ICS379. Quad PLL with VCXO Quick Turn Clock. Description. Features. Block Diagram

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1 Quad PLL with VCXO Quick Turn Clock Description The ICS379 QTClock TM generates up to 9 high quality, high frequency clock outputs including a reference from a low frequency pullable crystal. It is designed to replace crystals and crystal oscillators in most electronic systems. The ICS379 contains a One-Time Programmable (OTP) ROM which is factory programmed with PLL divider values to output a broad range of frequencies up to 200 MHz, allowing customer requests for different frequencies to be shipped within days. Programming features include a selectable frequency table and two banks of up to 4 low-skew outputs. Using Phase-Locked-Loop (PLL) techniques, the device runs from a standard fundamental mode, inexpensive crystal, or clock. It can replace multiple crystals and oscillators, saving board space and cost. Features Packaged in 20 pin SSOP (QSOP) Quick turn frequency programming allows samples within days Output frequencies of up to 200 MHz at 3.3V Can include nine selectable output frequencies Up to four reference outputs Two banks of four, low skew outputs Replaces a VCXO plus multiple crystals and oscillators On-chip patented VCXO pull range 200 ppm (minimum) Input crystal frequency of MHz Duty cycle of 45/55 Operating voltage of 3.3V or 5V Advanced, low power, CMOS process Block Diagram VDD CLK1 OTP ROM with S1:S0 2 CLK2 PLL Divider PLLA Values CLK3 Divide PLLB Logic CLK4 and MHz Output CLK5 PLLC Pullable Enable Crystal Control CLK6 X1 X2 Voltage Controlled Crystal Oscillator Capacitors are required with a crystal input. PLLD CLK7 CLK8 CLK9 OE GND MDS 379 A 1 Revision

2 Pin Assignment X1 S0 S1 CLK9 VDD GND CLK1 CLK2 CLK3 CLK X2 19 VDD 18 OE 17 VIN 16 VDD 15 GND 14 CLK5 13 CLK6 12 CLK7 11 CLK8 20 pin (150 mil) SSOP Pin Descriptions Pin Number Pin Name Pin Type Pin Description 1 XI Input Crystal connection. Connect to fundamental mode pullable crystal. 2 S0 Input Select pin 0 for frequency table/chip control. Internal pull-up resistor. 3 S1 Input Select pin 1 for frequency table/chip control. Internal pull-up resistor. 4 CLK9 Output Clock output 9. 5, 16, 19 VDD Power Connect to +3.3 V. 6, 15 GND Power Connect to ground. 7 CLK1 Output Clock output 1. Independent or low skew (Bank A) output. 8 CLK2 Output Clock output 2. Independent low skew (Bank A) or reference output. 9 CLK3 Output Clock output 3. Independent low skew (Bank A) or reference output. 10 CLK4 Output Clock output 4. Independent or low skew (Bank A) output. 11 CLK8 Output Clock output 8. Independent or low skew (Bank ) output. 12 CLK7 Output Clock output 7. Independent low skew (Bank B) or reference output. 13 CLK6 Output Clock output 6. Independent low skew (Bank B) or reference output. 14 CLK5 Output Clock output 5. Independent or low skew (Bank B) output. 17 VIN VI VCXO Voltage input. Zero to 3.3 V analog control voltage for VCXO. 18 OE Input Output enable pin. Active high. 20 X2 Input Crystal connection. Connect to fundamental mode pullable crystal. Key: MDS 379 A 2 Revision

3 External Components The ICS379 QTClock provides the facility for up to 9 outputs. The outputs are derived from either the reference input or from one of the four PLLs. All chip functions are controlled from an OTP ROM which has 2 input control lines (S1, S0), giving a total of four address locations. Each address location gives control of the following: 1) Each output can be turned off individually 2) The internal dividers for each PLL are controlled to generate any required frequency 3) Each PLL can be turned off (output enable) individually to lower power consumption 4) The output divide and control logic can be configured to bring the appropriate clock to the correct pin 5) Up to four low skew copies of the same clock can be enabled This chip architecture provides the user with unrivaled flexibility. For example, one of the input pins can be used to control the power of the chip by shutting down PLLs and outputs when not in use. A second can be used to change the output clock frequencies. The specification is complete when the ICS379 QTClock Order Form accompanies this datasheet. The order form lists the input and CLK actual frequencies, as well as any other available options. This unique configuration is given two character alphanumeric programming code (ICS379-xxx), which must be specified when referring to samples. Frequency Select Table The ICS379 can be configured so that one PLL provides up to 9 frequency selections. For example, CPU frequencies of 66.7 MHz, MHz, MHz, and MHz can be included. This information should be indicated on the Order Form when the ICS379 is initially defined. External Components The ICS379 requires a minimum number of external components for proper operation. Decoupling Capacitor A decoupling capacitor of 0.01µF must be connected between VDD (pins 5 and 16) and GND (pins 6 and 15), as close to these pins as possible. For optimum device performance, the decoupling capacitor should be mounted on the component side of the PCB. Avoid the use of vias in the decoupling circuit. Series Termination Resistor When the PCB trace between the clock outputs and the loads are over 1 inch, series termination should be used. To series terminate a 50Ω trace (a commonly used trace impedance) place a 33Ω resistor in series with the clock line, as close to the clock output pin as possible. The nominal impedance of the clock output is 20Ω. Quartz Crystal The ICS379 VCXO function consists of the external crystal and the integrated VCXO oscillator circuit. To assure the best system performance (frequency pull range) and reliability, a crystal device with the recommended parameters (shown below) must be used, and the layout guidelines discussed in the following section must be followed. The frequency of oscillation of a quartz crystal is determined by its cut and by the load capacitors connected to it. The ICS379 incorporates on-chip variable load capacitors that pull (change) the frequency of the crystal. The crystal specified for use with the ICS379 is designed to have zero frequency error when the total of on-chip + stray capacitance is 14pF. Recommended Crystal Parameters: Initial Accuracy at 25 C Temperature Stability Aging Load Capacitance Shunt Capacitance, C0 C0/C1 Ratio Equivalent Series Resistance ±20 ppm ±30 ppm ±20 ppm 14 pf 7 pf Max 250 Max 35 Ω Max The external crystal must be connected as close to the chip as possible and should be on the same side of the PCB as the ICS379. There should be no via s between the crystal pins and the X1 and X2 device pins. There should be no signal traces underneath or close to the crystal. MDS 379 A 3 Revision

4 Crystal Tuning Load Capacitors The crystal traces should include pads for small fixed capacitors, one between X1 and ground, and another between X2 and ground. Stuffing of these capacitors on the PCB is optional. The need for these capacitors is determined at system prototype evaluation, and is influenced by the particular crystal used (manufacture and frequency) and by PCB layout. The typical required capacitor value is 1 to 4 pf. To determine the need for and value of the crystal adjustment capacitors, you will need a PC board of your final layout, a frequency counter capable of about 1 ppm resolution and accuracy, two power supplies, and some samples of the crystals which you plan to use in production, along with measured initial accuracy for each crystal at the specified crystal load capacitance, CL. To determine the value of the crystal capacitors: 1. Connect VDD of the ICS379 to 3.3V. Connect pin 17 of the ICS379 to the second power supply. Adjust the voltage on pin 3 to 0V. Measure and record the frequency of the CLK output. 2. Adjust the voltage on pin 3 to 3.3V. Measure and record the frequency of the same output. To calculate the centering error: Error 10 6 x ( f 3.0V f target ) + ( f f 0V t arg ) = et error xtal f target Where: f target = nominal crystal frequency error xtal =actual initial accuracy (in ppm) of the crystal being measured If the centering error is less than ±25 ppm, no adjustment is needed. If the centering error is more than 25ppm negative, the PC board has excessive stray capacitance and a new PCB layout should be considered to reduce stray capacitance. (Alternately, the crystal may be re-specified to a higher load capacitance. Contact ICS for details.) If the centering error is more than 25ppm positive, add identical fixed centering capacitors from each crystal pin to ground. The value for each of these caps (in pf) is given by: External Capacitor = 2 x (centering error)/(trim sensitivity) Trim sensitivity is a parameter which can be supplied by your crystal vendor. If you do not know the value, assume it is 30 ppm/pf. After any changes, repeat the measurement to verify that the remaining error is acceptably low (typically less than ±25ppm). PCB Layout Recommendations For optimum device performance and lowest output phase noise, the following guidelines should be observed. 1) The 0.01µF decoupling capacitor should be mounted on the component side of the board as close to the VDD pin as possible. No vias should be used between decoupling capacitor and VDD pin. The PCB trace to VDD pin should be kept as short as possible, as should the PCB trace to the ground via. Distance of the ferrite bead and bulk decoupling from the device is less critical. 2) The external crystal should be mounted just next to the device with short traces. The X1 and X2 traces should not be routed next to each other with minimum spaces, instead they should be separated and away from other traces. 3) To minimize EMI the 33Ω series termination resistor, if needed, should be placed close to the clock output. 4) An optimum layout is one with all components on the same side of the board, minimizing vias through other signal layers (the ferrite bead and bulk decoupling capacitor can be mounted on the back). Other signal traces should be routed away from the ICS379. This includes signal traces just underneath the device, or on layers adjacent to the ground plane layer used by the device. MDS 379 A 4 Revision

5 Absolute Maximum Ratings Stresses above the ratings listed below can cause permanent damage to the ICS379. These ratings, which are standard values for ICS commercially rated parts, are stress ratings only. Functional operation of the device at these or any other conditions above those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods can affect product reliability. Electrical parameters are guaranteed only over the recommended operating temperature range. Item Rating Supply Voltage, VDD 7V All Inputs and Outputs -0.5V to VDD+0.5V Ambient Operating Temperature 0 to +70 C Storage Temperature -65 to +150 C Junction Temperature 175 C Soldering Temperature 260 C Recommended Operation Conditions Parameter Min. Typ. Max. Units Ambient Operating Temperature C Power Supply Voltage (measured in respect to GND) V MDS 379 A 5 Revision

6 DC Electrical Characteristics Unless stated otherwise, VDD = 3.3V ±5%, Ambient Temperature 0 to +70 C Parameter Symbol Conditions Min. Typ. Max. Units Operating Voltage VDD V Supply Current IDD No load, Note 1 ma Input High Voltage V IH OE, S0, S1 2 V Input Low Voltage V IL OE, S0, S1 0.8 V Output High Voltage V OH I OH = -4 ma VDD-0.4 V Output High Voltage V OH I OH = -12 ma 2.4 V Output Low Voltage V OL I OL = 12mA 0.4 V Short Circuit Current I OS CLK output ±50 ma On Chip Pull-up Resistor, 150 kω inputs On-Chip Pull-down Resistor, 150 kω outputs Input Capacitance, inputs 5 pf AC Electrical Characteristics Unless stated otherwise, VDD = 3.3V ±5%, Ambient Temperature 0 to +70 C Parameter Symbol Conditions Min. Typ. Max. Units Output Rise Time t OR 0.8 to 2.0V 1 ns Output Fall Time t OF 2.0 to 0.8V 1 ns Cycle Jitter (short term jitter) t ja Note 1 TBD ps Input Frequency, crystal input MHz Output Frequency MHz Output Frequency Synthesis Note 1 0 TBD ppm Error Output Enable Time, PDTS 8 20 ms high to output on Output Disable Time, PDTS low TBD ms to tri-state Note 1: Values dependent on programming MDS 379 A 6 Revision

7 Package Outline and Package Dimensions (20 pin SSOP, 150 Mil. Body) Package dimensions are kept current with JEDEC Publication No Millimeters Inches INDEX AREA 1 2 D E1 E Symbol Min Max Min Max A A A b C D E E e Basic Basic L α A 2 A A 1 - C - c e b SEATING PLANE.10 (.004) C α L Ordering Information Part / Order Number Marking Shipping Package Temperature packaging ICS379M-xx ICS379M-xx Tubes 20 pin SSOP 0 to +70 C ICS379M-xxT ICS379M-xxT Tape and Reel 20 pin SSOP 0 to +70 C The -xx indicates a two character programming code, which must be specified when ordering parts. While the information presented herein has been checked for both accuracy and reliability, Integrated Circuit Systems (ICS) assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial applications. Any other applications such as those requiring extended temperature range, high reliability, or other extraordinary environmental requirements are not recommended without additional processing by ICS. ICS reserves the right to change any circuitry or specifications without notice. ICS does not authorize or warrant any ICS product for use in life support devices or critical medical instruments. MDS 379 A 7 Revision