 [C] 0x08 0x89 186 Reserved No action 0x89 [C] 0x09 0x89 Page 43 Output Coils

Output Coils: Single bit digital (read / write) Note: [A], [B] and [C] represent the three slave group/unit numbers from the Procon V configuration menu. Index Description Multitrode command for control operation On (1) Off (0) 187 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 947) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 188 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 948) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 189 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 949) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 190 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 950) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 191 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 951) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). 192 Clear latched input 1. Turning this control on will force the Procon V Digital Input 1 (Object 01, Index 952) to th state of the associated physical input. Turning this control off has no effect. When read, the last control attempt is returned (0 = off, 1 = on). N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A 193 Reserved 194 Reserved 195 Procon Reset. Turning this on will force the Procon V protocol converter to restart. N/A N/A Page 44 Output Coils

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 1 Reservevd Memory: 0x0002 2 Current liquid level as an ASCII value between 0 and 200 (00hex to C8hex). status_quick[0] 3 Current value of master MonitorPRO's analog input 1. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 hex). 4 Current value of master MonitorPRO's analog input 2. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 hex). 5 Current value of master MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 hex). 6 Current value of master MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). When the MonitorPRO's analog outputis configured to transmit the "current level" then zero level will be 4mA and this point will show 40 (28 hex) while 100% level would be 20mA and show 100 (C8 hex). status_ana[0][0] status_ana[0][1] status_ana[0][2] status_ana[0][3] 7 Reserved status_ana[0][4] 8 Current RAW value of master MonitorPRO's analog input 1. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to status_ana[0][5] 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. 9 Current RAW value of master MonitorPRO's analog input 2. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to status_ana[0][6] 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. 10 Current value of slave 1 MonitorPRO's analog input 1. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 status_ana[1][0] hex). 11 Current value of slave 1 MonitorPRO's analog input 2. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 status_ana[1][1] hex). 12 Current value of slave 1 MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma status_ana[1][2] ie. 200 (C8 hex). 13 Current value of slave 1 MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). When the MonitorPRO's status_ana[1][3] analog outputis configured to transmit the "current level" then zero level will be 4mA and this point will show 40 (28 hex) while 100% level would be 20mA and show 100 (C8 hex). 14 Reserved status_ana[1][4] 15 Current RAW value of slave 1 MonitorPRO's analog input 1. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to status_ana[1][5] 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. 16 Current RAW value of slave 1 MonitorPRO's analog input 2. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to status_ana[1][6] 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. 17 Current value of slave 2 MonitorPRO's analog input 1. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 status_ana[2][0] hex). 18 Current value of slave 2 MonitorPRO's analog input 2. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma ie. 200 (C8 status_ana[2][1] hex). 19 Current value of slave 2 MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). The value is limited to 20 ma status_ana[2][2] ie. 200 (C8 hex). 20 Current value of slave 2 MonitorPRO's incoming DC supply voltage. This value is scaled to be between 0 and 200 (00 hex to C8 hex). When the MonitorPRO's status_ana[2][3] analog outputis configured to transmit the "current level" then zero level will be 4mA and this point will show 40 (28 hex) while 100% level would be 20mA and show 100 (C8 hex). 21 Reserved status_ana[2][4] 22 Current RAW value of slave 2 MonitorPRO's analog input 1. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. status_ana[2][5] Page 45 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 23 Current RAW value of slave 2 MonitorPRO's analog input 2. This value is NOT scaled to be between 0 and 65535 (0000 hex to FFFF hex). The value is limited to 21.1 ma ie. (FF00 hex) where 330 counts = 0.1 ma. status_ana[2][6] 24 Present value of current on red [L1] phase of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[0][0] 25 Present value of current on white [L2] phase of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[0][1] 26 Present value of current on blue [L3] phase of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[0][2] 27 Average value of current on all 3 phases of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[0][3] 28 Total flow volume of pump 1. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[0][4] 29 Last flow volume of pump 1. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[0][5] 30 Reserved Status_numeric[0][6] 31 Hours last run of pump 1. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[0][7] 32 Starts per hour of pump 1. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[0][8] 33 Last flow rate of pump 1. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[0][9] 34 Insulation resistance of pump 1. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[0][10] 35 Phase voltage of pump 1. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[0][11] 36 Average phase voltage of pump 1. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[0][12] 37 Present value of current on red [L1] phase of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[1][0] 38 Present value of current on white [L2] phase of pump 1. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[1][1] 39 Present value of current on blue [L3] phase of pump 2. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[1][2] 40 Average value of current on all 3 phases of pump 2. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[1][3] 41 Total flow volume of pump 2. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[1][4] 42 Last flow volume of pump 2. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[1][5] 43 Reserved Status_numeric[1][6] 44 Hours last run of pump 2. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[1][7] 45 Starts per hour of pump 2. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[1][8] 46 Last flow rate of pump 2. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[1][9] 47 Insulation resistance of pump 2. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[1][10] 48 Phase voltage of pump 2. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[1][11] 49 Average phase voltage of pump 2. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[1][12] 50 Present value of current on red [L1] phase of pump 3. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[2][0] 51 Present value of current on white [L2] phase of pump 3. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[2][1] 52 Present value of current on blue [L3] phase of pump 3. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[2][2] 53 Average value of current on all 3 phases of pump 3. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[2][3] 54 Total flow volume of pump 3. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[2][4] 55 Last flow volume of pump 3. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[2][5] 56 Reserved Status_numeric[2][6] 57 Hours last run of pump 3. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[2][7] 58 Starts per hour of pump 3. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[2][8] 59 Last flow rate of pump 3. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[2][9] 60 Insulation resistance of pump 3. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[2][10] 61 Phase voltage of pump 3. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[2][11] 62 Average phase voltage of pump 3. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[2][12] 63 Present value of current on red [L1] phase of pump 4. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[3][0] Page 46 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 64 Present value of current on white [L2] phase of pump 4. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[3][1] 65 Present value of current on blue [L3] phase of pump 4. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[3][2] 66 Average value of current on all 3 phases of pump 4. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[3][3] 67 Total flow volume of pump 4. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[3][4] 68 Last flow volume of pump 4. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[3][5] 69 Reserved Status_numeric[3][6] 70 Hours last run of pump 4. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[3][7] 71 Starts per hour of pump 4. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[3][8] 72 Last flow rate of pump 4. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[3][9] 73 Insulation resistance of pump 4. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[3][10] 74 Phase voltage of pump 4. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[3][11] 75 Average phase voltage of pump 4. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[3][12] 76 Present value of current on red [L1] phase of pump 5. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[4][0] 77 Present value of current on white [L2] phase of pump 5. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[4][1] 78 Present value of current on blue [L3] phase of pump 5. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[4][2] 79 Average value of current on all 3 phases of pump 5. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[4][3] 80 Total flow volume of pump 5. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[4][4] 81 Last flow volume of pump 5. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[4][5] 82 Reserved Status_numeric[4][6] 83 Hours last run of pump 5. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[4][7] 84 Starts per hour of pump 5. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[4][8] 85 Last flow rate of pump 5. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[4][9] 86 Insulation resistance of pump 5. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[4][10] 87 Phase voltage of pump 5. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[4][11] 88 Average phase voltage of pump 5. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[4][12] 89 Present value of current on red [L1] phase of pump 6. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[5][0] 90 Present value of current on white [L2] phase of pump 6. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[5][1] 91 Present value of current on blue [L3] phase of pump 6. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[5][2] 92 Average value of current on all 3 phases of pump 6. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[5][3] 93 Total flow volume of pump 6. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[5][4] 94 Last flow volume of pump 6. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[5][5] 95 Reserved Status_numeric[5][6] 96 Hours last run of pump 6. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[5][7] 97 Starts per hour of pump 6. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[5][8] 98 Last flow rate of pump 6. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[5][9] 99 Insulation resistance of pump 6. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[5][10] 100 Phase voltage of pump 6. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[5][11] 101 Average phase voltage of pump 6. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[5][12] 102 Present value of current on red [L1] phase of pump 7. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[6][0] 103 Present value of current on white [L2] phase of pump 7. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[6][1] 104 Present value of current on blue [L3] phase of pump 7. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[6][2] 105 Average value of current on all 3 phases of pump 7. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[6][3] Page 47 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 106 Total flow volume of pump 7. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[6][4] 107 Last flow volume of pump 7. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[6][5] 108 Reserved Status_numeric[6][6] 109 Hours last run of pump 7. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[6][7] 110 Starts per hour of pump 7. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[6][8] 111 Last flow rate of pump 7. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[6][9] 112 Insulation resistance of pump 7. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[6][10] 113 Phase voltage of pump 7. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[6][11] 114 Average phase voltage of pump 7. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[6][12] 115 Present value of current on red [L1] phase of pump 8. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[7][0] 116 Present value of current on white [L2] phase of pump 8. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[7][1] 117 Present value of current on blue [L3] phase of pump 8. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[7][2] 118 Average value of current on all 3 phases of pump 8. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[7][3] 119 Total flow volume of pump 8. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[7][4] 120 Last flow volume of pump 8. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[7][5] 121 Reserved Status_numeric[7][6] 122 Hours last run of pump 8. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[7][7] 123 Starts per hour of pump 8. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[7][8] 124 Last flow rate of pump 8. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[7][9] 125 Insulation resistance of pump 8. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[7][10] 126 Phase voltage of pump 8. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[7][11] 127 Average phase voltage of pump 8. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[7][12] 128 Present value of current on red [L1] phase of pump 9. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[8][0] 129 Present value of current on white [L2] phase of pump 9. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[8][1] 130 Present value of current on blue [L3] phase of pump 9. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[8][2] 131 Average value of current on all 3 phases of pump 9. Scaling is 0.1A per bit count (eg. 000A hex = 1.0A, 000B hex = 1.1A). Status_numeric[8][3] 132 Total flow volume of pump 9. Scaling is 1000 liters per bit count (eg. 000A hex = 10kL, 000B hex = 11kL). Status_numeric[8][4] 133 Last flow volume of pump 9. Scaling is 1 liter per bit count (eg. 000A hex = 10L, 000B hex = 11L). Status_numeric[8][5] 134 Reserved Status_numeric[8][6] 135 Hours last run of pump 9. Scaling is 0.1 liter per bit count (eg. 000A hex = 1min, 000B hex = 1.1min). Status_numeric[8][7] 136 Starts per hour of pump 9. Scaling is 1 start per 10 bit counts (eg. 000A hex = 1start/hour, 000B hex = not possible). Status_numeric[8][8] 137 Last flow rate of pump 9. Scaling is seconds per litre (eg. 000A hex = 10 L/s, 000B hex = 11L/s). Status_numeric[8][9] 138 Insulation resistance of pump 9. Scaling is 0.1 Mohm per bit count (eg. 000A hex = 1 Mohm, 000B hex = 1.1 Mohm). Status_numeric[8][10] 139 Phase voltage of pump 9. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[8][11] 140 Average phase voltage of pump 9. Scaling is 0.1 volts per bit count (eg. 000A hex = 1 VAC, 000B hex = 1.1 VAC). Status_numeric[8][12] 141 Most significant 16 bits of 32 bit cumulative total from digital input 1 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][0] (16:31) 142 Least significant 16 bits of 32 bit cumulative total from digital input 1 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][0] (0:15) 143 Most significant 16 bits of 32 bit cumulative total from digital input 2 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][1] (16:31) 144 Least significant 16 bits of 32 bit cumulative total from digital input 2 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][1] (0:15) 145 Most significant 16 bits of 32 bit cumulative total from digital input 3 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][2] (16:31) 146 Least significant 16 bits of 32 bit cumulative total from digital input 3 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][2] (0:15) 147 Most significant 16 bits of 32 bit cumulative total from digital input 4 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][3] (16:31) Page 48 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 148 Least significant 16 bits of 32 bit cumulative total from digital input 4 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][3] (0:15) 149 Most significant 16 bits of 32 bit cumulative total from digital input 5 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][4] (16:31) 150 Least significant 16 bits of 32 bit cumulative total from digital input 5 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][4] (0:15) 151 Most significant 16 bits of 32 bit cumulative total from digital input 6 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][5] (16:31) 152 Least significant 16 bits of 32 bit cumulative total from digital input 6 of the master MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[0][5] (0:15) 153 Most significant 16 bits of 32 bit cumulative total from digital input 1 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][0] (16:31) 154 Least significant 16 bits of 32 bit cumulative total from digital input 1 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][0] (0:15) 155 Most significant 16 bits of 32 bit cumulative total from digital input 2 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][1] (16:31) 156 Least significant 16 bits of 32 bit cumulative total from digital input 2 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][1] (0:15) 157 Most significant 16 bits of 32 bit cumulative total from digital input 3 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][2] (16:31) 158 Least significant 16 bits of 32 bit cumulative total from digital input 3 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][2] (0:15) 159 Most significant 16 bits of 32 bit cumulative total from digital input 4 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][3] (16:31) 160 Least significant 16 bits of 32 bit cumulative total from digital input 4 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][3] (0:15) 161 Most significant 16 bits of 32 bit cumulative total from digital input 5 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][4] (16:31) 162 Least significant 16 bits of 32 bit cumulative total from digital input 5 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][4] (0:15) 163 Most significant 16 bits of 32 bit cumulative total from digital input 6 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][5] (16:31) 164 Least significant 16 bits of 32 bit cumulative total from digital input 6 of the slave 1 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[1][5] (0:15) 165 Most significant 16 bits of 32 bit cumulative total from digital input 1 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][0] (16:31) 166 Least significant 16 bits of 32 bit cumulative total from digital input 1 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][0] (0:15) 167 Most significant 16 bits of 32 bit cumulative total from digital input 2 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][1] (16:31) 168 Least significant 16 bits of 32 bit cumulative total from digital input 2 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][1] (0:15) 169 Most significant 16 bits of 32 bit cumulative total from digital input 3 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][2] (16:31) 170 Least significant 16 bits of 32 bit cumulative total from digital input 3 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][2] (0:15) 171 Most significant 16 bits of 32 bit cumulative total from digital input 4 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][3] (16:31) 172 Least significant 16 bits of 32 bit cumulative total from digital input 4 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][3] (0:15) 173 Most significant 16 bits of 32 bit cumulative total from digital input 5 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][4] (16:31) 174 Least significant 16 bits of 32 bit cumulative total from digital input 5 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][4] (0:15) 175 Most significant 16 bits of 32 bit cumulative total from digital input 6 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][5] (16:31) 176 Least significant 16 bits of 32 bit cumulative total from digital input 6 of the slave 2 MonitorPRO. This accumulator needs to be enabled for this feature. status_pulsed[2][5] (0:15) 177 Most significant 16 bits of 32 bit cumulative number of faults on pump 1 status_fault_accumulator[0] (16:31) 178 Least significant 16 bits of 32 bit cumulative number of faults on pump 1 status_fault_accumulator[0] (0:15) 179 Most significant 16 bits of 32 bit cumulative number of faults on pump 2 status_fault_accumulator[1] (16:31) 180 Least significant 16 bits of 32 bit cumulative number of faults on pump 2 status_fault_accumulator[1] (0:15) 181 Most significant 16 bits of 32 bit cumulative number of faults on pump 3 status_fault_accumulator[2] (16:31) 182 Least significant 16 bits of 32 bit cumulative number of faults on pump 3 status_fault_accumulator[2] (0:15) 183 Most significant 16 bits of 32 bit cumulative number of faults on pump 4 status_fault_accumulator[3] (16:31) 184 Least significant 16 bits of 32 bit cumulative number of faults on pump 4 status_fault_accumulator[3] (0:15) 185 Most significant 16 bits of 32 bit cumulative number of faults on pump 5 status_fault_accumulator[4] (16:31) 186 Least significant 16 bits of 32 bit cumulative number of faults on pump 5 status_fault_accumulator[4] (0:15) 187 Most significant 16 bits of 32 bit cumulative number of faults on pump 6 status_fault_accumulator[5] (16:31) 188 Least significant 16 bits of 32 bit cumulative number of faults on pump 6 status_fault_accumulator[5] (0:15) 189 Most significant 16 bits of 32 bit cumulative number of faults on pump 7 status_fault_accumulator[6] (16:31) Page 49 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 190 Least significant 16 bits of 32 bit cumulative number of faults on pump 7 status_fault_accumulator[6] (0:15) 191 Most significant 16 bits of 32 bit cumulative number of faults on pump 8 status_fault_accumulator[7] (16:31) 192 Least significant 16 bits of 32 bit cumulative number of faults on pump 8 status_fault_accumulator[7] (0:15) 193 Most significant 16 bits of 32 bit cumulative number of faults on pump 9 status_fault_accumulator[8] (16:31) 194 Least significant 16 bits of 32 bit cumulative number of faults on pump 9 status_fault_accumulator[8] (0:15) 195 Most significant 16 bits of 32 bit cumulative number of hours run on pump 1. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[0] (16:31) 196 Least significant 16 bits of 32 bit cumulative number of hours run on pump 1. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[0] (0:15) 197 Most significant 16 bits of 32 bit cumulative number of hours run on pump 2. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[1] (16:31) 198 Least significant 16 bits of 32 bit cumulative number of hours run on pump 2. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[1] (0:15) 199 Most significant 16 bits of 32 bit cumulative number of hours run on pump 3. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[2] (16:31) 200 Least significant 16 bits of 32 bit cumulative number of hours run on pump 3. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[2] (0:15) 201 Most significant 16 bits of 32 bit cumulative number of hours run on pump 4. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[3] (16:31) 202 Least significant 16 bits of 32 bit cumulative number of hours run on pump 4. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[3] (0:15) 203 Most significant 16 bits of 32 bit cumulative number of hours run on pump 5. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[4] (16:31) 204 Least significant 16 bits of 32 bit cumulative number of hours run on pump 5. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[4] (0:15) 205 Most significant 16 bits of 32 bit cumulative number of hours run on pump 6. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[5] (16:31) 206 Least significant 16 bits of 32 bit cumulative number of hours run on pump 6. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[5] (0:15) 207 Most significant 16 bits of 32 bit cumulative number of hours run on pump 7. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[6] (16:31) 208 Least significant 16 bits of 32 bit cumulative number of hours run on pump 7. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[6] (0:15) 209 Most significant 16 bits of 32 bit cumulative number of hours run on pump 8. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[7] (16:31) 210 Least significant 16 bits of 32 bit cumulative number of hours run on pump 8. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[7] (0:15) 211 Most significant 16 bits of 32 bit cumulative number of hours run on pump 9. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[8] (16:31) 212 Least significant 16 bits of 32 bit cumulative number of hours run on pump 9. Scaling is 0.1 hours per count (ie 000A hex = 1 hour, 000B hex = 1.1 hours). status_hrs_run[8] (0:15) 213 Most significant 16 bits of 32 bit last flow volume on pump 1. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[0] (16:31) Page 50 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 214 Least significant 16 bits of 32 bit last flow volume on pump 1. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[0] (0:15) 215 Most significant 16 bits of 32 bit last flow volume on pump 2. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[1] (16:31) 216 Least significant 16 bits of 32 bit last flow volume on pump 2. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[1] (0:15) 217 Most significant 16 bits of 32 bit last flow volume on pump 3. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[2] (16:31) 218 Least significant 16 bits of 32 bit last flow volume on pump 3. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[2] (0:15) 219 Most significant 16 bits of 32 bit last flow volume on pump 4. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[3] (16:31) 220 Least significant 16 bits of 32 bit last flow volume on pump 4. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[3] (0:15) 221 Most significant 16 bits of 32 bit last flow volume on pump 5. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[4] (16:31) 222 Least significant 16 bits of 32 bit last flow volume on pump 5. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[4] (0:15) 223 Most significant 16 bits of 32 bit last flow volume on pump 6. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[5] (16:31) 224 Least significant 16 bits of 32 bit last flow volume on pump 6. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[5] (0:15) 225 Most significant 16 bits of 32 bit last flow volume on pump 7. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[6] (16:31) 226 Least significant 16 bits of 32 bit last flow volume on pump 7. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[6] (0:15) 227 Most significant 16 bits of 32 bit last flow volume on pump 8. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[7] (16:31) 228 Least significant 16 bits of 32 bit last flow volume on pump 8. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[7] (0:15) 229 Most significant 16 bits of 32 bit last flow volume on pump 9. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[8] (16:31) 230 Least significant 16 bits of 32 bit last flow volume on pump 9. Scaling is 1 litre per count (ie 000A hex = 10 L, 000B hex = 11 L). statuslastvolume[8] (0:15) 231 Most significant 16 bits of 32 bit total volume pumped for the station. statusstationtotalflow (16:31) 232 Least significant 16 bits of 32 bit total volume pumped for the station. statusstationtotalflow (0:15) 233 Station inflow rate. Scaling is in litres per second. statusstationflowrates[0] 234 Station outflow rate. Scaling is in litres per second. statusstationflowrates[1] 235 Most significant 16 bits of 32 bit cumulative starts for pump 1 status_starts_pump[0] (16:31) 236 Least significant 16 bits of 32 bit cumulative starts for pump 1 status_starts_pump[0] (0:15) 237 Most significant 16 bits of 32 bit cumulative starts for pump 2 status_starts_pump[1] (16:31) 238 Least significant 16 bits of 32 bit cumulative starts for pump 2 status_starts_pump[1] (0:15) 239 Most significant 16 bits of 32 bit cumulative starts for pump 3 status_starts_pump[2] (16:31) 240 Least significant 16 bits of 32 bit cumulative starts for pump 3 status_starts_pump[2] (0:15) 241 Most significant 16 bits of 32 bit cumulative starts for pump 4 status_starts_pump[3] (16:31) 242 Least significant 16 bits of 32 bit cumulative starts for pump 4 status_starts_pump[3] (0:15) 243 Most significant 16 bits of 32 bit cumulative starts for pump 5 status_starts_pump[4] (16:31) 244 Least significant 16 bits of 32 bit cumulative starts for pump 5 status_starts_pump[4] (0:15) 245 Most significant 16 bits of 32 bit cumulative starts for pump 6 status_starts_pump[5] (16:31) 246 Least significant 16 bits of 32 bit cumulative starts for pump 6 status_starts_pump[5] (0:15) 247 Most significant 16 bits of 32 bit cumulative starts for pump 7 status_starts_pump[6] (16:31) 248 Least significant 16 bits of 32 bit cumulative starts for pump 7 status_starts_pump[6] (0:15) 249 Most significant 16 bits of 32 bit cumulative starts for pump 8 status_starts_pump[7] (16:31) 250 Least significant 16 bits of 32 bit cumulative starts for pump 8 status_starts_pump[7] (0:15) 251 Most significant 16 bits of 32 bit cumulative starts for pump 9 status_starts_pump[8] (16:31) 252 Least significant 16 bits of 32 bit cumulative starts for pump 9 status_starts_pump[8] (0:15) 253 Day of last over flow StatusDateLastOflow[0] 254 Month of last over flow StatusDateLastOflow[1] 255 Year of last over flow StatusDateLastOflow[2] Page 51 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 256 Hour of last over flow StatusTimeLastOflow[0] 257 Minute of last over flow StatusTimeLastOflow[1] 258 Second of last over flow StatusTimeLastOflow[2] 259 Most significant 16 bits of 32 bit duration of last overflow. Scaling is in 0.1 minutes per count (eg. 000A hex = 1 min, 000B hex = 1.1 min). StatusDurationLastOflow (16:31) 260 Least significant 16 bits of 32 bit duration of last overflow. Scaling is in 0.1 minutes per count (eg. 000A hex = 1 min, 000B hex = 1.1 min). StatusDurationLastOflow (0:15) 261 Most significant 16 bits of 32 bit total number of overflows StatusTotalNumberOflows (16:31) 262 Least significant 16 bits of 32 bit total number of overflows StatusTotalNumberOflows (0:15) 263 Number of days of over flow StatusTotalOflowTime[0] 264 Number of hours of over flow StatusTotalOflowTime[1] 265 Number of minutes of over flow StatusTotalOflowTime[2] 266 Number of seconds of over flow StatusTotalOflowTime[3] 267 Most significant 16 bits of 32 bit last overflow volume. Scaling is 1 litre per count. StatusLastOflowVolume (16:31) 268 Least significant 16 bits of 32 bit last overflow volume. Scaling is 1 litre per count. StatusLastOflowVolume (0:15) 269 Most significant 16 bits of 32 bit total overflow volume. Scaling is 1000 litres per count. StatusTotalOflowVolume (16:31) 270 Least significant 16 bits of 32 bit total overflow volume. Scaling is 1000 litres per count. StatusTotalOflowVolume (0:15) 271 Current level value being used by the master pump controller. Scaling is as an ASCII value between 0 and 200. MTxPCCtrlStatus[0][0] 272 Current probe level value being used by the master pump controller. Scaling is as an ASCII value between 0 and 200. MTxPCCtrlStatus[0][1] 273 Current value of analog input 1 of the master pump controller. Scaling is as an ASCII value between 0 and 200. MTxPCCtrlStatus[0][4] 274 Current value of analog input 2 of the master pump controller. Scaling is as an ASCII value between 0 and 200. MTxPCCtrlStatus[0][5] 275 Current value of analog output 1 of the master pump controller. Scaling is as an ASCII value between 0 and 200. MTxPCCtrlStatus[0][6] 276 Current I/P device chosen. Level input device: 01 hex = standard multitrode probe, 02 hex = analog sensor only, 03 hex = analog sensor with probe sensor override, 04 hex = via telemetry. MTxPCCtrlStatus[0][9] bits 0-3 277 Key lock input: 00 hex = off, 01 hex = partial, 02 hex = full. MTxPCCtrlStatus[0][9] bits 6-7 278 Reserved MTxPCCtrlStatus[1][0] 279 Reserved MTxPCCtrlStatus[1][1] 280 Reserved MTxPCCtrlStatus[1][4] 281 Reserved MTxPCCtrlStatus[1][5] 282 Reserved MTxPCCtrlStatus[1][6] 283 Reserved MTxPCCtrlStatus[1][9] bits 0-3 284 Reserved MTxPCCtrlStatus[1][9] bits 6-7 285 Reserved MTxPCCtrlStatus[2][0] 286 Reserved MTxPCCtrlStatus[2][1] 287 Reserved MTxPCCtrlStatus[2][4] 288 Reserved MTxPCCtrlStatus[2][5] 289 Reserved MTxPCCtrlStatus[2][6] 290 Reserved MTxPCCtrlStatus[2][9] bits 0-3 291 Reserved MTxPCCtrlStatus[2][9] bits 6-7 292 Voltage on the red [L1] phase. Scaling is 0.1 volts per count (eg. 000A hex = 1 VAC, 000B = 1.1 VAC) status_rtu_phasevolts[0][0] 293 Voltage on the white [L2] phase. Scaling is 0.1 volts per count (eg. 000A hex = 1 VAC, 000B = 1.1 VAC) status_rtu_phasevolts[0][1] 294 Voltage on the blue [L3] phase. Scaling is 0.1 volts per count (eg. 000A hex = 1 VAC, 000B = 1.1 VAC) status_rtu_phasevolts[0][2] 295 Reserved status_rtu_phasevolts[1][0] 296 Reserved status_rtu_phasevolts[1][1] Page 52 Input Registers

Input Register: 16 bit regsister (read only) Index Description Multitrode Cross-Reference Variable 297 Reserved status_rtu_phasevolts[1][2] 298 Reserved status_rtu_phasevolts[2][0] 299 Reserved status_rtu_phasevolts[2][1] 300 Reserved status_rtu_phasevolts[2][2] 301 Reserved N/A (Number of pending commands in Procon V command queue) 302 Scaled value of Procon V analog input 1. Range and calibration is set via the Procon V configuration menu. N/A (From Procon V hardware) 303 Scaled value of Procon V analog input 2. Range and calibration is set via the Procon V configuration menu. N/A (From Procon V hardware) 304 Reserved N/A (From Procon V hardware) 305 Reserved N/A (From Procon V hardware) 306 Reserved N/A (From Procon V hardware) 307 Reserved N/A (From Procon V hardware) 308 Reserved N/A (From Procon V hardware) 309 Reserved N/A (From Procon V hardware) 310 Reserved N/A (Number of RTUs specified in last Assembled Status Response) 311 Reserved N/A (Number of pumps specified in last Assembled Status Response) 312 GucpWorkingOrder[0][0] Status_mit_ekim[0] 313 GucpWorkingOrder[0][1] Status_mit_ekim[1] 314 GucpWorkingOrder[0][2] Status_mit_ekim[2] 315 GucpWorkingOrder[0][3] Status_mit_ekim[3] 316 GucpWorkingOrder[0][4] Status_mit_ekim[4] 317 GucpWorkingOrder[0][5] Status_mit_ekim[5] 318 GucpWorkingOrder[0][6] Status_mit_ekim[6] 319 GucpWorkingOrder[0][7] Status_mit_ekim[7] 320 GucpWorkingOrder[0][8] Status_mit_ekim[8] 321 GucpWorkingOrder[1][0] Status_mit_ekim[9] 322 GucpWorkingOrder[1][1] Status_mit_ekim[10] 323 GucpWorkingOrder[1][2] Status_mit_ekim[11] 324 GucpWorkingOrder[1][3] Status_mit_ekim[12] 325 GucpWorkingOrder[1][4] Status_mit_ekim[13] 326 GucpWorkingOrder[1][5] Status_mit_ekim[14] 327 GucpWorkingOrder[1][6] Status_mit_ekim[15] 328 GucpWorkingOrder[1][7] Status_mit_ekim[16] 329 GucpWorkingOrder[1][8] Status_mit_ekim[17] 330 GucpWorkingGroup[0] Status_mit_ekim[18] 331 GucpWorkingGroup[1] Status_mit_ekim[19] 332 GucNTS Status_mit_ekim[20] Page 53 Input Registers

Holding Register: 16 bit register (read / write) Index Description Multitrode command when written 1 When read, this register will return the current analogue output value. Writting to this register will set the analogue output of the Master MonitorPRO to the value written. 0x81 [A] [VALUE] 0x81 2 Reserved 0x81 [B] [VALUE] 0x81 3 Reserved 0x81 [C] [VALUE] 0x81 4 When read, this register will return the current level of the Master Pump Controller. When written to, this byte will set the current level of the master level input device. However, the level can only be modified if the master level input device has been configured to allow "Communications Level" to be used (i.e. EDS 5 set to 7). 0x82 [A] [VALUE] 0x82 5 Reserved 0x82 [B] [VALUE] 0x82 6 Reserved 0x82 [C] [VALUE] 0x82 7 When read this byte will return the last written value. When written to with any value all level alarms will be reset on 0x84 [A] [VALUE] 0x84 units with-in the group. 8 Reserved 0x84 [B] [VALUE] 0x84 9 Reserved 0x84 [C] [VALUE] 0x84 10 Day of current date on the site. 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 11 Month of current date on the site. 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 12 Year of current date on the site. 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 13 Hour of current time on the site 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 14 Minute of current time on the site 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 15 Second of current time on the site 0x53 [DAY] [MONTH] [YEAR-HI] [YEAR-LO] [HOUR] [MINUTE] [SECOND] 0x53 16 Most significant 16 bits of the 32 bit Procon V digital input 1 accumulator. 17 Least significant 16 bits of the 32 bit Procon V digital input 1 accumulator. 18 Most significant 16 bits of the 32 bit Procon V digital input 2 accumulator. 19 Least significant 16 bits of the 32 bit Procon V digital input 2 accumulator. 20 Most significant 16 bits of the 32 bit Procon V digital input 3 accumulator. 21 Least significant 16 bits of the 32 bit Procon V digital input 3 accumulator. 22 Most significant 16 bits of the 32 bit Procon V digital input 4 accumulator. 23 Least significant 16 bits of the 32 bit Procon V digital input 4 accumulator. 24 Most significant 16 bits of the 32 bit Procon V digital input 5 accumulator. 25 Least significant 16 bits of the 32 bit Procon V digital input 5 accumulator. 26 Most significant 16 bits of the 32 bit Procon V digital input 6 accumulator. 27 Least significant 16 bits of the 32 bit Procon V digital input 6 accumulator. 28 reserved 29 reserved 30 reserved 31 reserved Holding Registers Page 54