Wireless Test Bench Simulation

Transcription

1 Wireless Test Bench Simulation May 2007

2 Notice The information contained in this document is subject to change without notice. Agilent Technologies makes no warranty of any kind with regard to this material, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. Agilent Technologies shall not be liable for errors contained herein or for incidental or consequential damages in connection with the furnishing, performance, or use of this material. Warranty A copy of the specific warranty terms that apply to this software product is available upon request from your Agilent Technologies representative. Restricted Rights Legend Use, duplication or disclosure by the U. S. Government is subject to restrictions as set forth in subparagraph (c) (1) (ii) of the Rights in Technical Data and Computer Software clause at DFARS for DoD agencies, and subparagraphs (c) (1) and (c) (2) of the Commercial Computer Software Restricted Rights clause at FAR for other agencies. Agilent Technologies, Inc Page Mill Road, Palo Alto, CA U.S.A. Acknowledgments Mentor Graphics is a trademark of Mentor Graphics Corporation in the U.S. and other countries. Microsoft, Windows, MS Windows, Windows NT, and MS-DOS are U.S. registered trademarks of Microsoft Corporation. Pentium is a U.S. registered trademark of Intel Corporation. PostScript and Acrobat are trademarks of Adobe Systems Incorporated. UNIX is a registered trademark of the Open Group. Java is a U.S. trademark of Sun Microsystems, Inc. SystemC is a registered trademark of Open SystemC Initiative, Inc. in the United States and other countries and is used with permission. MATLAB is a U.S. registered trademark of The Math Works, Inc. ii

3 Contents 1 Wireless Test Bench Basics Introduction Wireless Test Benches, Sources, and Expressions Required Licenses Wireless Test Bench Models Wireless Sources Wireless Expressions Wireless Examples Using Wireless Sources and Expressions Introduction Setting up a Circuit Envelope Analysis Using Wireless Test Bench Models Introduction Importing Wireless Test Bench Models Wireless Test Bench Models Update Preparing an RFIC Design for WTB Analysis Setting Up a Wireless Test Bench Analysis Opening a Wireless Test Bench Model Setting up a Wireless Test Bench Model Connecting to an RF Device Under Test Setting Required Parameters Setting Circuit Envelope Analysis Parameters Setting the Fundamental Tones Setting Optional Model Parameters Getting Help on WTB Models Setting Optional Analysis Parameters Setting Automatic Verification Modeling Parameters Automatic Verification Modeling Parameters Running a Simulation Performing Sweeps, Monte Carlo/Yield Analysis, and Optimizations Using Instrument Connectivity Introduction Connecting to Instruments Instrument Discovery Compatibility with Agilent Technologies Instruments Viewing Simulation Results Introduction iii

4 Automatic Plotting Distributed Simulation Wireless Measurement Definitions Introduction Transmission Test Measurements RF Envelope Constellation Power Spectrum EVM Receiver Test Measurements BER Measurements E b /N o Definition References A Creating Wireless Test Bench Designs for RFDE Introduction... A-1 Creating a Wireless Test Bench Design... A-1 Wireless Test Bench Design Examples... A-2 Setting the Units for WTB Design Parameters... A-2 Categorizing WTB Design Parameters... A-3 Information Parameters... A-3 Verifying a WTB Design in ADS... A-3 Exporting a WTB Design to RFDE... A-4 WTB Design User Interface Attributes... A-4 Creating a Results Display for WTB Designs... A-5 Circuit Envelope Parameters... A-6 Index iv

5 Chapter 1: Wireless Test Bench Basics Introduction RFDE wireless test benches enable system designers to make wireless system measurements available to RFIC designers to validate their RFIC designs intended for use with wireless systems. Previously, RFIC designers using RF Design Environment used traditional Analog/RF measurements such as spectrum, TOI, etc. to validate their designs. Empirical methods used to map Analog/RF measurements to determine wireless system performance were error prone. Typically, they could not perform more complex wireless system measurements successfully such as EVM and BER. And, a system designer using Advanced Design System s Ptolemy simulator could not easily deliver a system test bench to the RFIC designer for more accurate and complete RFIC verification. A similar capability for strictly RFIC designs is available in RFDE called wireless test bench; refer to ADS Ptolemy in AMSD-ADE documentation for details. Wireless Test Benches, Sources, and Expressions The pre-configured wireless test bench models delivered with RFDE enable the RFIC designer to validate their designs in wireless systems. The WTB models are complete, so the RFIC designer does not need to know the internal test bench details. System designers can also make custom wireless system measurements available to RFIC designers to validate their designs in RFDE. For details, refer to Appendix A, Creating Wireless Test Bench Designs for RFDE. The WTB analysis available in the RFDE ADSsim simulator s list of analyses provides easy access to the WTB models. Simply select a model within the WTB analysis. The RFIC designer need only connect their RFIC design (the RF design under test), specify test bench test frequency and/or power levels, and rely on the other default settings. RFDE WTB models are provided for transmitter and receiver RFIC testing. Transmitter models provide standards-specific wireless transmitter tests such as constellation, CCDF, and EVM; transmitter models can be linked to Agilent signal generator test instruments to further enable designers to use the same test signals Introduction 1-1

6 Wireless Test Bench Basics from the WTB models to test their RFDE RFIC designs as well as hardware prototype of their RFIC designs. Receiver models provide standards-specific wireless receiver tests such as BER. The RFIC designer typically should use the WTB analysis after doing traditional measurements to achieve an acceptable performance from the RFIC. In the initial design stages the RFIC designer may have to stimulate the design with proper wireless standard signals. Wireless sources are provided with RFDE as part of the adslib library. Their use model is similar to other adslib power sources such as P_1Tone. These configurable source components can be placed directly in the RFIC schematic. Wireless sources generate RF signals that can be used in traditional simulations. Additionally, these can be used for wireless system measurements, such as WLAN EVM, using the set of wireless expressions. These wireless expressions are available in the Expression Builder under the Env analysis type. For more complex receiver measurements, such as BER, you must use the wireless test bench models using the WTB analysis. The wireless sources and expressions are useful in the initial phases of the RFIC development for traditional Analog/RF measurements. As the design matures, the RFIC designer must use WTB analysis and the corresponding wireless test bench models for more complete transmitter and transmitter system verification. Required Licenses Licenses required to use wireless test bench models, wireless sources, and wireless expressions are listed in Table 1-1. Table 1-1. Required Licenses Feature Wireless Test Bench Models, Sources, and Expressions Wireless Test Bench Models also require: 3GPP FDD W-CDMA Wireless Design Library for 3GPP FDD Wireless Test Bench Models, Sources, and Expressions TD-SCDMA Wireless Design Library for TD-SCDMA Wireless Test Bench Models, Sources, and Expressions Required Licenses rfde_environment rfde_circuit_int rfde_wtb_int sim_systime mdl_wcdma3g mdl_tdscdma Note: Custom WTB models created in Advanced Design System may include models that require additional licenses to use the custom WTB models in RFDE. 1-2 Wireless Test Benches, Sources, and Expressions

7 Table 1-1. Required Licenses (continued) Feature WLAN Wireless Design Library for WLAN Wireless Test Bench Models, Sources, and Expressions Connection Manager (for WTB models with instrument connectivity) download to Agilent ESG instruments Connections to Agilent network analyzers Required Licenses mdl_wlan link_connect_mgr link_measampmodeling Note: Custom WTB models created in Advanced Design System may include models that require additional licenses to use the custom WTB models in RFDE. Wireless Test Bench Models Table 1-2 lists pre-configured wireless test bench models installed with RFDE. These test benches provide comprehensive transmitter and receiver testing for 3GPP FDD, TD-SCDMA, and WLAN technologies. All measurements are performed according to wireless technology industry standard specifications. For details about using these models, see the online documentation: 3GPP FDD Wireless Test Benches TD-SCDMA Wireless Test Benches WLAN Wireless Test Benches Note Custom test benches can be created in ADS. For details, refer to Appendix A, Creating Wireless Test Bench Designs for RFDE. Table 1-2. RFDE Wireless Test Bench Models WTB Model Measurements ESG Link 3GPPFDD_BS_TX: 3GPP FDD Base Station Transmitter Test 3GPPFDD_UE_TX: 3GPP FDD User Equipment Transmitter Test 3GPPFDD_BS_RX: 3GPP FDD Base Station Receiver Test 3GPPFDD_UE_RX: 3GPP FDD User Equipment Receiver Test WLAN_802_11a_TX: WLAN a/11g Transmitter Test RF Envelope, Power, ACLR, Occupied Bandwidth, CDP, PCDE, EVM RF Envelope, Power, ACLR, ACLR ST, Occupied Bandwidth, CDP, PCDE, EVM Ref Level, Dynamic Range, ACS, Blocking, Intermod Ref Level, Max Level, ACS, Blocking, Intermod RF Envelope, Power, Constellation, Spectrum Mask, EVM Signals can be sent to an ESG Signals can be sent to an ESG Signals can be sent to an ESG Wireless Test Benches, Sources, and Expressions 1-3

8 Wireless Test Bench Basics Table 1-2. RFDE Wireless Test Bench Models (continued) WTB Model Measurements ESG Link WLAN_802_11a_RX_ACR: WLAN a/11g Receiver Test WLAN_802_11a_RX_Sensitivity: WLAN a/11g Receiver Test WLAN_802_11b_TX: WLAN b/11g Transmitter Test WLAN_802_11b_RX_Sensitivity: WLAN b/11g Receiver Test TDSCDMA_DnLnk_TX: TD-SCDMA Downlink Transmitter Test TDSCDMA_UpLnk_TX: TD-SCDMA Uplink Transmitter Test TDSCDMA_DnLnk_MultiCarrier_TX: TD-SCDMA Downlink Transmitter Test for Multi-carrier Signals TDSCDMA_DnLnk_RX_ACS: TD-SCDMA Downlink Receiver Test TDSCDMA_UpLnk_RX_Sensitivity: TD-SCDMA Uplink Receiver Test Receiver Adjacent Channel Rejection Test Minimum Input Power Sensitivity RF Envelope, Power, Constellation, Spectrum Mask, EVM Minimum Input Power Sensitivity RF Envelope, Constellation, Power, Spectrum, EVM RF Envelope, Constellation, Power, Spectrum, EVM Power, Spectrum Downlink Adjacent Channel Selectivity Test Uplink Minimum Input Level Sensitivity Test Signals can be sent to an ESG Signals can be sent to an ESG Signals can be sent to an ESG 1-4 Wireless Test Benches, Sources, and Expressions

9 Wireless Sources Table 1-3 lists the RFDE wireless sources. These wireless sources provide standard compliant RF signals for WLAN, TD-SCDMA, and 3GPP FDD wireless technologies. In addition to the RF signal, the TD-SCDMA and 3GPP FDD sources provide baseband I and Q signals. These sources are highly configurable and can generate signals with different rates, power levels, impairments, etc. For details about these sources, see the online Components documentation Sources-DSP-Based. Table 1-3. RFDE Wireless Sources Source Name WLAN_802_11a WLAN_802_11b TDSCDMA_DnLink TDSCDMA_UpLink 3GPPFDD_DnLink 3GPPFDD_UpLink Description WLAN a (OFDM) source WLAN b (CCK/PBCC) source TD-SCDMA downlink source TD-SCDMA uplink source 3GPP FDD downlink source 3GPP FDD uplink source Wireless Expressions Table 1-4 lists the RFDE wireless expressions. These expressions are used to perform measurements commonly used for testing 3GPP FDD, WLAN, and TD-SCDMA transmitters. These expressions are available in the Expression Builder under Env Analysis Type. The Expression Builder also provides versions of these expressions that can be used with differential voltage signals. See Expression Builder in the Measurement Expressions documentation for details. See the Measurement Expressions documentation for details about using these expressions. Table 1-4. RFDE Wireless Expressions Measurement Baseband signal in time-domain EVM measurement for WLAN DSSS/CCK/PBCC EVM measurement for WLAN OFDM Expression Name real() evm_wlan_dsss_cck_pbcc() evm_wlan_ofdm() The power_ccdf_ref() expression, which generates a reference curve for the Power-CCDF measurement, can be used in transmitter testing. This expression is not available in the Expression Builder. The spectrum_analyzer() and fs() expressions can be used for spectrum measurement. Although spectrum_analyzer() uses fs() internally, it provides an easy way to set the measurement resolution bandwidth as well as video averaging. Wireless Test Benches, Sources, and Expressions 1-5

10 Wireless Test Bench Basics Table 1-4. RFDE Wireless Expressions Measurement Magnitude of carrier in time-domain Phase of carrier in time-domain Power - CCDF Power - Peak Power - Peak to Average Power - Power vs. Time Power - Total Spectrum analyzer Expression Name mag() phase() power_ccdf() peak_pwr() peak_to_avg_pwr() pwr_vs_t() total_pwr() spectrum_analyzer() Spectrum of carrier in db db( fs() ) Spectrum of carrier in dbm dbm( fs() ) Voltage <named node>[1] The power_ccdf_ref() expression, which generates a reference curve for the Power-CCDF measurement, can be used in transmitter testing. This expression is not available in the Expression Builder. The spectrum_analyzer() and fs() expressions can be used for spectrum measurement. Although spectrum_analyzer() uses fs() internally, it provides an easy way to set the measurement resolution bandwidth as well as video averaging. Wireless Examples RFDE examples demonstrate how to use wireless test benches, sources, and expressions. To access these examples, from the CIW window, choose Tools > RFDE Examples > Open Examples; select WLAN, TDSCDMA, or WCDMA3G; then select an example from the Top-level cells list. Examples use the following naming convention: Wireless test bench models: <standard_name>_wtb_test. Wireless sources and expressions: <standard_name>_source_expression_test. 1-6 Wireless Test Benches, Sources, and Expressions

11 Chapter 2: Using Wireless Sources and Expressions Introduction The Wireless Sources available in RF Design Environment are useful for traditional Analog/RF measurements. In the initial stages of an RFIC design you may need to stimulate the design with proper wireless standard signals. Wireless sources generate complex signals useful for traditional measurements. Additionally, these can be used for wireless system measurements, such as WLAN EVM, using the set of Wireless Expressions. The Wireless Sources are provided as part of the adslib library in RFDE for wireless standard signal generation. These are configurable source components and their use model is similar to adslib power sources such as P_1Tone. Wireless sources can be used in different analyses such as Circuit Envelope, and S-parameter just like other adslib library sources. The Wireless Expressions can be found in the Expression Builder under Env analysis type. For more complex measurements, such as BER, you must use the Wireless Test Bench Models using the WTB analysis. For details about using the Wireless Test Bench Models, refer to Chapter 3, Using Wireless Test Bench Models. Setting up a Circuit Envelope Analysis In the early stages of RFIC design you can use the wireless sources to generate the standard wireless signal required to stimulate the RFIC design under test (DUT). These sources, part of the adslib library under Sources Modulated, can be placed on the schematic design similar to other adslib source components. The sources are typically used with Circuit Envelope analysis. To set up the DUT for a Circuit Envelope analysis: 1. Open the Analog Design Environment window. This can be done from the schematic window using Tools > Analog Design Environment. 2. In the Analog Design Environment window, select Analyses > Choose to open the Choosing Analyses window. Introduction 2-1

12 Using Wireless Sources and Expressions 3. Choose the Env analysis. Update the parameters with the stop time, time step, and frequencies of interest. To set up wireless expressions for measurements: 1. In the Analog Design Environment window, select Outputs > Measurement Expressions. 2. In the Measurement Expressions window, choose Build Expressions. 3. In the RFDE Expression Builder window, select the Env analysis type. The list of Measurements includes wireless expressions in the list of Env expressions. 4. Select the expression, the DUT node to operate on, and set the parameters. Click OK. The expression appears in the string field in the Measurement Expressions window. 5. In the Measurement Expressions window, on the left side of the string field, add the expression name or the equation s left side followed by =. Click Add to add this expression to the expression list. 2-2 Setting up a Circuit Envelope Analysis

13 Chapter 3: Using Wireless Test Bench Models Introduction Wireless test bench simulation is used to perform complex wireless system measurements using wireless test bench models. Pre-configured models are installed with RFDE; custom models created by system designers using ADS can be selected to perform other measurements (for information, refer to Appendix A, Creating Wireless Test Bench Designs for RFDE). WTB simulation uses Circuit Envelope analysis along with the ADS Ptolemy Data Flow (DF) controller to perform Analog/RF and system cosimulation. Each wireless test bench model is packaged such that the RFIC designer avoids working with DF analysis parameters. The RFIC designer can change and control the underlying Circuit Envelope analysis parameters on the Wireless Test Bench Options window. Importing Wireless Test Bench Models System designers can create wireless test bench models in ADS and export them to RFDE. RFIC designers can import these WTB models into RFDE to perform complex wireless system measurements. In the Wireless Test Bench Path Editor window, you can specify directory paths to ADS projects that contain WTB models created and exported by system designers. These paths are used to import WTB models so they are available when you need to use a model. Introduction 3-1

14 Using Wireless Test Bench Models For details about creating and exporting WTB models, refer to Appendix A, Creating Wireless Test Bench Designs for RFDE. To specify the paths to wireless test bench models: 1. In the Analog Design Environment window, select Tools > WTB Path Editor to open the Wireless Test Bench Path Editor window. 2. Click Browse to open the File Browser window. Locate the path to the project containing exported WTB model(s). Click OK or Apply. The selected path appears in the Path Editor s field Select ADS Project to Import WTB from. 3. Click Add to move the path selection into the list area. To change the specification of a path in the list: 1. Select a path in the list area that you want to change. 2. The path appears in the field Select ADS Project to Import WTB from. Type in any changes. or Click Browse to open the File Browser window. Locate the path to the project containing exported WTB model(s). Click OK or Apply. The selected path appears in the Path Editor s field Select ADS Project to Import WTB from. 3. Click Change to replace the path selected in the list area. To modify the list of paths: 3-2 Importing Wireless Test Bench Models

15 Select a path in the list area, then Click Delete to remove the path from the list. Click Move Up or Move Down to reposition the path in the list. Importing Wireless Test Bench Models 3-3

16 Using Wireless Test Bench Models Wireless Test Bench Models Update When you are ready to use a WTB model in a WTB analysis, the WTB models are imported or updated when you click Edit in the Choosing Analyses window. The WTB models are read and imported from the list of paths specified in the Wireless Test Bench Path Editor. The list is read from top to bottom. Each time you click OK or Apply in the Wireless Test Bench Path Editor, all of the models are checked to see if they are new or have been updated. An exported WTB model file is imported only if it is newer than the model file imported previously. The pre-configured WTB models installed with RFDE are always imported last after all of the models in the user-specified paths. So a WTB model in an ADS project path specification that is earlier in the list can override the WTB model with same name specified later in the list. You can use this feature to override the pre-configured WTB models. For a summary of the pre-configured WTB models, see Wireless Test Bench Models on page 1-3. Preparing an RFIC Design for WTB Analysis The DUT must contain an input and an output Pin connected to the node or wire to which the WTB model must be connected. With the design open in the schematic window, add pins to the design using Add > Pins. It is not necessary to add other input and output components because the WTB model provides the input source signal to simulate the DUT and appropriate termination to perform various measurements. Figure 3-1 shows an example design with pins added. Note During a WTB analysis, naming a wire on the DUT will not produce data for that named node in the final dataset. Figure 3-1. Example DUT 3-4 Preparing an RFIC Design for WTB Analysis

17 Setting Up a Wireless Test Bench Analysis Before setting up a WTB analysis you must have a valid design selected in the Analog Design Environment window and the simulator must be set to ADSsim (Setup > Simulator/Directory/Host). Then choose the wtb analysis (Analyses > Choose). After choosing the wtb analysis, open a wireless test bench model, connect the RFIC design ports to the WTB model, set the required parameters, and set optional parameters if necessary. These topics are discussed in the following sections: Opening a Wireless Test Bench Model on page 3-6 Connecting to an RF Device Under Test on page 3-8 Setting Required Parameters on page 3-9 Setting Optional Model Parameters on page 3-13 Setting Optional Analysis Parameters on page 3-14 Setting Up a Wireless Test Bench Analysis 3-5

18 Using Wireless Test Bench Models Opening a Wireless Test Bench Model Before opening any wireless test bench model, they must be available in any of the following locations: Under $HPEESOF_DIR/adsptolemy/wtb where RF Design Environment is installed. In the user-specified WTB model path. In the ADS project containing the exported WTB models and specified in the Wireless Test Bench Path Editor. To open a wireless test bench model: 1. In the Choosing Analyses window, click Edit in the Wireless Test Bench Setup area. The Wireless Test Bench Setup window opens where you can select a wireless test bench model. Clicking Edit also updates WTB models imported into RFDE. See Wireless Test Bench Models Update on page 3-4 for details. Note The Wireless Test Bench Setup window will not open if WTB models are not found. 3-6 Opening a Wireless Test Bench Model

19 2. In the Wireless Test Bench Setup window, select the wireless standard from the Category drop-down list. The pre-configured models installed with RFDE are organized into TD-SCDMA, WCDMA3G, and WLAN categories. If a system designer exports any WTB model from ADS, a new category is added based on the name of the ADS project from which the WTB design was exported. 3. Select the test bench model from the Test Bench drop-down list, which is a list of WTB models available for a selected category. Each time a WTB model is selected the ports and parameters lists are automatically updated in the Wireless Test Bench Setup window. You are now ready to connect the WTB model s input and output to the RFIC DUT pins, select measurements, and set parameters. See Setting Circuit Envelope Analysis Parameters on page 3-10, and Setting up a Wireless Test Bench Model on page 3-7. Setting up a Wireless Test Bench Model Use the Wireless Test Bench Setup window to set up a WTB for system verification measurements on the RFIC design. You must connect the RFIC DUT s ports to the WTB model, set the required parameters, and set optional parameters as necessary. The required parameters include setting simulation frequencies and selecting measurements; at least one measurement must be enabled for successful simulation. Optional parameters provide additional control of the selected measurements. These topics are discussed in the following sections: Connecting to an RF Device Under Test on page 3-8 Setting Required Parameters on page 3-9 Setting Optional Model Parameters on page 3-13 The following table lists the various parameter data entry fields found in the Wireless Test Bench Setup window, and describes how they behave. Setting up a Wireless Test Bench Model 3-7

20 Using Wireless Test Bench Models Parameter Field Type String data entry field String data entry field with multiple choices Information fields Instrument selection field Description Used to enter integer, real, complex, or string type of scalar data. Array and string type data must be enclosed in quotes. This gives you multiple choices for the value of the parameter to select from. The pull down list field also enables you to type in the data directly. The last choice in the list specifies what the type-in value can be, such as an option index, a real value, etc. Use this mode to assign a variable to this type of parameter; then use the variable to either sweep or optimize the parameter. This non-editable information field provides information on a certain aspect of the WTB model. This is a string data entry field followed by a button to launch the instrument-selection user interface. This type of parameter is used only when you enable ESG download. You can enter the instrument address directly or use the button to launch the instrument-selection user interface to interactively select the instrument and update the address. Connecting to an RF Device Under Test You must identify the port connections between the RFIC DUT and the WTB model in the Wireless Test Bench Setup window. Simply connect the WTB RF_out and Meas_in ports to the DUT by identifying the appropriate pin names. 3-8 Connecting to an RF Device Under Test

21 To connect the ports: 1. Open the RFIC design (the DUT) in a schematic window. The design in the schematic must match the design indicated in the Analog Design Environment window from where the Choosing Analyses and the Wireless Test Bench Setup windows were opened. 2. Add input and output pins to the RFIC design using Add > Pin in the schematic window. 3. In the Wireless Test Bench Setup window Pin Connections area, click Select Pin next to the field linked to RF_out, then click the input pin in the schematic. The input pin name appears in the field between the ports, indicating that the RF_out port is connected to the DUT input. 4. Click Select Pin next to the field linked to Meas_in, then click the output pin in the schematic. The output pin name appears in the field between the ports, indicating that the Meas_in port is connected to the DUT output. You should now set the required parameters; see Setting Required Parameters on page 3-9. Setting Required Parameters After connecting the WTB model and DUT ports, set the model parameters in the Required Parameters area of the Wireless Test Bench Setup window. The number of parameters will vary between different models. These parameters control the simulation and identify the selected measurements. They must have valid values and cannot be left blank. For detailed information about setting these parameters, click WTB Model Help. Important You must set the required frequencies and select at least one measurement for successful simulations. Note To reset all parameter values to their default or standard factory-set values, click Reset To Standard located at the top of the Wireless Test Bench Setup window. Setting Required Parameters 3-9

22 Using Wireless Test Bench Models Setting Circuit Envelope Analysis Parameters The WTB analysis is a cosimulation between an Env (Circuit Envelope) analysis and a DataFlow analysis to verify an RFIC design s system performance. The DataFlow analysis is pre-configured with the WTB model. When you select the WTB analysis in the Choosing Analyses window, the contents are similar to Env analysis. The Wireless Test Bench Options window is the same as Circuit Envelope Options except the Wireless Test Bench Options window contains Automatic Verification Modeling (AVM) parameters for faster cosimulation. The RFIC designer must configure the Circuit Envelope analysis to ensure proper simulation. CE_TimeStep (Circuit Envelope Time Step): set the value based on the information field below this parameter. FSource (Source Frequency): This DUT input signal frequency should be added to the Fundamental Tones area in the Choosing Analyses window, based on the frequency conversion characteristics of the DUT s input side. FMeasurement (Measurement Frequency): This DUT output signal frequency is used for selected measurements and should be added to the Fundamental Tones 3-10 Setting Required Parameters

23 area in the Choosing Analyses window, based on the frequency conversion characteristics of the DUT s output side. Setting the Fundamental Tones Use the Fundamental Tones table to enter the frequencies for the underlying Circuit Envelope simulation. This table must contain all of the different frequencies such as FSource and FMeasurement that are set in the Wireless Test Bench Setup window. The WTB model uses these parameters for accurate simulation and measurement. When you click OK or Apply in the Wireless Test Bench Setup, the following actions help complete the frequency information in the Fundamental Tones table: Setting Required Parameters 3-11

24 Using Wireless Test Bench Models If the Fundamental Tones table is empty, then a warning appears asking if the frequencies FSource and FMeasurement should be added to the table. Click Yes or No. If the Fundamental Tones table contains data and you modify FSource or FMeasurement, a warning appears stating which of the frequencies have been modified and that you should make the necessary changes in the Fundamental Tones table. If the Fundamental Tones table contains data and you have not modified FSource or FMeasurement, no message appears even if the frequencies are inconsistent. Once the frequency information is correctly added to the table, do not delete these frequencies from the table. You can modify other parameters for a frequency added to the table. For details about modifying the Fundamental Tones table, see this parameter s description in the section RFDE Envelope Analysis Parameters in the Circuit Envelope Simulation documentation. Simulation stop time is controlled by the selected measurements and their parameter values. The measurements and their parameters are located on the tabs below the Required Parameters area. If necessary for your measurement requirements, set the optional parameters for the WTB model, and for the WTB analysis. See Setting Optional Model Parameters on page 3-13, and Setting Optional Analysis Parameters on page Setting Required Parameters

25 Setting Optional Model Parameters The WTB model s optional parameters are located on tabs located in the lower area of the Wireless Test Bench Setup window. Scroll down to see all of the parameters. The parameters on some of these tabs control the simulation run time. You will use these tabs mostly to modify the simulation run time; otherwise, you will rarely need to modify them. Note To reset all parameter values to their default or standard factory-set values, click Reset To Standard at the top of the Wireless Test Bench Setup window. Other tabs in this area contain parameters for measurements listed in Required Parameters. Some of those parameters will also control the simulation run time. You may need to change parameters for the measurements you have selected. For detailed information about setting these parameters, click WTB Model Help. Use the left and right arrows beside the tabs to scroll through them. Click a tab label to view its parameters. Getting Help on WTB Models Detailed documentation is available from the Wireless Test Bench Setup window: For documentation about the currently selected, pre-configured model, click WTB Model Help. For documentation about using the Wireless Test Bench Setup window, click Help. Setting Optional Model Parameters 3-13

26 Using Wireless Test Bench Models Setting Optional Analysis Parameters To set the optional WTB analysis parameters, click Options on the Choosing Analyses window when WTB analysis is selected. This opens the Wireless Test Bench Options window. The parameters set the underlying Circuit Envelope optional parameters. For faster cosimulation, enable the Automatic Verification Modeling (AVM). For information about using AVM, see Setting Automatic Verification Modeling Parameters on page For details about the AVM parameters, see Automatic Verification Modeling Parameters on page For details about the additional, optional Circuit Envelope parameters, see the section RFDE Envelope Analysis Parameters in the Circuit Envelope Simulation documentation. Setting Automatic Verification Modeling Parameters When the Wireless Test Bench Options window is open, enable Automatic Verification Modeling (AVM) to view and set its parameters. AVM (also known as Fast Cosim) is a user-selected mode of operation, available for WTB analysis that can significantly speed up Circuit Envelope simulations of Analog/RF circuits. When this mode is enabled, the analog subcircuit is characterized using a variety of Harmonic Balance simulations at the start of each wireless test bench simulation. During the actual wireless test bench simulation, this characterization data is then used to predict the response of the subcircuit instead of performing the full circuit simulation at each time point. Since this characterization is normally done at the start of each WTB analysis sweep based on the full circuit level schematic, the overall capability is basically the same as if the actual circuit level representation is used throughout the Circuit Envelope simulation. For example, optimization of circuit level parameters, or swept parameters including bias, temperature or swept carrier frequency, will continue to operate as expected. These capabilities do not exist when the circuit is manually replaced with behavioral models. This ability to predict the modulated response based on the Harmonic Balance characterization relies on the fact that many circuits, when used in relatively narrow band modulated applications, can have their nonlinearity represented as a static nonlinearity that is strictly a function of the instantaneous amplitude of the carrier. Many of these circuits (amplifiers and mixers) have little or no frequency response over the modulation bandwidth of interest; any frequency response effects that do 3-14 Setting Optional Analysis Parameters

27 exist can often be represented as a linear filter on the input or output of the nonlinearity. Each output of the Analog/RF subcircuit is then characterized by the equation: Out k = ( P k ( InputMag) P k ( 0) ) e jinputphase HarmGain + P ( 0 ) k The P k (mag) functions are determined by the swept amplitude Harmonic Balance simulation. The HarmGain is the harmonic gain determined from the harmonic indices of the input and output frequencies. If phase characterization has been enabled (setting the Num. of phase pts parameter to a non-zero value) each output is then characterized by this modified equation: Out k = P k ( InputMag, InputPhase) In this case, P k (mag, phase) functions are determined by a 2D swept amplitude and swept phase Harmonic Balance simulation. If the subcircuit nonlinearities are a function of the input phase, as in a nonlinear IQ demodulator, then the amplitude-only characterization is not accurate and the 2-dimensional amplitude and phase characterization must be used. Note that the magnitude-only characterization assumes the output phase can be determined from the harmonic indices of the input and output frequencies. In certain rare cases, this can be ambiguous. For example, if the input frequency is fund1 and the output frequency is 2*fund1, then the simulator assumes the output signal is generated by doubling the input frequency and so the input phase is doubled. However, if this 2*fund1 output frequency is actually generated by mixing with another LO source at the fund1 frequency and the phase relationship is supposed to be linear, then the AVM (Fast Cosim) results will be incorrect. If the mixer LO is operating at an independent fund2 frequency, with a mixer output at fund1 + fund2, then the HarmGain of 1.0 is correctly determined. So, as with the IQ demodulator, if there are circuit sources operating at the same frequency as the input signal, caution must be used when enabling this AVM (Fast Cosim) mode, and the 2D amplitude and phase characterization may be required. In addition to the swept amplitude characterization, the AVM characterization also includes a small signal Harmonic Balance frequency sweep. In this case, the input amplitude is set to 0, and the small signal frequency is swept between +/- 0.5/TimeStep. Note that even though the input amplitude is set to 0, a nonlinear analysis is still being done so any frequency translation effects due to internal mixers will be fully captured. An impulse response representing this frequency response can Setting Optional Analysis Parameters 3-15

28 Using Wireless Test Bench Models then be generated and placed (at the user's choice) on the input or the output of the nonlinear block. An additional delay can be added to the frequency response, so that the impulse can be made a more accurate representation of the frequency response. The user should set the number of frequency points high enough that any frequency response deviations are sufficiently sampled (a minimum of 4 samples every 360 degrees). The maximum duration of the impulse response will be approximately 0.75/FreqSpacing, where FreqSpacing = N TimeStep N is determined so that 2 N is just larger than the user-specified number of frequency points. In addition to the amplitude and frequency response characterization, nonlinear noise characterization is also done. A single value for the equivalent input noise for each output is determined, then added to the input signal prior to the above nonlinear and frequency response effects. In the case of multiple outputs, these equivalent noise sources are uncorrelated. So any correlation of the Analog/RF subcircuit added noise between multiple outputs is lost during this AVM (Fast Cosim) mode. This noise characterization is implemented by selecting Turn On All Noise in the Envelope parameter group in the Options window. In certain cases, the time spent doing this characterization can be eliminated if the user requests that the simulator use previous characterization. Once this mode is selected, then the user must make sure that the previous characterization is still valid, and that circuit parameters have not been changed (perhaps by optimization), biases have not changed, carrier frequencies have not changed, etc. The circuit should not have changed its connectivity within the WTB analysis environment. Also, the format and data in the dataset must be in the same expected configuration as when it was written by simulator. In addition to the characterization and implementation portion of the AVM (Fast Cosim) mode, there is also a user-selectable verification step. If the user specifies a non-zero verification Stop Time, then the normal Circuit Envelope simulation is performed in parallel with the fast cosimulation predictions. The error over this verification is then calculated and output to determine how well these predictions are performing. If the behavior is unacceptable, as determined by the Accept Tolerance, then the AVM (Fast Cosim) will be disabled and only the normal Circuit Envelope results will be used. Clearly, if used, this verification time should be set long enough to include a representative portion of the input signal. This may need to take into 3-16 Setting Optional Analysis Parameters

29 account the fact that many sources, due to channel filtering, take a while to generate their full amplitude outputs. Limitations While you may have selected the AVM (Fast Cosim) mode, it may become disabled if: The RF DUT has more than one input from the WTB model or the input is not for an RF signal (non-zero carrier frequency). The CE_TimeStep is not an integer submultiple of the WTB_TimeStep. See the specific WTB documentation to understand how the WTB_TimeStep is set. It cannot be set directly by the user and is set by derivation from the other WTB model parameters. Verification was enabled but performance did not meet an acceptance level. The Envelope analysis includes an oscillator analysis. The input frequency was a mixing term and not harmonically related to a single fundamental. The input frequency does not exactly match an Envelope analysis frequency. There was a problem reading the previously generated dataset. Additional limitations of the AVM (Fast Cosim) mode, that may not be automatically detected by the simulator unless verification is enabled, include: Envelope analyses parameters such as the Freq parameters should not be swept or optimized. Setting Optional Analysis Parameters 3-17

30 Using Wireless Test Bench Models Automatic Verification Modeling Parameters These parameters enable and control the Automatic Verification Modeling (AVM) mode and are only applicable when the Wireless Test Bench Analysis is selected for use with a Ptolemy cosimulation. The following table describes the parameter details. Names listed in the Parameter Name column are used in netlists. Table 3-1. Wireless Test Bench Analysis AVM Parameters Setup Dialog Name Parameter Name Description Automatic Verification Modeling (AVM) AVM This enables the Automatic Verification Modeling (AVM) mode to be used for the Analog/RF subcircuit. If AVM (Fast Cosim) is not possible for this subcircuit, then a warning will be output and regular Circuit Envelope Cosimulation will be performed. Max Input Power (dbm) ABM_MaxPower This specifies the maximum input power to this Analog/RF subcircuit that will be used during the AVM (Fast Cosim) characterization phase. Excessively high values will take longer to characterize due to potentially more difficult circuit convergence. If the input power during the cosimulation exceeds this value, a warning will be generated since the AVM (Fast Cosim) results will no longer be accurate. Number of Amplitude Points ABM_AmpPts This sets the number of linear amplitude points between 0 and the full scale value defined by the Max Input Power. Depending on how much variation there is in the output vs. input amplitude characterization, more amplitude points may be needed to achieve optimum accuracy at a cost of additional characterization time. Due to the continuation nature of the swept amplitude harmonic balance characterization when not using Krylov modes, the cost of additional amplitude points is usually small. In addition to these linear spaced points, the characterization adds an additional power point every 6 db down to a value 100 db below the Max Input Power. Number of Phase Points ABM_PhasePts Any value greater than 0 will enable the characterization to be done as a function of both amplitude and phase. This specifies the number of phase points to be used at each amplitude point. Since this will now be a two dimensional sweep and so will be slower, it should only be used when required, such as with IQ demodulators where the output is a nonlinear function of the input phase. IQ Modems that are linear with phase, but nonlinear with amplitude, do not require phase characterization. Just identify the I/Q pair with the correct polarity in the Node Names section. Number of Frequency Points ABM_FreqPts This sets the minimum number of small signal frequency points that are used to characterize the Analog/RF subcircuit. The actual number of points is increased to the next highest power of 2 value. These points are spaced between +/- 0.5/TimeStep, where TimeStep is the Step time defined for the Envelope analysis. The maximum impulse duration for this frequency response characterization is determined by this frequency spacing. So the number of frequency points should be greater than the maximum impulse response time of the circuit around the carrier frequency plus any additional Delay specified in the Implementation block, both normalized by the Circuit Envelope TimeStep value Setting Optional Analysis Parameters

31 Table 3-1. Wireless Test Bench Analysis AVM Parameters Setup Dialog Name Parameter Name Description Use Previous Characterization ABM_ReUseData Checking this tell the simulator to re-use any previous characterization that was done for this Analog/RF subcircuit. This characterization is saved in a dataset named after the subcircuit name. This eliminates any overhead time associated with the characterization, but it is then the responsibility of the user to make sure that nothing significant enough has changed (including carrier frequency, time step, bias voltages, temperature, optimization variables, etc.) since the last characterization. Frequency Compensation ABM_FreqComp This specifies whether or not a frequency compensation filter is to be created for use in the AVM (Fast Cosim) mode. In addition, the user can specify whether this filter is best placed on the input or the output of the nonlinear block. If the modulation is sufficiently narrow that there is not significant frequency response over the envelope bandwidth, then None should be selected. If the frequency response is primarily due to input filtering or transistor bandwidth limitations, then an Input frequency compensation should perform the best. Similarly, if the dominant filtering is at the output of Analog/RF subcircuit, such as the channel filter, then an Output frequency compensation should be used. Delay (sec) ABM_Delay This adds additional transit delay to all the outputs of the Analog/RF subcircuit. In cases where this absolute delay is not critical to the overall system simulation, adding additional delay permits more accurate impulse implementation of the frequency response. This delay should not exceed half the impulse length, as determined by the frequency response characterization. Verification Time (sec) ABM_VTime If this verification stop time is not zero, then both the normal Envelope cosimulation and the AVM (Fast Cosim) results are computed. The RMS error between these two results is computed and output after this verification time has ended. This gives an indication as to how well the AVM (Fast Cosim) is matching the Circuit Envelope results. Verification Acceptance Tolerance ABM_VTol If the Verification Stop Time has been set, then the resultant RMS error must be less than this value or else the AVM (Fast Cosim) will be turned off and just the normal Envelope cosimulation results will be used for the remainder of the Ptolemy simulation. The stop time must be large enough to account for turn-on delays of filters and to give a sufficiently representative sample of the normal input signal. Setting Optional Analysis Parameters 3-19

32 Using Wireless Test Bench Models Running a Simulation After setting the WTB analysis parameters, connecting the WTB model ports to the DUT ports, and setting the model parameters, you can run a simulation. WTB analysis is supported for remote and distributed simulations. To run a simulation: 1. On the Choosing Analyses window, select Enable, then click OK or Apply. 2. Verify that the Analog Design Environment window indicates Yes for the WTB analysis in the Analyses queue. During a WTB analysis, do not select any other analysis type. If this happens, the netlisting will error out, suggesting that you turn off other analyses. 3. In the Analog Design Environment window, select Simulation > Netlist and Run Running a Simulation

33 Performing Sweeps, Monte Carlo/Yield Analysis, and Optimizations WTB model parameters can be included in Parameter Sweep, Monte Carlo/Yield Analysis, and Optimization Analysis. These are available in the Analog Design Environment window on the Tools menu. The simulation start and stop are not controlled from the Analog Design Environment window; they are controlled from the windows for each of these other tools. To include WTB model parameters in a sweep, Monte Carlo/yield analysis, and optimization: 1. In the Analog Design Environment window choose Variables > Edit. 2. Define a variable. This variable must be assigned to the WTB model parameter value. The multiple choice parameters can also be used in a sweep, Monte Carlo/yield analysis, and optimization in a similar manner. 3. Click OK. For information about Parameter Sweeps, see Parameter Sweeps and Sweep Plans in RFDE in the chapter Parameter Sweeps and Sweep Plans in the Simulation documentation. For information about Monte Carlo/Yield Analysis and Optimizations, see Optimization and Statistical Design. Performing Sweeps, Monte Carlo/Yield Analysis, and Optimizations 3-21

34 Using Wireless Test Bench Models 3-22 Performing Sweeps, Monte Carlo/Yield Analysis, and Optimizations

35 Chapter 4: Using Instrument Connectivity Introduction Transmitter wireless test benches support instrument connectivity. The following sections explain how to connect to instruments and describe the test benches compatibility with Agilent Technologies instruments. Connecting to Instruments The wireless test benches rely on Connection Manager architecture for instrument connectivity. Connection Manager is the implementation of Agilent Technologies Connected Solutions for RFDE. A Connection Manager-based simulation is part of the client half of the Connection Manager client/server system, and operates through an instance of the Connection Manager server. You can think of the Connection Manager-based simulation as an interface into the measurement available on the server. Detailed information about using Connection Manager, including functional concepts and server IO configuration is provided in the Connection Manager documentation. The Connection Manager architecture also provides instrument discovery and measurement exploration. Discovery makes it easy to identify the instruments that are connected to your server workstation, enabling the client to easily associate a particular instrument with a particular measurement. Exploration locates measurements on the server and describes a measurement s capabilities so a client can easily determine what a measurement does and how to use that measurement. Instrument Discovery The transmitter test benches provide interactive selection of the instrument before simulation. The Signal to ESG tab includes an Instrument parameter that is set to a string following a specific syntax as shown in this example: [GPIB::20::INSTR][localhost][4790] Introduction 4-1

36 Using Instrument Connectivity To interactively select an instrument: 1. From the Wireless Test Bench Setup window, select the Signal to ESG tab. 2. Look for Instrument in the parameter list. 3. Click the Select Instrument button to access the Set Server dialog box. 4. Enter the DNS hostname or IP address of the workstation on which an instance of the Connection Manager server is running. 5. Enter the port number on which the server is waiting for incoming connection requests. Unless the server settings are changed manually, use the default port number Click OK to access the Remote Instrument Explorer dialog box. This dialog box shows the Visa Resource identifiers of all instruments that are currently connected to the workstation running the Connection Manager server. A Visa Resource identifier is like an IP address that can uniquely identify an instrument among all the instruments connected to the workstation through all available interfaces. 4-2 Connecting to Instruments

37 To map the Visa Resource identifiers to the associated instrument model number, select one or more of the Visa Resource entries and click the Query Instruments IDs button. This tells the Connection Manager server to send the standard IEEE identification command *IDN? to the instrument(s). Most modern instruments that understand this command will respond with an identification string. After all selected instruments are queried, the Instrument IDs are displayed: 7. Select a specific instrument based on the Instrument ID string displayed and click OK. Click OK on the component dialog box to return to the RFDE dialog box. Click Cancel on any of the dialogs to retain your old settings. Compatibility with Agilent Technologies Instruments WLAN test benches, signal sources, and EVM measurements are compatible with the Agilent E4438C ESG Vector Signal Generator, and Agilent Series Vector Signal Analyzer; details are given in Table 4-1. TD-SCDMA test benches and signal sources are compatible with Agilent E4438C Signal Generator and Agilent Series Vector Signal Analyzer; details are given in Table GPP FDD test benches and signal sources are compatible with Agilent E4406A VSA Series Transmitter Tester, Agilent PSA Series High-Performance Spectrum Analyzer, and Agilent Series Vector Signal Analyzer; details are given in Table 4-3. Compatibility with Agilent Technologies Instruments 4-3

38 Using Instrument Connectivity Table 4-1. WLAN Agilent Instrument Compatibility Information WLAN Spec ESG Models VSA Models SpecVersion= 1999 E4438C, Firmware Revision C Option WLAN Software Personality (Signal Studio) Series, software version 4.xx/5.xx Option B7R - WLAN Modulation Analysis Table 4-2. TD-SCDMA Agilent Instrument Compatibility Information TD-SCDMA Spec ESG Models VSA Models SpecVersion= E4438C, Firmware Revision C Option TD-SCDMA (TSM) Software Personality (Signal Studio) Series, software version 4.xx/5.xx Option B7N - 3G Modulation Analysis Table GPP FDD Agilent Instrument Compatibility Information 3GPP Spec ESG Models VSA Models SpecVersion= E4438C, Firmware Revision C Option 400-3GPP W-CDMA FDD Personality E4406A, Firmware Revision A Option BAF - W-CDMA Measurement Personality PSA, Firmware Revision A Option BAF - W-CDMA Measurement Personality Series, software version 3.01/4.xx/5.xx Option B7N - 3G Modulation Analysis For more information about Agilent ESG Series of Digital and Analog RF Signal Generator and Options, visit For more information about Agilent PSG Series of Digital and Analog RF Signal Generator and Options, visit For more information about Agilent Series Vector Signal Analyzer and Options, visit For more information about Agilent PSA series High-Performance Signal Analyzer and Options, visit Compatibility with Agilent Technologies Instruments

39 Chapter 5: Viewing Simulation Results Introduction Wireless test bench simulation results can be viewed in a data display window. A dataset is generated for each simulation with configurations and data display template information in which to view results. For automatic plotting, a data display window automatically opens showing the results. For distributed simulation, data display options are provided for viewing plot outputs. The following sections provide information on viewing automatic plotting and distributed simulation results. For more details regarding using the data display, see the Data Display documentation. Automatic Plotting A Data Display/autoplot data display window contains pages that are set up for every measurement enabled in the Wireless Test Bench Setup form. To enable automatic plotting of results at the end of a simulation: 1. In the Analog Design Environment window, select Results > Data Display Options. 2. In the Data Display Options window, enable the options Open Data Display After Simulation and Enable Automatic Plotting of Outputs. To perform automatic plotting of a simulation dataset collected earlier: 1. In the Analog Design Environment window, select Results > Data Display Options. 2. In the Data Display Options window, for the option Dataset Used for Automatic Plotting, choose Use most recent dataset, or Prompt for dataset. 3. In the Analog Design Environment window, select Results > Plot Outputs. If the Analog Design Environment window is opened for a given DUT and the simulation directory is same as the directory used earlier when a successful WTB simulation dataset was generated, then you can see the results without re-running the simulation. Introduction 5-1

40 Viewing Simulation Results Distributed Simulation Wireless test bench models can be used in a distributed simulation with a different model for each simulation, or the same model can be used having different measurements for each simulation. A dataset is generated for each simulation with configurations and data display template information in which to view results (a data display window does not open automatically). To plot the most recent generated dataset: 1. In the Analog Design Environment window, select Results > Data Display Options. 2. In the Data Display Options window, for the option Dataset Used for Automatic Plotting, choose Use most recent dataset (the default setting). 3. In the Analog Design Environment window, select Results > Plot Outputs. To select a specific dataset for plotting: 1. In the Analog Design Environment window, select Results > Data Display Options. 2. In the Data Display Options window, for the option Dataset Used for Automatic Plotting, choose Prompt for dataset. 3. In the Analog Design Environment window, select Results > Plot Outputs. The Prompt for Dataset window opens containing the list of datasets generated from a given Analog Design Environment session. The datasets in the list can include the results of distributed and individual simulations. 4. Select a dataset to use for automatic plotting, and click OK. The selected dataset will contain the data display template names that must be used for automatic plotting. Each different dataset selection will update the final automatic plot window. 5-2 Distributed Simulation

41 Chapter 6: Wireless Measurement Definitions Introduction The following sections briefly describe the most commonly used measurements in transmitter and receiver testing for WLAN, TD-SCDMA, and 3GPP FDD. Transmission Test Measurements RF Envelope on page 6-1 Constellation on page 6-1 Power on page 6-5 Spectrum on page 6-8 EVM on page 6-10 Receiver Test Measurements BER Measurements on page 6-12 E b /N o Definition on page 6-12 Transmission Test Measurements RF Envelope The RF envelope measurement shows the magnitude of the RF signal s envelope versus time. By observing a signal s RF envelope versus time you can see the signal s frame/burst structure. Some wireless standards specify a mask, to which the signal s RF envelope must conform. The mask is typically specified during the ramp up and ramp down transient of the signal. Constellation The constellation measurement shows in a graphical way the general quality of a signal. For a more accurate measurement of a signal s modulation quality an EVM analysis must be performed. Introduction 6-1

42 Wireless Measurement Definitions A constellation measurement is most appropriate when a QAM modulation scheme is used (directly or indirectly; for example WLAN a uses OFDM modulation, where a set of subcarriers is modulated using some QAM scheme). An ideal QAM signal will have a constellation that consists of a set of distinct points on the IQ plane. Figure 6-1 shows the constellation for an ideal 16-QAM signal. This constellation has 16 points and is symmetric around the X and Y axes. All points are equally spaced. Figure 6-1. Constellation for Ideal 16-QAM Signal Different signal distortions modify the ideal constellation in different ways and so by looking at the constellation you can get some idea of what types of distortions are present in the signal. Figure 6-2 through Figure 6-6 show some examples of how signal distortions appear in the constellation. Figure 6-2 shows the constellation for a 16-QAM signal with gain imbalance. This can be deduced by the fact that in the ideal constellation the span of the points across both axes is the same (approximately 0.425), whereas in the constellation with the gain imbalance the Y axis has a bigger span (approximately 0.475). Figure 6-3 shows the constellation for a 16-QAM signal with phase imbalance. This can be deduced by the fact that in the ideal constellation the points are lined up in lines that are parallel to the X and Y axes, whereas in the constellation with the phase imbalance the points are lined up in lines that are parallel to the X axis but not to the Y axis. 6-2 Transmission Test Measurements

43 Figure 6-2. Constellation for 16-QAM Signal with Gain Imbalance Figure 6-3. Constellation for 16-QAM Signal with Phase Imbalance Transmission Test Measurements 6-3

44 Wireless Measurement Definitions Figure 6-4 shows the constellation for a 16-QAM signal with ISI (intersymbol interference) and AWGN (additive white gaussian noise). Notice that instead of 16 distinct points there are 16 clusters of points centered around the ideal 16-QAM points. Figure 6-5 shows the constellation for a 16-QAM signal with gain compression (from a nonlinear amplifier). Notice how the outer points (especially the four corner points), which have the highest power, have been compressed (moved closer to the center of the IQ plane). Figure 6-4. Constellation for 16-QAM Signal with ISI and AWGN Figure 6-5. Constellation for 16-QAM Signal with Gain Compression 6-4 Transmission Test Measurements

45 Figure 6-6 shows the constellation for a 16-QAM signal which includes all of the distortions discussed above. Figure 6-6. Constellation for 16-QAM Signal with Multiple Types of Distortion Power The power measurement is a set of power-related measurements that provides information about a signal s statistical properties. The power measurement includes: Power vs. Time shows the instantaneous signal power versus time. Some wireless standards specify a mask, to which the signal s instantaneous power versus time waveform must conform. The mask is typically specified during the ramp- up and ramp-down transient of the signal. Total (Average) Power is the average signal power over the measurement duration. For signals that are transmitted in bursts or in slots this measurement should be performed only when the signal is active (on) and not during the idle intervals or inactive slots. Peak Power is the maximum instantaneous signal power over the measurement duration. Some standards define the peak power not as the absolute maximum instantaneous signal power but as the power level that is exceeded only for a small percentage (e.g. 1%) of the time. Peak to Average Ratio signal power. is the ratio of the peak signal power to the average Transmission Test Measurements 6-5

46 Wireless Measurement Definitions Power Complementary Cumulative Distribution Function is defined as CCDF = 1 - CDF, where CDF is the cumulative distribution function of the signal s instantaneous power. If the probability density function of the signal s instantaneous power is p(x), then CDF( y) = px ( ) dx y The power CCDF curve shows the probability that the instantaneous signal power will be higher than the average signal power by a certain amount of db. The X axis of the CCDF curve shows power levels in db with respect to the signal average power level (0 db corresponds to the signal average power level). The Y axis of the CCDF curve shows the probability that the instantaneous signal power will exceed the corresponding power level on the X axis. Figure 6-7 shows the CCDF curve for a WLAN a 54 Mbps signal. In Figure 6-7, you can see that the instantaneous signal power exceeds the average signal power (0 db) for approximately 20% of the time. You can also see that the instantaneous signal power exceeds the average signal power by 5 db for only 0.7% of the time. For signals that are transmitted in bursts or in slots this measurement should be performed only when the signal is active (on) and not during the idle intervals or inactive slots. 6-6 Transmission Test Measurements

47 Figure 6-7. Power CCDF Curve for a WLAN a 54 Mbps Signal Code Domain Power (CDP) For signals that use Code Division Multiple Access (CDMA) techniques, CDP is another useful power measurement. CDP shows the distribution of the signal s power in the code domain. Figure 6-8 shows the results of a CDP measurement for a 3GPP FDD Test Model 3 signal (based on version of the standard) with 16 DPCHs. Transmission Test Measurements 6-7

48 Wireless Measurement Definitions Figure 6-8. CDP Measurement for 3GPP FDD Test Model 3 Signal with 16 DPCHs In Figure 6-8, you can clearly see the 16 active DPCHs (occupying codes in the 64 to 128 range), as well as the primary CPICH (code 0), the P-CCPCH+SCH (code 1), and the PICH (code 16). Spectrum The spectrum measurement shows the spectrum of a signal, that is the distribution of the signal s power in the frequency domain. Most wireless standards specify a mask, to which the signal s spectrum must conform. The need for the transmitted signal spectrum to conform to a spectral mask is so that the interference to adjacent channels is minimized and kept at acceptable levels. Figure 6-9 is an example of a spectrum measurement and a spectral mask for a WLAN a signal. 6-8 Transmission Test Measurements

49 Measurement Mask Figure 6-9. Spectrum Measurement and Spectral Mask for WLAN a Signal Some wireless standards specify additional spectrum related measurements. For example, the 3GPP FDD standard defines the following spectrum measurements: Adjacent channel leakage ratio (ACLR) is the ratio of the transmitted power to the power measured after a receiver filter in the adjacent channel(s). Occupied Bandwidth is the bandwidth that contains 99% of the signal s total transmitted power. The bandwidth is centered around the channel frequency so that the total power outside this bandwidth is split equally (0.5% of the total transmitted power) between the bands below and above it. Figure 6-10 shows the definition of the occupied bandwidth. Transmission Test Measurements 6-9

50 Wireless Measurement Definitions Figure Occupied Bandwidth Definition EVM The EVM (error vector magnitude) measurement provides a metric for the modulation quality/accuracy of a signal. EVM is a measure of the difference between the measured signal and an ideal reference signal. While EVM may be defined differently in each wireless standard, the basic concept is described here. Let S(k), k = 1,..., N, be the ideal transmitted signal sampled at one sample per symbol (or chip) at the optimal (zero-isi) instance. The actual transmitted signal can be modeled as Zk ( ) = [ C 0 + C 1 ( Sk ( ) + Ek ( ))]W k where: W = e Dr+jDa, accounts for both a frequency offset (Da radians/symbol phase rotation) and an amplitude change rate (Dr nepers/symbol) C 0 is a complex constant representing origin offset C 1 is a complex constant representing the arbitrary phase and output power of the transmitter E(k) is the residual vector error on sample S(k) 6-10 Transmission Test Measurements

51 The sum square error vector is N 1 = 0 Ek ( ) 2 = where C 0, C 1, W are chosen such as to minimize the above expression. EVM (rms) is defined to be the rms value of E(k) normalized by the rms value of S(k). Therefore, EVM( rms) = 0 In addition to the EVM rms value, the EVM analysis provides other useful results, such as: Peak EVM Symbol (or chip) where the peak EVM occurs rms magnitude error (difference between the magnitudes of the ideal and reference signals) Peak magnitude error Symbol (or chip) where the peak magnitude error occurs rms phase error (difference between the phases of the ideal and reference signals) Peak phase error Symbol (or chip) where the peak phase error occurs Frequency error N 1 [ Zk ( )W k C 0 ] Sk ( ) C 1 = 0 N 1 1 N ---- Ek ( ) 2 k = 0 = = N 1 1 N ---- Sk ( ) 2 N 1 Ek ( ) 2 k = N 1 IQ offset (some wireless standards do not remove IQ offset from the measured signal and so this type of distortion is included in the EVM value) For signals that use code division multiple access (CDMA) techniques, peak code domain error (PCDE) is another useful measurement related to EVM. To get the = 0 Sk ( ) 2 Transmission Test Measurements 6-11

52 Wireless Measurement Definitions PCDE value, the error vector E(k) is first projected on the code domain. This is done by calculating the inner-product between E(k) and all the orthogonal vectors in the channelization code set (all codes belonging to the one spreading factor). Then the maximum projection is selected and normalized by the rms value of the reference signal. Receiver Test Measurements BER Measurements A receiver s performance is determined by its ability to receive and demodulate a wanted signal in the presence of noise and/or other interfering signals. Although there are several measurements used to test a receiver s performance, all of them measure the same quantity under different conditions. The measured quantity is the bit error rate (BER). BER is the probability that a transmitted bit will be received and detected in error. Of course, better receivers have a lower BER. Different wireless standards give different names to various BER measurements such as: Minimum Input Power Sensitivity, Minimum Input Level Sensitivity, Adjacent Channel Rejection, Adjacent Channel Selectivity, Reference Sensitivity Level, Dynamic Range, Blocking, Intermod. As mentioned earlier, all the above measurements are BER measurements under different conditions. These different conditions include additive white gaussian noise (AWGN), modulated interference signals, and CW interference signals. The interference signals can be in band and/or out of band. Typically, the standards specify that the BER should not exceed a certain value for certain power levels of the wanted and interfering signals, and a certain frequency offset (between the wanted signal s channel frequency and the frequency of the interfering signals). E b /N o Definition Bit error rate (BER) and Frame and packet error rate (FER/PER) are typically reported with respect to E b /N o. This note defines E b /N o and relates it to signal to noise ratio (SNR). Distinction is made of local and system E b /N o. The following discussion is based on similar discussions published by Bernard Sklar [1], [2]. For this discussion Figure 6-11 illustrates a typical RF comm system receiver block diagram Receiver Test Measurements

53 S A, S B, S C, TX N 0A A RX DUT 1 NF 1, G 1 N 0B B RX DUT 2 NF 2, G 2 N 0C C Detector DSP and BER Meas R RX Antenna T a In Figure 6-11: Figure Typical RF Comm System Receiver Block Diagram The initial two blocks represent the transmitted signal and the propagation channel between the transmit and receive antennas. The transmitted signal contains data with bit time T b with bit rate R bits/sec. The propagation channel includes significant attenuation and propagation effects (phase, amplitude, multi-path fading, etc.). A is the receiver antenna output. B is a mid point within the receiver system. C is the receiver system pre-detection point. RX DUT 1 is the receiver RF frontend and contains any lossy lines before the receiver and receiver front-end amplifiers, filters, and mixers. For this discussion it is defined with gain in db (G 1 ) and noise figure in db (NF 1 ). RX DUT 2 is the receiver backend and contains content before detection and includes amplifiers, filters, matched filter, and sampler. For this discussion it is defined with gain in db (G 2 ) and noise figure in db (NF 2 ). The BER is then measured, typically with suitable DSP algorithms. At each A, B, and C point in the system, there is a measurable value for the signal (S A, S B, S C ) and noise density (N OA, N OB, N OC ), where the signal is in Watts (W) and noise density is in Watts/Hz (W/Hz). In this system, and for discussion purposes, the received desired signal has additive thermal noise contributions from the propagation path available at the receiver antenna output and from the receiver noise figures. Other noise contributors are ignored, such as interfering signals and nonlinear intermodulation products. Thermal noise at the receiver antenna output is typically defined in terms of noise temperature in Kelvin. Call this T A. Note that 290 K (16.85 o C) corresponds to a noise power density of dbm/hz value. Receiver Test Measurements 6-13

54 Wireless Measurement Definitions The receiver antenna output noise power density is: N 0A = k T a, where k is Boltzmann s constant. Receiver noise figures can also be represented in terms of noise temperature in Kelvin: T = 290 (F-1) where F = 10 (NF/10). The RF DUT 1 and 2 have associated noise temperatures at T 1 and T 2 respectively. T 1 = 290 (F 1-1); F 1 = 10 (NF 1 /10) T 2 = 290 (F 2-1); F 2 = 10 (NF 2 /10) T 1 represents the equivalent noise temperature due to RF DUT 1 defined at the input of RF DUT 1 and has associated noise power density: k T1. This results in definition for N 0B as: N 0B = G 1 (k T a ) + G 1 (k T 1 ) = G 1 k (T a +T 1 ) T 1 represents the equivalent noise temperature due to RF DUT 2 defined at the input of RF DUT 2 and has associated noise power density: k T 2. This results in definition of N 0C as: N 0C = G 1 G 2 (k T a ) + G 1 G 2 (k T 1 ) + G 2 (k T 2 ) = G 1 G 2 k (T a +T 1 +T 2 /G 2 ) SNR is related to E b /N o in the following way: SNR E b S T b E b R = ---- = = = N N 0 N BW N 0 N BW E b N 0 R N BW where: SNR = signal-to-noise ratio (unitless) S = signal power (W) N = noise power (W) E b = bit energy (W / sec) T b = bit time (sec) N BW = receiver noise bandwidth (Hz) N 0 = noise power density = N / N BW (W/Hz) R = data rate = 1/ T b (1/sec) E b /N 0 = E b over N 0 (unitless) 6-14 Receiver Test Measurements

55 To provide a signal-to-noise figure that is independent on the receiver noise bandwidth, the signal-to-noise density is typically used. S N 0 E b T b E b R = = = N 0 N 0 E b R N 0 Thus, we now see the relationship between E b /N 0 and S/N o and S/N. E b N 0 S NBW = = N R S N R S/N o and E b /N 0 values may be considered as local or system values. Local values are specific to the receiver system point where they are evaluated (points A, B, or C in Figure 6-11); system values are independent of the receiver system point where they are evaluated. Local values of S/N o and E b /N 0 are directly measurable at each point in the system and are typically the preferred S/N o and E b /N 0 values used by RF/analog designers. At points A, B, and C, the local S/N o values are: S A /N OA = S A /(k T a ) S B /N OB = (S A G 1 )/(k (T a +T 1 ) G 1 ) = S 1 /(k (T a +T 1 )) S C /N OC = (S A G 1 G 2 )/(G 1 G 2 k (T a +T 1 )+G 2 k T 2 ) = S A /(k (T a +T 1 +T 2 /G 1 ) System values of E b /N 0 and S/N o are directly measurable only at the pre-detection system point (point C in Figure 6-11). These are the system values because they characterize the overall system performance. The system values are typically the preferred S/N o and E b /N 0 values used by System/DSP designers. In all cases, E b /N 0 = S/N o /R At point C, the local E b /N 0 and S/N o values are the same as the system E b /N 0 and S/N o values. Receiver Test Measurements 6-15

56 Wireless Measurement Definitions Summary Local S/N o and E b /N 0 values are not the same at all points of measurement in the receiver. System S/N o and E b /N 0 values are only measurable at the receiver pre-detection point (point C in Figure 6-11), may be inferred at the other receiver points (points A and B) and have only one value defined for the system. Always specify if the S/N 0 or E b /N o you are using is the Local or the System value. In the Wireless Test Bench data displays, the E b /N o value used is the local E b /N o value at the receiver input, equivalent to point A in Figure E b /N o References [1] Sklar, Bernard, Digital Communications: Fundamentals and Applications, 2nd Edition, Prentice-Hall, N.J., [2] Sklar, Bernard, RF Resign: Will the Real E b /N o Please Stand Up, Communication Systems Design, April, References [1] Agilent Application Note Characterizing Digitally Modulated Signals with CCDF Curves. [2] Agilent PN (Product Note) Using Error Vector Magnitude Measurements to Analyze and Troubleshoot Vector-Modulated Signals References

57 Appendix A: Creating Wireless Test Bench Designs for RFDE Introduction Using Ptolemy in ADS, a system designer can create a DSP system design that is available to an RFIC designer as a wireless test bench (WTB) model. The wireless test bench is a mechanism by which a system designer can make system measurements available to an RFIC designer. The RFIC designer can then validate and verify the RFIC design or device under test (DUT). This appendix describes how to create and verify, then export a WTB design to RFDE. Creating a Wireless Test Bench Design Creating wireless test bench designs using Ptolemy components in ADS is similar to setting up other Analog/RF designs for cosimulation. The design must be created in a DSP schematic using only DSP components. The WTB design can be split between two parts. The first part of the WTB design is the group of components that generate a signal appropriate for simulating the RFIC or DUT. Ports (appropriately named) added at the output of this part of the design will act as WTB model output and DUT input when used in RFDE. The second part of the WTB design is the group of components that process the DUT output and perform various system measurements using Ptolemy Sink components. Ports (appropriately named) added at the input of this part of the design act as WTB model input and DUT output. The input ports must have an EnvOutSelector or EnvOutShort (from the Circuit Cosimulation library) to select the correct frequency to be extracted from the Circuit Envelope analysis of the DUT for system measurement. Any port that is not connected to an EnvOutSelector or EnvOutShort is considered to be an output port. A DF controller (from the Controller library) must be added to the design that uses the correct setup of scheduler type, deadlock manager, and other parameters. A-1

58 Creating Wireless Test Bench Designs for RFDE Create the WTB design parameters that the RFIC designer can use to modify the WTB design s configuration, using the File > Design Parameters in the ADS schematic window. Wireless Test Bench Design Examples For examples on how to create a WTB design for export to RFDE, look at the designs listed with the example projects in Table A-1. Each design has instances of the pre-configured WTB model components. Push into the components to view the design. These projects are contained in the TDSCDMA, WCDMA3G, and WLAN Design Libraries and can be installed by using the custom installation option. Table A-1. Wireless Test Bench Design Examples Example Project Design License Required TDSCDMA_RF_Verification_prj WCDMA3G_RF_Verification_prj WLAN_RF_Verification_prj TDSCDMA_Uplink_TX_test.dsn 3GPPFDD_BS_TX_test.dsn WLAN_802_11a_TX_test.dsn mdl_tdscdma mdl_wcdma3g mdl_wlan Push into the instance of TDSCDMA_Uplink_TX. This design is not in the project networks directory. It is in the $HPEESOF_DIR/adsptolemy/design directory. This is the design that may be exported to RFDE. Push into the instance of 3GPPFDD_BS_TX. This design is not in the project networks directory. It is in the $HPEESOF_DIR/adsptolemy/design directory. This is the design that may be exported to RFDE. Push into the instance of WLAN_802_11a_TX. This design is not in the project networks directory. It is in the $HPEESOF_DIR/adsptolemy/design directory. This is the design that may be exported to RFDE. Note RangeCheck components used in the pre-configured WTB designs are created specifically for those WTB designs. Do not use the RangeCheck components when you create your own WTB designs. Setting the Units for WTB Design Parameters The system designer can use the list of units provided in the Design Parameter dialog box to correctly specify the unit used for a parameter. If the parameter value is a unit that is not part of the list, such as percent, and the system designer wants to communicate the units to the RFIC designer, then the unit can be placed within parentheses at the end of the parameter s description text. A-2

59 Categorizing WTB Design Parameters WTB designs support a feature that enables a person using the WTB design to categorize the parameters. It is helpful for the System designer to group the parameters in a way that makes it easier for the RFIC designer. To categorize the list of parameters, define a string type of parameter at the beginning of the group of parameters that belong in a category. The parameter must have a description field specified that contains a very short description of the category. The parameter's default value must be set to Category to identify this parameter as a categorization parameter. And, the parameter s attributes must be set such that it will not be netlisted and not displayed. The group of parameters will appear in different tabs in the Wireless Test Bench Setup dialog in RFDE. The first group of parameters are considered Required Parameters and will appear in a separate widget along with the ports in the top half of the Wireless Test Bench Setup dialog box. These parameters are considered as parameters that must have value (they cannot be blank). All subsequent groups of parameters will be considered as optional parameters for modification. Information Parameters The system designer can insert various information parameters that describe a particular aspect of the WTB design, such as instructions related to timing setup. To create such a parameter, define a string type of parameter and set its attribute such that it will not be netlisted and will not be displayed on the schematic. Leave the parameter's default value blank. Verifying a WTB Design in ADS To verify a WTB design in ADS: 1. Create a DUT in ADS. Add an Envelope controller inside this DUT. 2. Open a new DSP schematic window. 3. Add an instance of the WTB design and the instance of the DUT; connect them. 4. Add a WTB controller. 5. Simulate this design and generate the dataset to verify the results. A-3

60 Creating Wireless Test Bench Designs for RFDE Important Do not use more than one unconnected DUT design or Envelope controller during WTB design verification in ADS. Exporting a WTB Design to RFDE After creating a WTB design as described in Creating a Wireless Test Bench Design on page A-1, export the design so it can be used in RFDE. To export the WTB design, save it and select Tools > Export WTB Design to RFDE in the schematic window containing the design. An Export Status/Error/Warning dialog box appears showing the exporting progress. A temporary design window will open where the WTB design will be instantiated before the export starts. A successful export process generates the files <WTBname>_TB.il and <WTBname>_TB.net. These files are saved with the exported design under the project directory..._prj/adsptolemy/wtb. WTB Design User Interface Attributes Each WTB design has a category to which it belongs. The category name is the project name from which it was exported without the _prj extension. The WTB design name is same as the corresponding design name. The Wireless Test Bench Setup dialog in RFDE contains a pull-down list of categories. Each category selection updates another pull-down list containing WTB models exported from a single project. Following the WTB model selection pull-down list is the Required Parameters widget that contains the ports that can be connected to the DUT, along with the first group of parameters created by the system designer. If no categories are created, all of the parameters are included as part of this widget. The items in this widget cannot be left blank, or unspecified, and must contain some value. To aid WTB model and DUT port connection, a button is provided, per port, that takes the RFIC designer to the schematic window to select a pin on the DUT. Following the Required Parameters widget is a widget containing tabs for all subsequent parameter groups. The tab name is the description specified for the categorization parameter. These parameters are optional parameters for modification. A-4

61 Creating a Results Display for WTB Designs A WTB design can have complex data that the RFIC designer will not know how to interpret. To help simplify data analysis, the System designer must use the following steps: 1. System designer must use a simple DUT in ADS to create a dataset. 2. Open a new DDS window. Add one or more new pages and name them appropriately. 3. Leave page 1 untouched and blank; this page is used for other Analog/RF automatic plots. 4. Add correct equations/plots/configurations on the new pages. 5. Save this DDS file as a template by choosing File > Save as Template on the DDS window. Select the User category to save the template. 6. The template file is saved under $HOME/hpeesof/circuit/templates. 7. Copy the template file to _prj/adsptolemy/templates. 8. Place an OutputOption controller in the WTB design s schematic window. (The OutputOption component can be placed at any level of hierarchy in the WTB design.) 9. Add the data display template name, created above, to the list of names. More than one data display template is allowed for a given WTB design. 10. Re-export the WTB design. Now, when this WTB design is used in an RFDE simulation, the templates named in the OutputOption controller will be inserted in the DDS window that appears at the end of the simulation. A-5

62 Creating Wireless Test Bench Designs for RFDE Circuit Envelope Parameters Some parameters must be defined as WTB design parameters to ensure compliance with Circuit Envelope requirements within the WTB design s simulation setup. CE_TimeStep The WTB design must have a CE_TimeStep parameter that enables the RFIC designer to set the Circuit Envelope time step. If this parameter is not added to a WTB design, the time step will always be set to 0.01µsec. FSource The WTB design can optionally have an FSource parameter to enable the RFIC designer to set the source carrier frequency. This parameter will automatically be added to the Fundamental Tones parameters of Circuit Envelope after the WTB design is set up in RFDE. To ensure correct behavior this frequency must not be deleted from the Fundamental Tones. FMeasurement The WTB design can optionally have an FMeasurement parameter to enable the RFIC designer to set the measurement carrier frequency. This parameter will automatically be added to the Fundamental Tones parameters of Circuit Envelope after the WTB design is set up in RFDE. To ensure correct behavior this frequency must not be deleted from the Fundamental Tones. A-6

63 Index Numerics 3GPP FDD wireless source descriptions, 5 wireless test bench model descriptions, 3 A ABM_AmpPts, 18 ABM_Delay, 19 ABM_FreqComp, 19 ABM_FreqPts, 18 ABM_MaxPower, 18 ABM_PhasePts, 18 ABM_ReUseData, 19 ABM_VTime, 19 ABM_VTol, 19 Adjacent Channel Rejection, 12 Adjacent Channel Selectivity, 12 ADS Ptolemy, 1 adslib, 1 analysis running, 20 viewing results, 1 Automatic Verification Modeling (AVM), 14 limitations, 17 Automatic Verification Modeling (fast cosimulation) parameters, 18 autoplot, 1 AVM, 18 B BER (Bit Error Rate) measurements Eb/No definition, 12 list of, 12 BER (bit error rate) measurements defined, 12 Blocking, 12 C Circuit Envelope analysis, 1, 10 component library, adslib, 1 Connection Manager, 1 discovering instruments, 1 instrument discovery defined, 1 measurement exploration defined, 1 constellation measurement, 1 cosimulation, 1, 10 D data display, 1 design preparing for WTB analysis, 4 directory paths updating, 4 distributed simulation, 20 viewing results, 1 DUT connecting ports, 8 Dynamic Range, 12 E Eb/No, 12 noise density, 13 signal-to-noise ratio, 14 thermal noise, 13 EVM (error vector magnitude) measurement, 10 examples, 6 exporting models, 1 Expression Builder, 1 expressions See wireless expressions F Fast Cosim See Automatic Verification Modeling FMeasurement, 11 impact on Fundamental Tones, 11 Frame and Packet Error Rate (Eb/No), 12 FSource, 11 impact on Fundamental Tones, 11 Fundamental Tones setting, 11 H Help on WTB models, 13 I importing models, 1 instrument connections, 1 instrument discovery defined, 1 Index-1

64 how to, 1 instruments compatibility with test benches, 3 Intermod, 12 L library, adslib, 1 licenses, required, 2 M measurement exploration defined, 1 measurements BER (bit error rate), 12 constellation, 1 EVM (error vector magnitude), 10 power, 5 receiver test, 12 RF envelope, 1 spectrum, 8 transmission test, 1 Minimum Input Level Sensitivity, 12 Minimum Input Power Sensitivity, 12 Monte Carlo analysis, 21 O opening WTB models, 6 optimizations, 21 P parameters ABM_AmpPts, 18 ABM_Delay, 19 ABM_FreqComp, 19 ABM_FreqPts, 18 ABM_MaxPower, 18 ABM_PhasePts, 18 ABM_ReUseData, 19 ABM_VTime, 19 ABM_VTol, 19 AVM, 18 Monte Carlo/Yield analysis, 21 optimizations, 21 optional for analysis, 14 optional for WTB model, 13 required for WTB model, 9 resetting to default values, 9, 13 setting, 11 sweeping, 21 Path Editor, 1 power measurement, 5 Ptolemy, 1 R receiver test measurements, 12 Reference Sensitivity Level, 12 remote simulation, 20 RF envelope measurement, 1 RFIC design preparing for WTB analysis, 4 S simulation distributed, 20 remote, 20 running, 20 viewing results, 1 sources See wireless sources spectrum measurement, 8 sweeping parameters, 21 T TD-SCDMA wireless source descriptions, 5 wireless test bench model descriptions, 3 test benches See wireless test bench models transmission test measurements, 1 U updating directory paths, 4 V VISA Resource, 2 W Wireless Expressions defined, 2 list of, 5 using, 2 wireless expressions db( fs() ), 6 dbm( fs() ), 6 evm_wlan_dsss_cck_pbcc(), 5 evm_wlan_ofdm(), 5 fs(), 5 mag(), 6 Index-2

65 named node, 6 peak_pwr(), 6 peak_to_avg_pwr(), 6 phase(), 6 power_ccdf(), 6 power_ccdf_ref(), 5 pwr_vs_t(), 6 real(), 5 spectrum_analyzer(), 6 total_pwr(), 6 Wireless Sources defined, 2 list of, 5 using, 1 wireless sources 3GPPFDD_DnLink, 5 3GPPFDD_UpLink, 5 TDSCDMA_DnLink, 5 TDSCDMA_UpLink, 5 WLAN_802_11a, 5 WLAN_802_11b, 5 Wireless Test Bench Models connecting to DUT, 8 defined, 1 exporting, 1 help, 13 importing, 1 list of, 3 opening, 6 running simulation, 20 setup for analysis, 7 wireless test bench models 3GPPFDD_BS_RX, 3 3GPPFDD_BS_TX, 3 3GPPFDD_UE_RX, 3 3GPPFDD_UE_TX, 3 TDSCDMA_DnLnk_MultiCarrier_TX, 4 TDSCDMA_DnLnk_RX_ACS, 4 TDSCDMA_DnLnk_TX, 4 TDSCDMA_UpLnk_RX_Sensitivity, 4 TDSCDMA_UpLnk_TX, 4 WLAN_802_11a_RX_ACR, 4 WLAN_802_11a_RX_Sensitivity, 4 WLAN_802_11a_TX, 3 WLAN_802_11b_RX_Sensitivity, 4 WLAN_802_11b_TX, 4 Wireless Test Bench, defined, 1 WLAN wireless source descriptions, 5 wireless test bench model descriptions, 3 Y yield analysis, 21 Index-3

66 Index-4