GENLINX TMII GS9025A Serial Digital Receiver DATA SHEET DESCRIPTION * SMPTE 259M compliant The GS9025A provides automatic cable equalization and high performance clock and data recovery for serial digital signals. The GS9025A receives either single-ended or differential serial digital data and outputs differential clock and retimed data signals at PECL levels (800mV). The onboard cable equalizer provides up to 40dB of gain at 200MHz which typically results in equalization of greater than 350m of high quality cable at 270Mb/s. * operational to 540Mb/s * automatic cable equalization (typically greater than 350m of high quality cable at 270Mb/s) * adjustment-free operation * auto-rate selection (5 rates) with manual override * single external VCO resistor for operation with five input data rates The GS9025A operates in either auto or manual data rate selection mode. In both modes, the GS9025A requires only one external resistor to set the VCO centre frequency and provides adjustment free operation. * data rate indication output * serial data outputs muted and serial clock remains active when input data is lost * operation independent of SAV/EAV sync signals * signal strength indicator output * carrier detect with programmable threshold level * power savings mode (output serial clock disable) * Pb-free and Green APPLICATIONS Cable equalization plus clock and data recovery for all high speed serial digital interface applications involving SMPTE 259M and other data standards. The GS9025A has dedicated pins to indicate signal strength/carrier detect, LOCK and data rate. Optional external resistors allow the carrier detect threshold level to be customized to the user's requirement. In addition, the GS9025A provides an 'Output Eye Monitor Test' (OEM_TEST) for diagnostic testing of signal integrity after equalization, prior to reslicing. The serial clock outputs can also be disabled to reduce power. The GS9025A operates from a single +5 or -5 volt supply. ORDERING INFORMATION PART NUMBER PACKAGE TEMPERATURE Pb-FREE AND GREEN GS9025ACQM 44 pin MQFP Tray 0C to 70C No GS9025ACTM 44 pin MQFP Tape 0C to 70C No GS9025ACQME3 44 pin MQFP Tray 0C to 70C Yes GS9025ACTME3 44 pin MQFP Tape 0C to 70C Yes COSC A/D DDI LOCK ANALOG DIGITAL MUX DDI CARRIER DETECT PHASELOCK HARMONIC LOGIC MUTE SDO SDI + SDI -- FREQUENCY ACQUISITION VARIABLE GAIN EQ STAGE SDO CLK_EN PHASE DETECTOR SCO SCO OEM_TEST EYE MONITOR 3 BIT COUNTER DIVISION AUTO EQ CONTROL SMPTE AUTO/MAN + AGC CAP CD_ADJ SSI/CD CHARGE PUMP LF+ LFS LF- VCO DECODER SS0 SS1 SS2 CBG RVCO BLOCK DIAGRAM Revision Date: August 2005 Document No. 522 - 75 - 05 GENNUM CORPORATION P.O. Box 489, Stn. A, Burlington, Ontario, Canada L7R 3Y3 Tel. +1 (905) 632-2996 Fax. +1 (905) 632-5946 E-mail: info@gennum.com www.gennum.com GS9025A FEATURES ABSOLUTE MAXIMUM RATINGS PARAMETER VALUE Supply Voltage (VS) 5.5V Input Voltage Range (any input) VCC + 0.5 to VEE - 0.5V 0C TA 70C Operating Temperature Range GS9025A -65C TS 150C Storage Temperature Range Lead Temperature (soldering, 10 sec) 260C DC ELECTRICAL CHARACTERISTICS VCC = 5.0V, TA = 0 to 70C unless otherwise stated, RLF = 1.8k, CLF1 = 15nF, CLF2 = 3.3pF TEST LEVEL MIN TYPICAL1 MAX UNITS 4.75 5 5.25 V 3 CLK_EN = 0 - 115 mA 9 CLK_EN = 1 - 125 mA 3 - 2.4 - V 3 DDI Common Mode Input Voltage Range VEE+(VDIFF/2) 0.4 to 4.6 VCC-(VDIFF/2) V DDI Differential Input Drive 200 800 2000 mV 3 HIGH, 100m, 143Mb/s, OH=-10A - 4.2 - V 3 HIGH, 300m, 143Mb/s, OH=-10A - 3.7 - LOW, OL=1mA - 0.4 0.8 V 1 OEM_TEST Bias Potential RL=50 - 4.75 - V A/D High 2.3 - - V 3 Low - - 0.8 High 2.0 - - V 3 Low - - 0.8 High 2.5 - - V 3 Low - - 0.8 LOCK Output Low Voltage OL=500A - 0.25 0.4 V SS[2:0] Output Voltage HIGH, OH=-180A, Auto Mode 4.4 4.8 - V - 0.3 0.4 PARAMETER CONDITION Supply Voltage Supply Current SDI Common Mode Voltage SSI/CD Output Current AUTO/MAN, SMPTE, SS[2:0] Input Voltage CLK_EN Input Voltage LOW, OL=600A, Auto Mode NOTES 2 5 3 3 3 1 1 2 of 18 GENNUM CORPORATION 522 - 75 - 05 DC ELECTRICAL CHARACTERISTICS (Continued) VCC = 5.0V, TA = 0 to 70C unless otherwise stated, RLF = 1.8k, CLF1 = 15nF, CLF2 = 3.3pF PARAMETER SS[2:0] Input Voltage MIN TYPICAL HIGH, Manual Mode 2 LOW, Manual Mode Low, VIL = 0V 1 NOTES TEST LEVEL MAX UNITS - - V 3 - - 0.8 - 26 55 A 1 NOTES TEST LEVELS 1. TYPICAL - measured on EB9025A board. 1. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges. 2. VDIFF is the differential input signal swing. 3. LOCK is an open collector output and requires an external pull-up resistor. 4. Pins SS[2:0] are outputs in AUTO mode and inputs in MANUAL mode. 5. If OEM_TEST is permanently enabled, operating temperature range is limited from 0C to 60C inclusive. 2. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges using correlated test. 3. Production test at room temperature and nominal supply voltage. 4. QA sample test. 5. Calculated result based on Level 1,2, or 3. 6. Not tested. Guaranteed by design simulations. 7. Not tested. Based on characterization of nominal parts. 8. Not tested. Based on existing design/characterization data of similar product. 9. Indirect test. AC ELECTRICAL CHARACTERISTICS VCC = 5.0V, VEE = 0V, TA = 0 to 70C unless otherwise stated, RLF = 1.8k, CLF1 = 15nF, CLF2 = 3.3pF PARAMETER CONDITIONS Serial Data Rate SDI Maximum Equalizer Gain Additive Jitter MIN TYPICAL 1 MAX UNITS NOTES TEST LEVEL 143 - 540 Mb/s 3 @ 200MHz - 40 - dB 6 270Mb/s, 300m (Belden 8281) - 300 - ps p-p 2, 8 9 540Mb/s, 100m (Belden 8281) - 275 - 270Mb/s - 185 see Figure 12 ps p-p 2, 7 4 540Mb/s - 164 270Mb/s - 462 see Figure 13 ps p-p 2, 7 3 360Mb/s - 308 540Mb/s - 260 270Mb/s 0.40 0.56 - UI p-p 3, 7 9 540Mb/s 0.32 0.43 - tswitch < 0.5s, 270Mb/s - 1 - s 4 7 0.5s< tswitch <10ms - 1 - ms tswitch > 10 ms - 4 - ms Lock Time - Loop Bandwidth - 10 - ms 5 7 Asynchronous Switch = 6MHz @ 540Mb/s 23 [Pseudorandom (2 -1)] Intrinsic Jitter 23 [Pseudorandom (2 -1)] Intrinsic Jitter [Pathological (SDI checkfield)] Input Jitter Tolerance Lock Time Synchronous Switch 3 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A CLK_EN Source Current CONDITION AC ELECTRICAL CHARACTERISTICS (Continued) VCC = 5.0V, VEE = 0V, TA = 0 to 70C unless otherwise stated, RLF = 1.8k, CLF1 = 15nF, CLF2 = 3.3pF PARAMETER CONDITIONS SDO Mute Time SDO to SCO Synchronization MAX UNITS NOTES TEST LEVEL 1 2 s 6 7 -200 0 200 ps 7 MIN TYPICAL 0.5 1 75 DC load 600 800 1000 mV p-p 1 SDO, SCO Rise & Fall times 20%-80% 200 300 400 ps 7 SDI/SDI Input Resistance - 10 - k 8 6 SDI/SDI Input Capacitance - 1.0 - pF 8 6 Carrier Applied, - 3 - s 8, 9 6 Carrier Removed, - 30 - Carrier Detect Response Time NOTES TEST LEVELS 1. TYPICAL - measured on CB9025A board. 1. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges. 2. Characterized 6 sigma rms. 3. IJT measured with sinusoidal modulation beyond Loop Bandwidth (at 6.5MHz). 4. Synchronous switching refers to switching the input data from one source to another source which is at the same data rate (ie. line 10 switching for component NTSC). 5. Asynchronous switching refers to switching the input data from one source to another source which is at a different data rate. 2. Production test at room temperature and nominal supply voltage with guardbands for supply and temperature ranges using correlated test. 3. Production test at room temperature and nominal supply voltage. 4. QA sample test. 6. SDO Mute Time refers to the response of the SDO outputs from valid re-clocked input data to mute mode when the input signal is removed. 5. Calculated result based on Level 1,2, or 3. 7. Using the DDI input, A/D=0. 8. Not tested. Based on existing design/characterization data of similar product. 8. Using the SDI input, A/D=1. 9. Carrier detect response time refers to the response of the SSI/CD output from a logic high to logic low state when the input signal is removed or its amplitude drops below the threshold set by the CD_ADJ PIN. SSI/CD PIN loading CL<50pF, RL = open cct. DATA TEKTRONIX GigaBERT 1400 TRANSMITTER DATA GS9028 CABLE DRIVER 6. Not tested. Guaranteed by design simulations. 7. Not tested. Based on characterization of nominal parts. 9. Indirect test. BELDEN 8281 CABLE CB9025A BOARD TEKTRONIX GigaBERT 1400 ANALYZER CLOCK TRIGGER Fig. 1 Test Setup for Figures 6 - 13 4 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A SDO, SCO Output Signal Swing COSC 39 38 37 36 35 34 VEE LOCK 40 VCC SSI/CD 41 CLK_EN A/D 42 VEE SMPTE 43 31 SDO VCC 4 30 VEE VEE 5 GS9025A 29 SCO SDI 6 TOP VIEW 28 SCO SDI 7 27 VEE VCC 8 26 AUTO/MAN VEE 9 25 SS0 CD_ADJ 10 24 SS1 AGC- 11 23 SS2 13 14 15 16 17 18 19 20 21 22 VCC 12 CBG 3 RVCO VCC_75 RVCO_RTN SDO VEE 32 LF- 2 LFS DDI LF+ VEE VEE 33 VCC 1 AGC+ DDI GS9025A 44 OEM_TEST VCC_75 PIN CONNECTIONS PIN DESCRIPTIONS NUMBER SYMBOL TYPE DESCRIPTION 1, 2 DDI/DDI I Digital data inputs (Differential ECL/PECL). 3, 44 VCC_75 I Power supply connection for internal 75 pull-up resistors connected to DDI/DDI. 4, 8, 13, 22, 35 VCC I Most positive power supply connection. 5, 9, 14, 18, 27, 30, 33, 34, 37 VEE I Most negative power supply connection. 6, 7 SDI/SDI I Differential analog data inputs. 10 CD_ADJ I Carrier detect threshold adjust. 11, 12 AGC-, AGC+ I External AGC capacitor. VCOMMON MODE=2.7V TYP. 15 LF+ I Loop filter component connection. 16 LFS I Loop filter component connection. 17 LF- I Loop filter component connection. 19 RVCO_RTN I Frequency setting resistor return connection. 20 RVCO I Frequency setting resistor connection. 21 CBG I Internal bandgap voltage filter capacitor. 23, 24, 25 SS[2:0] I/O 26 AUTO/MAN I Data rate indication (auto mode) or data rate select (manual mode). TTL/CMOS compatible I/O. In auto mode, these pins can be left unconnected. Auto or manual mode select. TTL/CMOS compatible input. 5 of 18 GENNUM CORPORATION 522 - 75 - 05 PIN DESCRIPTIONS (Continued) SYMBOL TYPE DESCRIPTION 28, 29 SCO/SCO O Serial clock output. SCO/SCO are differential current mode outputs and require external 75 pull-up resistors. 31, 32 SDO/SDO O Equalized and reclocked serial digital data outputs. SDO/SDO are differential current mode outputs and require external 75 pull-up resistors. 36 CLK_EN I Clock enable. When HIGH, the serial clock outputs are enabled. 38 COSC I Timing control capacitor for internal system clock. 39 LOCK O Lock indication. When HIGH, the GS9025A is locked. LOCK is an open collector output and requires an external 10k pull-up resistor. 40 SSI/CD O Signal strength indicator/Carrier detect. 41 A/D I Analog/Digital select. 42 SMPTE I SMPTE/Other data rate select. TTL/CMOS compatible input. 43 OEM_TEST O Output `Eye' monitor test. Single-ended current mode output that requires an external 50 pull-up resistor. This feature is recommended for debugging purposes only. If enabled during normal operation, the maximum operating temperature is rated to 60C. For maximum cable length performance OEM_TEST must be disabled. 6 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A NUMBER TYPICAL PERFORMANCE CURVES (VS = 5V, TA = 25C unless otherwise shown) j1 j2 j0.5 j5 SSI/CD OUTPUT VOLTAGE (V) 4.50 270 3000 4.00 1620 -j0.2 3.50 -j5 810 3.00 -j0.5 -j2 2.50 0 50 100 150 200 250 300 350 400 450 500 -j1 Frequencies in MHz, impedances normalized to 50 CABLE LENGTH (m) Fig. 2 SSI/CD Voltage vs. Cable Length (Belden 8281) (CD_ADJ = 0V) Fig. 5 Input Impedance 50 450 45 400 40 JITTER (ps p-p) GAIN (dB) 35 30 25 20 15 540Mb/s 300 250 200 270Mb/s 150 100 10 50 5 0 (Characterized) 350 1 10 100 0 1000 0 50 100 150 200 250 300 350 400 CABLE LENGTH (m) FREQUENCY (MHz) Fig. 3 Equalizer Gain vs. Frequency Fig. 6 Typical Additive Jitter vs. Input Cable Length (Belden 8281) Pseudorandom (223-1) 450 5.0 400 CABLE LENGTH (m) CD_ADJ VOLTAGE (V) 4.5 4.0 3.5 3.0 350 300 250 200 2.5 150 2.0 200 250 300 350 100 400 200 300 400 500 600 DATA RATE (Mb/s) CABLE LENGTH (m) Fig. 4 Carrier Detect Adjust Voltage Threshold Characteristics Fig. 7 Typical Error Free Cable Length 7 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A j0.2 5.00 GS9025A 23 Fig. 8 Intrinsic Jitter (2 Fig. 11 Intrinsic Jitter (2 - 1 Pattern) 30Mb/s 23 - 1 Pattern) 540Mb/s 2000 1800 1600 JITTER (ps) 1400 1200 1000 800 600 Typical Range, Characterized 400 Max Typical Min 200 0 100 200 300 400 500 600 SDI DATA RATE (Mb/s) TA=0 to 70C, VCC=4.75 to 5.25V for the typical range Fig. 9 Intrinsic Jitter (223 - 1 Pattern) 143Mb/s Fig. 12 Intrinsic Jitter - Pseudorandom (2 23 - 1) 2000 1800 1600 JITTER (ps p-p) 1400 1200 1000 800 600 400 Max Typical Min 200 Typical Range, Characterized 0 100 200 300 400 500 600 SDI DATA RATE (Mb/s) TA = 0 to 70C, VCC = 4.75 to 5.25V for the typical range Fig. 10 Intrinsic Jitter (2 23 Fig. 13 Intrinsic Jitter - Pathological SDI Checkfield - 1 Pattern) 270Mb/s 8 of 18 GENNUM CORPORATION 522 - 75 - 05 0.5 IJT (UI) 0.4 0.3 0.2 0.1 0 100 200 300 400 500 600 The edge energy of the equalized signal is monitored by a detector circuit which produces an error signal corresponding to the difference between the desired edge energy and the actual edge energy. This error signal is integrated by an external differential AGC filter capacitor (AGC+/AGC-) providing a steady control voltage for the gain stage. As the frequency response of the gain stage is automatically varied by the application of negative feedback, the edge energy of the equalized signal is kept at a constant level which is representative of the original edge energy at the transmitter. DATA RATE (Mb/s) TA = 0 to 70C, VCC = 4.75 to 5.25V Fig. 14 Typical Input Jitter Tolerance (Characterized) 0.600 143Mb/s 0.550 177Mb/s 270Mb/s 0.500 360Mb/s 0.400 The equalized signal is DC restored, effectively restoring the logic threshold of the equalized signal to its corrective level irrespective of shifts due to AC coupling. 540Mb/s 0.350 0.300 1.1 0.250 0.200 0 10 20 30 40 50 60 70 TEMPERATURE (C) Fig. 15 Typical IJT vs. Temperature (VCC = 5.0V) (Characterized) DETAILED DESCRIPTION The GS9025A Serial Digital Receiver is a bipolar integrated circuit containing a built-in cable equalizer and reclocker. Serial digital signals are applied to either the analog SDI/SDI or digital DDI/DDI inputs. Signals applied to the SDI/SDI inputs are equalized and then passed to a multiplexer. Signals applied to the DDI/DDI inputs bypass the equalizer and go directly to the multiplexer. The analog/digital select pin (A/D) determines which signal is then passed to the reclocker. Signal Strength Indication/Carrier Detect The GS9025A incorporates an analog signal strength indicator/carrier detect (SSI/CD) output indicating both the presence of a carrier and the amount of equalization applied to the signal. The voltage output of this pin versus cable length (signal strength) is shown in Figures 2 and 16. With 0m of cable (800mV input signal levels), the SSI/CD output voltage is approximately 4.5V. As the cable length increases, the SSI/CD voltage decreases linearly providing accurate correlation between the SSI/CD voltage and cable length. Packaged in a 44 pin MQFP, the receiver operates from a single 5V supply to data rates of 540Mb/s. Typical power consumption is 575mW. 5 SSI/CD OUTPUT VOLTAGE (V) IJT (UI) 0.450 4 3 CD_ADJ CONTROL RANGE 2 1 1. CABLE EQUALIZER The automatic cable equalizer is designed to equalize serial digital data signals from 143Mb/s to 540Mb/s. 0 0 50 100 150 200 250 300 350 400 450 500 CABLE LENGTH (m) Fig. 16 SSI/CD Voltage vs. Cable Length 9 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A The serial data signal is connected to the input pins (SDI/SDI) either differentially or single-ended. An input return loss of 20dB at 270 Mb/s has typically been achieved on the CB9025A characterization board. The input signal then passes through a variable gain equalizing stage whose frequency response closely matches the inverse cable loss characteristic. The variation of the frequency response with control voltage imitates the variation of the inverse cable loss characteristic with cable length. The gain stage provides up to 40dB of gain at 200MHz which typically results in equalization of greater than 350m at 270Mb/s of Belden 8281 cable. 0.6 When the signal strength decreases to the level set at the "Carrier Detect Threshold Adjust" pin, the SSI/CD voltage goes to a logic "0" state (0.8 V) and can be used to drive other TTL/CMOS compatible logic inputs. When loss of carrier is detected, the SDO/SDO outputs are muted (set to a known static state). Additional SSI/CD output source current can be obtained in applications with a pull-up resistor. An external 5k pull-up resistor with less than 50pF capacitor loading is recommended. SDO SCO 1.2 Carrier Detect Threshold Adjust GS9025A 50% Fig. 17 Output and Clock Signal Timing Carrier Detect Threshold Adjust is designed for applications such as routers where signal crosstalk and circuit noise cause the equalizer to output erroneous data when no input signal is present. The GS9025A solves this problem with a user adjustable threshold which meets the unique conditions that exist in each application. Override and internal default settings are provided to give the user total flexibility. The threshold level at which loss of carrier is detected is adjustable via external resistors at the CD_ADJ pin. The control voltage at the CD_ADJ pin is set by a simple resistor divider circuit (see Typical Application Circuit). The threshold level is adjustable from 200m to 350m. By default (no external resistors), the threshold is typically 320m. In noisy environments, it is not recommended to leave this pin floating. Connecting this pin to VEE disables the SDO/SDO muting function and allows for maximum possible cable length equalization. The reclocker contains four main functional blocks: the Phase Locked Loop, Frequency Acquisition, Logic Circuit, and Auto/Manual Data Rate Select. 2.1 Phase Locked Loop (PLL) The Phase Locked Loop locks the internal PLL clock to the incoming data rate. A simplified block diagram of the PLL is shown below. The main components are the VCO, the Phase Detector, the Charge Pump, and the Loop Filter. DDI/DDI 2 PHASE DETECTOR INTERNAL PLL CLOCK DIVISION 1.3 Output Eye Monitor Test The GS9025A provides an 'Output Eye Monitor Test' (OEM_TEST) which allows the verification of signal integrity after equalization, prior to reslicing. The OEM_TEST pin is an open collector current output that requires an external 50 pull-up resistor. When the pull-up resistor is not used, the OEM_TEST block is disabled and the internal OEM_TEST circuit is powered down. The OEM_TEST provides a typical 100mVp-p signal when driving a 50 oscilloscope input. Due to additional power consumed by this diagnostic circuit, it is not recommended for continuous operation. NOTE: For maximum cable length performance the OEM_TEST block should be disabled. 2. RECLOCKER The reclocker receives a differential serial data stream from the internal multiplexer. It locks an internal clock to the incoming data. It outputs the differential PECL retimed data signal on SDO/SDO. It outputs the recovered clock on SCO/SCO. The timing between the output and clock signals is shown in Figure 17. CHARGE PUMP LF+ LFS RLF CLF1 VCO LF- RVCO LOOP FILTER CLF2 Fig. 18 Simplified Block Diagram of the PLL 2.1.1 VCO The VCO is a differential low phase noise, factory trimmed design that provides increased immunity to PCB noise and precise control of the VCO centre frequency. The VCO operates between 30 and 540Mb/s and has a pull range of 15% about the centre frequency. A single low impedance external resistor, RVCO, sets the VCO centre frequency (see Figure 19). The low impedance RVCO minimizes thermal noise and reduces the PLL's sensitivity to PCB noise. For a given RVCO value, the VCO can oscillate at one of two frequencies. When SMPTE = SS0 = logic 1, the VCO centre frequency corresponds to the L curve. For all other SMPTE/SS0 combinations, the VCO centre frequency corresponds to the H curve (H is approximately 1.5 x L). 10 of 18 GENNUM CORPORATION 522 - 75 - 05 2.1.4 Loop Filter 800 The loop filter integrates the charge pump packets and produces a VCO control voltage. The loop filter is comprised of three external components which are connected to pins LF+, LFS, and LF-. The loop filter design is fully differential which increases the GS9025's immunity to PCB board noise. 600 500 400 H 300 SMPTE=1 SSO=1 100 0 0 The loop filter components are critical in determining the loop bandwidth and damping of the PLL. Choosing these component values is discussed in detail in section 2.9, PLL Design Guidelines. Recommended values for SMPTE 259M applications are shown in the Typical Application Circuit. L 200 200 400 600 800 1000 1200 1400 1600 1800 RVCO () Fig. 19 RVCO vs. VCO Centre Frequency 2.2 Frequency Acquisition The recommended RVCO value for auto rate SMPTE 259M applications is 365. The VCO and an internal divider generate the PLL clock. Divider moduli of 1, 2, and 4 allow the PLL to lock to data rates from 143Mb/s to 540Mb/s. The divider modulus is set by the AUTO/MAN, SMPTE, and SS[2:0] pins (for further details, see section 2.4, Auto/Manual Data Rate Select). In addition, a manually selectable modulus 8 divider allows operation at data rates as low as 30Mb/s. The core PLL is able to lock if the incoming data rate and the PLL clock frequency are within the PLL capture range (which is slightly larger than the loop bandwidth). To assist the PLL to lock to data rates outside of the capture range, the GS9025A uses a frequency acquisition circuit. The frequency acquisition circuit sweeps the VCO control voltage so that the VCO frequency changes from -10% to +10% of the centre frequency. Figure 20 shows a typical sweep waveform. When the input data stream is removed for an excessive period of time (see AC Electrical Characteristics table), the VCO frequency can drift from the previously locked frequency to the limits shown in Table1. tsys tswp VLF TABLE 1: Frequency Drift Range (when PLL loses lock) A LOSES LOCK FROM MIN (%) MAX(%) 143Mb/s lock -21 21 177Mb/s lock -12 26 Fig. 20 Typical Sweep Waveform 270Mb/s lock -13 28 360 Mb/s lock -13 24 540 Mb/s lock -13 28 The VCO frequency starts at point A and sweeps up attempting to lock. If lock is not established during the up sweep, the VCO is then swept down. The probability of locking within one cycle period is greater than 0.999. If the system does not lock within one cycle period, it will attempt to lock in the subsequent cycle. In manual mode, the divider modulus is fixed for all cycles. In auto mode, each subsequent cycle is based on a different divider moduli as determined by the internal 3-bit counter. Tcycle Tcycle = tswp + tsys 2.1.2 Phase Detector The phase detector compares the phase of the PLL clock with the phase of the incoming data signal and generates error correcting timing pulses. The phase detector design provides a linear transfer function which maximizes the input jitter tolerance of the PLL. The average sweep time, tswp, is determined by the loop filter component, CLF1, and the charge pump current, CP: 2.1.3 Charge Pump The charge pump takes the phase detector output timing pulses and creates a charge packet that is proportional to the system phase error. A unique differential charge pump design ensures that the output phase does not drift when data transitions are sparse. This makes the GS9025A ideal for SMPTE 259M applications where pathological signals have data transition densities of 0.05. 4C LF1 t SWP = --------------3I CP The nominal sweep time is approximately 121s when CLF1 = 15nF and CP = 165A (RVCO = 365). An internal system clock determines tsys (see section 2.3, Logic Circuit). 11 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A VCO FREQUENCY (MHz) 700 2.3 Logic Circuit 2.4.2 Manual Mode (AUTO/MAN = 0) The GS9025A is controlled by a finite state logic circuit which is clocked by an asynchronous system clock. In other words, the system clock is completely independent of the incoming data rate. It runs at low frequencies, relative to the incoming data rate, thereby reducing interference to the PLL. The period of the system clock is set by the COSC capacitor and is In manual mode, the GS9025A divider moduli is fixed. In this mode, the SS[2:0] pins are inputs and set the divider moduli according to Table 3. TABLE 3. 4 t sys = 9.6 x 10 x C OSC [ sec onds ] The recommended value for tsys is 450s (COSC = 4.7nF). 2.4 Auto/Manual Data Rate Select SMPTE SS[2:0] DIVIDER MODULI PLL CLOCK 1 000 4 H/4 1 001 2 L/2 The GS9025A can operate in either auto or manual data rate select mode. The mode of operation is selected by a single input pin (AUTO/MAN). 1 010 2 H/2 1 011 1 L 1 100 1 H 2.4.1 Auto Mode (AUTO/MAN = 1) 1 101 8 L/8 In auto mode, the GS9025A uses a 3-bit counter to automatically cycle through five (SMPTE=1) or three (SMPTE=0) different divider moduli as it attempts to acquire lock. In this mode, the SS[2:0] pins are outputs and indicate the current value of the divider moduli according to Table 2. 1 110 8 H/8 1 111 - - 0 000 4 H/4 0 001 4 H/4 0 010 2 H/2 0 011 2 H/2 0 100 1 H 0 101 1 H 0 110 8 H/8 0 111 - - NOTE: For SMPTE = 0 and divider moduli of 2 and 4, the PLL can correctly lock for two values of SS[2:0]. TABLE 2. AUTO/MAN = 1 (AUTO MODE) H, L = VCO centre frequency as per Figure 19. SMPTE SS[2:0] DIVIDER MODULI PLL CLOCK 1 000 4 H/4 1 001 2 L/2 1 010 2 H/2 1 011 1 L 1 100 1 H 1 101 - - 1 110 - - 1 111 - - 0 000 4 H/4 0 001 4 H/4 0 010 2 H/2 0 011 2 H/2 0 100 1 H 0 101 - - 0 110 - - 0 111 - - 2.5 LOCKING The GS9025A indicates lock when three conditions are satisfied: 1. Input data is detected. 2. The incoming data signal and the PLL clock are phase locked. 3. The system is not locked to a harmonic. The GS9025A defines the presence of input data when at least one data transition occurs every 1s. The GS9025A assumes that it is NOT locked to a harmonic if the pattern `101' or `010' (in the reclocked data stream) occurs at least once every tsys/3 seconds. Using the recommended component values, this corresponds to approximately 150s. In a harmonically locked system, all bit cells are double clocked and the above patterns become `110011' and `001100', respectively. 12 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A AUTO/MAN = 1 (MANUAL MODE) H, L = VCO centre frequency as per Figure 19. 2.6 Output Data Muting The lock time of the GS9025A depends on whether the input data is switching synchronously or asynchronously. Synchronous switching means that the input data is changed from one source to another source which is at the same data rate (but different phase). Asynchronous switching means that the input data is changed from one source to another source which is at a different data rate. The GS9025A internally mutes the SDO and SDO outputs when the device is not locked. When muted, SDO/SDO are latched providing a logic state to the subsequent circuit and avoiding a condition where noise could be amplified and appear as data. The output data muting timing is shown in Figure 21. When input data to the GS9025A is removed, the GS9025A latches the current state of the counter (divider modulus). Therefore, when data is reapplied, the GS9025A begins the lock procedure at the previous locked data rate. As a result, in synchronous switching applications, the GS9025A locks very quickly. The nominal lock time depends on the switching time and is summarized in Table 4. NO DATA TRANSITIONS DDI LOCK SDO VALID DATA OUTPUTS MUTED VALID DATA TABLE 4. SWITCHING TIME LOCK TIME <0.5s 10s 0.5s - 10ms 2tsys >10ms 2Tcycle + 2tsys Fig. 21 Output Data Muting Timing 2.7 Clock Enable In asynchronous switching applications, including power up, the lock time is determined by the frequency acquisition circuit (see section 2.2, Frequency Acquisition). To acquire lock in manual mode, the frequency acquisition circuit may have to sweep over an entire cycle depending on initial conditions. Maximum lock time is 2Tcycle + 2tsys. To acquire lock in auto tune mode, the frequency acquisition circuit may have to cycle through 5 possible counter states depending on initial conditions. Maximum lock time is 6Tcycle + 2tsys. The nominal value of Tcycle for the GS9025A operating in a typical SMPTE 259M application is approximately 1.3ms. The GS9025A has a dedicated LOCK output (pin 39) indicating when the device is locked. NOTE: In synchronous switching applications where the switching time is less than 0.5s, the LOCK output will NOT be de-asserted and the data outputs will NOT be muted. 2.5.2 DVB-ASI When CLK_EN is high, the GS9025A SCO/SCO outputs are enabled. When CLK_EN is low, the SCO/SCO outputs are set to a high Z state and float to VCC. Disabling the clock outputs results in a power savings of 10%. It is recommended that the CLK_EN input be hard wired to the desired state. For applications which do not require the clock output, connect CLK_EN to ground and connect the SCO/SCO outputs to VCC. 2.8 Stressful Data Patterns All PLL's are susceptible to stressful data patterns which can introduce bit errors in the data stream. PLL's are most sensitive to patterns which have long run lengths of 0's or 1's (low data transition densities for a long period of time). The GS9025A is designed to operate with low data transition densities such as the SMPTE 259M pathological signal (data transition density = 0.05). 2.9 PLL Design Guidelines The reclocking performance of the GS9025A is primarily determined by the PLL. Thus, it is important that the system designer is familiar with the basic PLL design equations. A model of the GS9025A PLL is shown in Figure 22. The main components are the phase detector, the VCO, and the external loop filter components. Design Note: For DVB-ASI applications having significant instances of few bit transitions or when only K28.5 idle bits are transmitted, the wide-band PLL in the GS9025A may lock at 243MHz being the first 27MHz sideband below 270MHz. In this case, when normal bit density signals are transmitted, the PLL will correctly lock onto the proper 270MHz carrier. 13 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A 2.5.1 Lock Time PHASE DETECTOR + CP KPD VCO 2 K Ns - Oo RLF CLF2 CLF1 GS9025A LOOP FILTER AMPLITUDE Oi Fig. 22 Model of the GS9025A 2.9.1 WZ Transfer Function WP2 Fig. 23 Transfer Function Bode Plot The 3dB bandwidth approximately: sC LF1 R LF + 1 Oo 1 ------- = ---------------------------------------------------------------- --------------------------------------------------------L 2 L Oi s C LF1 R LF - --------- + 1 s C LF2 L + s --------+1 R LF R LF of the transfer function is w BW w BW w 3dB = ---------------------------------------------------------------------- -----------2 0.78 w BW ( w BW w P2 ) 1 - 2 ------------ + --------------------------------w P2 w BW 1 - 2 -----------w P2 Equation 1 N L = ------------------DI CP K WBW FREQUENCY The transfer function of the PLL is defined as Oo/Oi and can be approximated as: where WP1 and N is the divider modulus 2.9.2 D is the data density (=0.5 for NRZ data) Transfer Function Peaking ICP is the charge pump current in amps There are two causes of peaking in the PLL transfer function given by Equation 1. K is the VCO gain in Hz/V The first is the quadratic: This response has (wP1,wBW,wP2) where: 1 zero (wZ) and three 2 L s C LF2 L + s --------- + 1 R LF poles which has: 1 w Z = ---------------------C LF1 R LF 1 w o = -------------------C LF2 L 1 w P1 = -------------------------------------L C LF1 R LF - --------R LF and R LF2 Q = R LF ----------L This response is critically damped for Q = 0.5. Thus, to avoid peaking: R LF w BW = --------L C LF2 1 - < --R LF -----------2 L 1 w P2 = ---------------------C LF2 R LF The bode plot for this transfer function is plotted in Figure 23. or 1 L ------------------------- -------->4 R LF2 C LF2 R LF Therefore, wP2 > 4 wBW To reduce the high frequency content on the loop filter, keep wP2 as low as possible. The second is the zero-pole combination: s- + 1 -----sC LF1 R LF + 1 wZ ---------------------------------------------------------- = -------------------s-+1 1 - + 1 --------s C LF1 R LF - ------- w P1 R LF 14 of 18 GENNUM CORPORATION 522 - 75 - 05 This causes lift in the transfer function given by: 2.9.4 SPICE Simulations More detailed analysis of the GS9025A PLL can be done using SPICE. A SPICE model of the PLL is shown below: w P1 1 20 LOG ---------- = 20 LOG --------------------wZ wZ 1 - ----------w BW PHII G1 IN+ To keep peaking to less than 0.05dB: V1 E1 2 K IN- Ns RLF 2.9.3 Selection of Loop Filter Components 1 Based on the above analysis, the loop filter components should be selected for a given PLL bandwidth, 3dB, as follows: CLF1 Fig. 25 SPICE Model of the PLL 2N L = -------------I CP K where: ICP is the charge pump current and is a function of the RVCO resistor and is obtained from Figure 24. K = 90MHz/V for VCO frequencies corresponding to the L curve. K = 140MHz/V for VCO frequencies corresponding to the H curve. N is the divider modulus (L, H and N can be obtained from Table 2 or Table 3) 2. Choose RLF = 2(3.14)3dB(0.78)L 3. Choose CLF1 = 174L/(RLF)2 4. Choose CLF2 = L/4(RLF)2 CHARGE PUMP CURRENT (A) 400 350 300 250 200 150 100 50 0 200 CLF2 NOTE: PHII, PHIO, LF, and 1 are node names in the SPICE netlist. 1. Calculate 0 R2 400 600 800 1000 1200 1400 1600 1800 The model consists of a voltage controlled current source (G1), the loop filter components (RLF, CLF1, and CLF2), a voltage controlled voltage source (E1), and a voltage source (V1). R2 is necessary to create a DC path to ground for Node 1. V1 is used to generate the input phase waveform. G1 compares the input and output phase waveforms and generates the charge pump current, CP. The loop filter components integrate the charge pump current to establish the loop filter voltage. E1 creates the output phase waveform (PHIO) by multiplying the loop filter voltage by the value of the Laplace transform (2K/Ns). The net list for the model is given below. The .PARAM statements are used to set values for CP, K, N, and D. CP is determined by the RVCO resistor and is obtained from Figure 24. SPICE NETLIST * GS9025A PLL Model .PARAM ICP = 165E-6 KF= 90E+6 .PARAM N = 1 D = 0.5 .PARAM PI = 3.14 .IC V(Phio) = 0 .ac dec 30 1k 10meg RLF 1 LF 1000 CLF1 1 0 15n CLF2 0 LF 15p E_LAPLACE1 Phio 0 LAPLACE {V(LF)} {(2*PI*KF)/(N*s)} G1 0 LF VALUE{D * ICP/(2*pi)*V(Phii, Phio)} V1 2 0 DC 0V AC 1V R2 0 1 1g .END RVCO () Fig. 24 RVCO vs. Charge Pump Current 15 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A wZ < 0.0057wBW PHIO LF 3. I/O DESCRIPTION RSOURCE ZO DDI 3.1 High Speed Analog Inputs (SDI/SDI) SDI/SDI are high impedance inputs differential or single-ended input drive. which accept 113 10nF SDI 75 ZO Figure 29 shows the recommended interface when the GS9025A digital inputs are driven single-endedly. In this case, the input must be AC-coupled and a matching resistor (Zo) must be used. GS9025 SDI DDI ZO GS9025 DDI Fig. 26 3.2 High Speed Digital Inputs (DDI/DDI) Fig. 29 DDI/DDI are high impedance inputs which accept differential or single-ended input drive. Two conditions must be observed when interfacing to these inputs: 1. Input signal amplitudes are between 200 and 2000mV. When the DDI and the DDI inputs are not used, saturate one input of the differential amplifier for improved noise immunity. To saturate, connect either pins 44 and 1 or pins 2 and 3 to VCC. Leave the other pair floating. 2. The common mode input voltage range is as specified in the DC Characteristics table. 3.3 High Speed Outputs (SDO/SDO and SCO/SCO) Commonly used interface examples are shown in Figures 27 to 29. SDO/SDO and SCO/SCO are current mode outputs that require external pullup resistors (see Figure 30). To calculate the output sink current use the following relationship: Figure 27 illustrates the simplest interface to the GS9025A digital inputs. In this example, the driving device generates the PECL level signals (800mV amplitudes) having a common mode input range between 0.4V and 4.6V. This scheme is recommended when the trace lengths are less than 1in. The value of the resistors depends on the output driver circuitry. Output Sink Current = Output Signal Swing / Pullup Resistor A diode can be placed between Vcc and the pullup resistors to reduce the common mode voltage by approximately 0.7 volts. When the output traces are longer than 1in, controlled impedance traces should be used. The pullup resistors should be placed at the end of the output traces as they terminate the trace in its characteristic impedance (75). VCC DDI GS9025 DDI 75 75 75 75 SDO SDO GS9025 SCO SCO Fig. 27 When trace lengths become greater than 1in, controlled impedance traces should be used. The recommended interface is shown in Figure 29. In this case, a parallel resistor (RLOAD) is placed near the GS9025A inputs to terminate the controlled impedance trace. The value of RLOAD should be twice the value of the characteristic impedance of the trace. In addition, place series resistors (RSOURCE) near the driving chip to serve as source terminations. They should be equal to the value of the trace impedance. Assuming 800mV output swings at the driver, RLOAD = 100, RSOURCE = 50 and ZO = 50. VCC Fig. 30 High Speed Outputs with External Pullups 4. OPTIMIZING GS9025A PERFORMANCE For optimal device performance, implement loop filter component values for the GS9025A as shown in Table 5. TABLE 5: Recommended Loop Filter Component Values COMPONENT RLF CLF1 CLF2 GS9025 1k 15nF 5.6pF GS9025A 1.8k 15nF 3.3pF 16 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A 10nF GS9025 DDI Fig. 28 Figure 26 shows the recommended interface when a singleended serial digital signal is used. 75 RLOAD RSOURCE TYPICAL APPLICATION CIRCUIT VCC VCC VCC VCC 4.7n 10k VCC VCC 36 35 OEM_TEST SMPTE A/D SSI/CD LOCK COSC VEE CLK_EN VCC 31 4 VCC VEE 30 5 VEE SCO 29 6 SDI SCO 28 7 SDI VEE 27 AUTO/MAN 26 VCC 10n 8 GS9025A TOP VIEW VCC 23 12 13 14 15 16 17 18 100p VCC 1.8k 15n 19 VCC SS2 CBG AGC- RVCO 11 RVCO_RTN 24 VEE SS1 LF- CD_ADJ LFS 10 LF+ 25 VEE SS0 VCC VEE AGC+ 9 All resistors in ohms, all capacitors in microfarads, unless otherwise stated. Power supply decoupling capacitors are not shown. 34 VEE 37 VCC 20 21 22 4 x 75 see Note 2 To GS9020 VCC } To LED Driver (optional) VCC 365 (1%) 0.1 0.1 see Note 3 3.3p NOTES 1. It is recommended that the DDI/DDI inputs are not driven when the SDI/SDI inputs are being used. This minimizes crosstalk between the DDI/DDI and SDI/SDI inputs and maximizes performance. 2. These resistors are not needed if the internal pull-up resistors on the GS9020 are used. 3. It is recommended that for new designs VCO components should be returned to the RVCO_RTN pin for improved ground bounce immunity. If replacing GS9025 with GS9025A connection to ground can be maintained. TABLE 6: RVCO = 365, H = 540MHz, L = 360MHz SMPTE SS[2:0] DATA RATE (Mb/s) LOOP BANDWIDTH (MHz) 1 000 143 1.2 1 001 177 1.9 1 010 270 3.0 1 011 360 4.5 1 100 540 6.0 17 of 18 GENNUM CORPORATION 522 - 75 - 05 GS9025A 38 SDO 3 100k Pot (Optional) 39 VCC_75 VCC VCC 40 32 DDI 75 10n VCC 41 SDO 2 37.5 42 33 DDI 75 75 43 VEE 1 From GS9024 see Note 1 44 VCC_75 VCC PACKAGE DIMENSIONS 13.20 0.25 10.00 0.10 GS9025A 13.20 0.25 10.00 0.10 PIN 1 0.80 BSC 0.45 MAX 0.30 MIN 5 to 16 0.20 MIN 0 MIN 2.20 MAX 1.85 MIN 7 MAX 0 MIN 2.55 MAX 5 to 16 0.23 MAX. 0.35 MAX 0.15 MIN 0.3 MAX. RADIUS 0.88 NOM. 0.13 MIN. RADIUS 1.60 REF All dimensions in millimetres 44 pin MQFP REVISION NOTES: Corrected input high level for A/D pin. For latest product information, visit www.gennum.com DOCUMENT IDENTIFICATION CAUTION DATA SHEET The product is in production. Gennum reserves the right to make changes at any time to improve reliability, function or design, in order to provide the best product possible. GENNUM CORPORATION MAILING ADDRESS: P.O. Box 489, Stn. A, Burlington, Ontario, Canada L7R 3Y3 Tel. +1 (905) 632-2996 Fax. +1 (905) 632-5946 SHIPPING ADDRESS: 970 Fraser Drive, Burlington, Ontario, Canada L7L 5P5 ELECTROSTATIC SENSITIVE DEVICES DO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A STATIC-FREE WORKSTATION GENNUM JAPAN CORPORATION Shinjuku Green Tower Building 27F, 6-14-1, Nishi Shinjuku, Shinjuku-ku, Tokyo, 160-0023 Japan Tel. +81 (03) 3349-5501, Fax. +81 (03) 3349-5505 GENNUM UK LIMITED 25 Long Garden Walk, Farnham, Surrey, England GU9 7HX Tel. +44 (0)1252 747 000 Fax +44 (0)1252 726 523 Gennum Corporation assumes no responsibility for the use of any circuits described herein and makes no representations that they are free from patent infringement. (c) Copyright June 2000 Gennum Corporation. All rights reserved. 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