GS1522-CQRE3

HD-LINX ™ GS1522 HDTV Serial Digital Serializer DATA SHEET FEATURES • SMPTE 292M compliant • 20:1 parallel to serial conversion • NRZ(I) encoder & SMPTE scrambler with selectable bypass • NRZ to NRZ(I) serial data conversion • 1.485Gb/s and 1.485/1.001Gb/s operation • lock detect output • selectable DUAL or QUAD 75Ω cable driver outputs • 8 bit or 10 bit input data support • 20 bit wide inputs • Pb-free and Green • 3.3V and 5V CMOS/TTL compatible inputs • single +5.0V power supply APPLICATIONS SMPTE 292M Serial Digital Interfaces for Video Cameras, Camcorders, VTRs, Signal Generators, Portable Equipment, and NLEs. • 1.485Gb/s or 1.485/1.001Gb/s operation This device requires a single 5V supply and typically consumes less than 1000mW of power while driving two 75Ω cables. The GS1522 uses the GO1515 external VCO connected to the internal PLL circuitry to achieve ultra low noise PLL performance. ORDERING INFORMATION PART NUMBER GS1522-CQR GS1522-CQRE3 PACKAGE 128 pin MQFP 128 pin MQFP TEMPERATURE 0°C to 70°C 0°C to 70°C Pb-FREE AND GREEN No Yes DESCRIPTION The GS1522 is a monolithic bipolar integrated circuit designed to serialize SMPTE 274M and SMPTE 260M bit parallel digital signals. This device performs the following functions: • • • • • Sync word mapping for 8-bit/10-bit operation. Parallel to Serial conversion of Luma & Chroma data Interleaving of Luma and Chroma data 9 4 Data Scrambling (using the X +X +1 algorithm) GS1522 Conversion of NRZ to NRZI serial data (using the (X+1) algorithm) Selectable DUAL or QUAD 75Ω Cable Driver outputs Lock Detect Output • • RESET BYPASS RSET0 SYNC_DETECT _DISABLE 20 DATA_IN[19:0] 20 INPUT LATCH SYNC DETECT SMPTE SCRAMBLER INTERLEAVER O/P0 RESET BYPASS SCLK PARALLEL TO SERIAL CONVERTER NRZ TO NRZI O/P1 SDO1 PLOAD MUTE RSET1 SDO1_EN PLL_LOCK SDO1 SDO0 SDO0 PCLK_IN PLL GO1515 FUNCTIONAL BLOCK DIAGRAM Revision Date: June 2004 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 Document No. 522 - 26 - 03 ABSOLUTE MAXIMUM RATINGS PARAMETER Supply Voltage (VS) Input Voltage Range (any input) DC Input Current (any input) Power Dissipation (VCC = 5.25V) Input ESD Voltage Die Temperature Operating Temperature Range Storage Temperature Range Lead Temperature (soldering 10 seconds) VALUE 5.5V VEE – 0.5 < VIN < VCC+ 0.5 TBD GS1522 TBD TBD 125°C 0°C ≤ TA ≤ 70°C -40°C ≤ TS ≤ 150°C 260°C AC ELECTRICAL CHARACTERISTICS VCC = 5V, VEE = 0V, TA = 0°C to 70°C unless otherwise specified. PARAMETER Serial data bit rate Digital Serial Data Outputs CONDITIONS SMPTE 292M Differential outputs SYMBOL BRSDO VSDO MIN 750 TYP 1.485 800 MAX 850 UNITS Gb/s mV p-p NOTES 1.485/1.001Gb/s also With 52.3Ω 1% RSET Resistor Rise/Fall times, 20-80% Overshoot Output Return Loss @ 1.485GHz tr, tf - 150 0 17 270 7 - ps % dB As per SMPTE292M (5MHz to clock frequency), using Gennum Evaluation Board, recommended layout and components. ORL 15 Lock Time Typical Loop Bandwidth Worst case ≤ 0.1dB peaking, 1.485Gb/s Pseudo-random PRBS (2 -1) (200kHz LBW) Pathological PRBS (2 -1) (200kHz LBW) Pseudo-random (1.5 MHz LBW) Pathological (1.5 MHz LBW) 23 23 tLOCK - 200 0.200 250 1.5 ms MHz Intrinsic Jitter tIJR - - 100 ps p-p tIJP - - 100 ps p-p tIJR - - 100 ps p-p tIJP - - 100 ps p-p 2 of 20 GENNUM CORPORATION 522 - 26 - 03 AC ELECTRICAL CHARACTERISTICS - PARALLEL TO SERIAL STAGE VDD = 5V, TA = 0°C to 70°C unless otherwise specified. PARAMETER Input Voltage Levels CONDITIONS SYMBOL VIL VIH MIN - TYP - MAX 0.8 UNITS V NOTES For compatibility with TTL voltage levels For compatibility with TTL voltage levels 2.0 - - V GS1522 Input Capacitance Output Voltage Levels CIN VOL VOH - 1 - 2 0.4 pF V For compatibility with TTL voltage levels For compatibility with TTL voltage levels 74.25/1.001MHz also 2.4 - - V Parallel Input Clock Frequency Input Clock Pulse Width LOW Input Clock Pulse Width HIGH Input Clock Rise/Fall time Input Clock Rise/Fall time Matching Input Setup Time Input Hold Time PCLK_IN tPWL tPWH tr, tf trfm tSU tIH - 74.25 - MHz 5 - - ns 5 - - ns - 500 200 1000 - ps ps 20% to 80% 1.0 0 - - ns ns DC ELECTRICAL CHARACTERISTICS VCC = 5V, VEE = 0V, TA = 0°C to 70°C unless otherwise specified. PARAMETER Positive Supply Voltage Power (system power) CONDITIONS Operating Range VCC = 5.00V, T=25°C VCC = 5.00V, T=25°C SYMBOL VCC PD PD MIN 4.75 - TYP 5.00 950 1170 234 - MAX 5.25 300 240 UNITS V mW mW mA mA mA NOTES (Driving two 75Ω outputs) (Driving four 75Ω outputs) (Driving four 75Ω outputs) (Driving four 75Ω outputs) (Driving two 75Ω outputs) Supply Current VCC = 5.25V, T=70°C VCC = 5.00V, T=25°C SDO1 disabled VCC = 5.25V, 70°C SDO1 disabled VCC = 5.0V, 25°C - 190 - mA (Driving two 75Ω outputs) 3 of 20 GENNUM CORPORATION 522 - 26 - 03 PIN CONNECTIONS OSC_VEE A0 NC NC NC VEE2 RSET0 VCC2 NC SDO0 SDO_NC SDO0 NC NC NC SDO1 SDO_NC SDO1 NC VCC2 RSET1 NC NC NC NC NC 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 GS1522 NC NC NC NC NC NC NC NC NC VCO VCO PD_VEE PDSUB_VEE IJI PD_VCC NC NC LFS NC LFS PLCAP DM PLCAP DFT_VEE LFA_VEE LFA LBCONT LFA_VCC NC VCC3 VEE3 SYNC_DETECT_DISABLE NC NC NC NC NC NC 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 GS1522 TOP VIEW 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 NC NC NC NC NC NC NC SDO1_EN VEE2 VEE2 VEE2 VEE2 VEE2 VCC2 VCC2 VCC2 VCC2 VCC2 NC NC VEE2 RESET BYPASS PLL_LOCK NC XDIV20 NC NC BUF_VEE NC NC NC NC NC NC NC PCLK_IN VEE3 NOTE: No Heat Sink Required DATA_IN[19] DATA_IN[18] DATA_IN[17] DATA_IN[16] DATA_IN[15] NC NC DATA_IN[14] DATA_IN[13] DATA_IN[12] DATA_IN[11] DATA_IN[10] DATA_IN[9] NC NC DATA_IN[8] DATA_IN[7] NC NC DATA_IN[6] DATA_IN[5] DATA_IN[4] DATA_IN[3] DATA_IN[2] DATA_IN[1] DATA_IN[0] 4 of 20 GENNUM CORPORATION 522 - 26 - 03 PIN DESCRIPTIONS NUMBER 1, 95 SYMBOL VEE3 PCLK_IN NC LEVEL Power TYPE Input DESCRIPTION Negative Supply. Most negative power supply connection, for input stage. Parallel Data Clock. 74.25 or 74.25/1.001MHz No Connect. These pins are not used internally. These pins should be floating. 2 3, 4, 5, 6, 7, 8, 9, 11, 12, 14, 19, 20, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43,46, 50, 51, 52, 56, 60, 61, 62, 65, 66, 67, 68, 69, 70, 71, 72, 73, 80, 81, 83, 93, 97, 98, 99, 100, 101, 102, 108, 109, 116, 117, 120, 121 10 TTL Input GS1522 BUF_VEE Power TEST Negative Supply/Test Pin. Most negative power supply connection. For buffer for oscillator/divider for test purposes only. Leave floating for normal operation. Test Pin. Test block output. Leave floating for normal operation. Status Signal Output. Indicates when the GS1522 is phase locked to the incoming PCLK_IN clock signal. LOGIC HIGH indicates PLL is in Lock. LOGIC LOW indicates PLL is out of Lock. Control Signal Input. Used to bypass the scrambling function if data is already scrambled by GS1501 or if non-SMPTE encoded data stream such as 8b/10b is to be transmitted. When BYPASS is LOW, the SMPTE scrambler and NRZ(I) encoder are enabled. When BYPASS is HIGH, the SMPTE scrambler and NRZ(I) encoder are bypassed. Control Signal Input. Used to reset the SMPTE scrambler. For logic HIGH; Resets the SMPTE scrambler and NRZ(I) encoder. For logic LOW: normal SMPTE scrambler and NRZ(I) encoder operation. Negative Supply. Most negative power supply connection. For Cable Driver outputs and all other digital circuitry excluding input stage and PLL stage. Positive Supply. Most positive power supply connection. For Cable Driver outputs and all other digital circuitry excluding input stage and PLL stage. Control Signal Input. Used to enable or disable the second serial data output stage. This signal must be tied to GND to enable this stage. Do not connect to a logic LOW. Control Signal Input. External resistor is used to set the data output amplitude for SDO1 and SDO1. Use a ±1% resistor. Serial Data Output Signal. Current mode serial data output #1. Use 75Ω ±1% pull up resistors to VCC2. 13 15 XDIV20 PLL_LOCK TTL TTL TEST Output 16 BYPASS TTL Input 17 RESET TTL Input 18, 26, 27, 28, 29, 30, 59 VEE2 Power Input 21, 22, 23, 24, 25, 45, 57 VCC2 Power Input 31 SDO1_EN Power Input 44 RSET1 SDO1, SDO1 Analog Input 47, 49 Output 48, 54 53, 55 SDO_NC SDO0, SDO0 Analog Output No Connect. Not used internally. This pin must be left floating. Serial Data Output Signal. Current mode serial data output #0. Use 75Ω ± 1% pull up resistors to VCC2. Control Signal Input. External resistor is used to set the data output amplitude for SDO0 and SDO0. Use a ±1% resistor. 58 RSET0 Analog Input 5 of 20 GENNUM CORPORATION 522 - 26 - 03 PIN DESCRIPTIONS (Continued) NUMBER 63 SYMBOL A0 LEVEL TTL TYPE TEST DESCRIPTION Test Signal. Used for manufacturing test purposes only. This pin must be tied low for normal operation. Negative Supply. Ground for ring oscillator. This pin must be floating for normal operation. 64 OSC_VEE VCO Power Input GS1522 74 Analog Input Control Signal Input. Input pin is AC coupled to ground using a 50Ω transmission line. Control Signal Input. Voltage controlled oscillator input. This pin is connected to the output pin of the GO1515 VCO. This pin must be connected to the GO1515 VCO output pin via a 50Ω transmission line. Negative Supply. Most negative power supply connection. For phase detector stage. Guard Ring. Ground guard ring connection to isolate phase detector in PLL stage. Status Signal Output. Indicates the amount of excessive jitter on the incoming SDI and SDI input. Positive Supply. Most positive power supply connection. For phase detector stage. Loop Filter Connections. Control Signal Input. Phase lock detect time constant capacitor. Test Signal. Used for manufacturing test only. This pin must be left floating in normal operation. 75 VCO Analog Input 76 PD_VEE PDSUB_VEE IJI Power Input 77 Power Input 78 Analog Output 79 PD_VCC LFS, LFS PLCAP, PLCAP DM Power Input 82, 84 85, 87 86 Analog Analog Input Input 88 DFT_VEE Power Input Most Negative Power Supply Connection . Enables the jitter demodulator functionality. This pin should be connected to ground. If left floating, the DM function is disabled resulting in a current saving of 340µA. Negative Supply. Most negative power supply connection. For loop filter stage. Control Signal Output. Control voltage for GO1515 VCO. Control Signal Input. Used to provide electronic control of Loop Bandwidth. Positive Supply. Most positive power supply connection. For loop filter stage. Positive Supply. Most positive power supply connection. For input stage. Control Signal Input. Used to disable the sync detection function. Logic HIGH disables sync detection. Logic LOW: 000-003 is mapped into 000 and 3FC-3FF is mapped into 3FF for 8-bit operation. Input Data Bus. The device receives a 20 bits data stream running at 74.25 or 74.25/1.001 MHz from the GS1501 HDTV Formatter or GS1511 HDTV Formatter. Input data can be in SMPTE292M scrambled or unscrambled format. DATA_IN[19] is the MSB (pin 103). DATA_IN[0] is the LSB (pin 128). 89 LFA_VEE LFA LBCONT Power Input 90 91 Analog Analog Output Input 92 LFA_VCC VCC3 SYNC_DETECT_DISABLE Power Input 94 Power Input 96 TTL Input 103, 104, 105, 106, 107, 110, 111, 112, 113, 114, 115, 118, 119, 122, 123, 124, 125, 126, 127, 128 DATA_IN[19:0] TTL Input 6 of 20 GENNUM CORPORATION 522 - 26 - 03 INPUT/OUTPUT CIRCUITS PD_VCC LFA_VCC 5k 5k 500 GS1522 LFA 10k 10k 40 40 31p PD_VEE VCO 5mA 100µA LFA_VEE 50 VCO Fig. 1 VCO/VCO Input Circuit Fig. 4 LFA Circuit PD_VCC 25k 10k DM 10k LFA_VCC LFS 85µA DFT_VEE 400µA LFA_VEE Fig. 2 DM Output Circuit Fig. 5 LFS Output Circuit PD_VCC 20k PLCAP 10k PLCAP LFS 10k 5k LFA_VCC 100µA 100µA 100µA PD_VEE 100µA 100µA LFA_VEE Fig. 3 PLCAP/PLCAP Output Circuit Fig. 6 LFS Input Circuit 7 of 20 GENNUM CORPORATION 522 - 26 - 03 VCC3 2k PD_VCC 10k 10k PLL_LOCK D0 - D19, SYNC_DETECT_DISABLE BIAS GS1522 PD_VEE VEE3 All on-chip resistors have ±20% tolerance at room temperature. Fig. 7 PLL_LOCK Output Circuit Fig. 10 Data Input and SYNC_DETECT_DISABLE Circuit VCC 1k PD_VCC 10k IJI PCLK_IN 5k VCC 30k A PD_VEE VEE 5k BIAS Fig. 8 IJI Output Circuit Fig. 11 PCLK_IN Circuit VCC 20k SDO SDO BIAS RESET 10k + CD_VEE RSET VEE Fig. 9 SDO/SDO Output Circuit Fig. 12 RESET Circuit 8 of 20 GENNUM CORPORATION 522 - 26 - 03 VCC 5k 5k BIAS GS1522 BYPASS 10k VEE Fig. 13 BYPASS Circuit DETAILED DESCRIPTION The GS1522 HDTV Serializer is a bipolar integrated circuit used to convert parallel data into serial format according to the SMPTE 292M standard. The device encodes both 8-bit and 10-bit TTL compatible parallel signals producing a serial data rate of 1.485Gb/s. The device operates from a single 5V supply and is available in a 128 pin MQFP package. The functional blocks within the device include the input latches, interleaver, sync detector, parallel to serial converter, SMPTE scrambler, NRZ to NRZ(I) converter, two internal cable drivers, PLL for 20x parallel clock multiplication and lock detect circuitry. 1. INPUT LATCHES ones respectively. This allows the system to be compatible with 8-bit and 10-bit data. For non-SMPTE standard parallel data, a logic input Sync Detect Disable pin (96) is available to disable this feature. 4. SCRAMBLER The scrambler is a linear feedback shift register used to pseudo-randomize the incoming data according to the fixed polynomial (X9+X4+1). This minimizes the DC component in the output serial stream. The NRZ to NRZ(I) converter uses another polynomial (X+1) to convert a long sequence of ones to a series of transitions, minimizing polarity effects. To disable these features, set the BYPASS pin (16) HIGH. 5. SLEW PHASE LOCK LOOP (S-PLL) The 20-bit input latch accepts either 3.3V or 5V CMOS/TTL inputs. The input data is buffered and then latched on the rising edge of the PCLK_IN pin (2). The output of the latch is a differential signal for increased noise immunity. Further noise isolation is provided by the use of separate power supplies. 2. INTERLEAVER The interleaver takes the 20-bit wide parallel data (Y and C) and reduces it internally to a 10-bit wide word by alternating the Y and C data words according to SMPTE 292M, section 6.1. 3. SYNC DETECTOR An innovative feature of the GS1522 is the slew phase lock loop (S-PLL). When a step phase change is applied to the PLL, the output phase gains constant rate of change with respect to time. This behavior is termed slew. Figure 14 shows an example of input and output phase variation over time for slew and linear (conventional) PLLs. Since the slewing is a non-linear behavior, the small signal analysis cannot be done in the same way as it is for the standard PLL. However, it is still possible to plot input jitter transfer characteristics at a constant input jitter modulation. Slew PLLs offer several advantages such as excellent noise immunity. The loop corrects small input jitter modulation immediately because of the infinite bandwidth. Therefore, the small signal noise of the VCO is cancelled immediately. The GS1522 uses a very clean, external VCO called the GO1515 (refer to the GO1515 Data Sheet for details). Another advantage is the bi-level digital phase detector which provides constant loop bandwidth that is predominantly independent of the data transition density. The loop bandwidth of a conventional tri-stable charge The sync detector looks for the reserved words 000-003 and 3FC-3FF in 10-bit hexadecimal, or 00-03 and FC-FF in 8-bit hexadecimal used in the TRS-ID sync word. When there is an occurrence of all zeros or all ones in the eight higher order bits, the lower two bits are forced to zeros or 9 of 20 GENNUM CORPORATION 522 - 26 - 03 pump drops with reducing data transitions. During pathological signals, the data transition density reduces from 0.5 to 0.05 but the slew PLL’s performance does not change significantly. Because most of the PLL circuitry is digital, it is very robust as digital systems are generally more robust than their analog counterparts. Signals which represent the internal functionality, like DM (86), can be generated without adding additional artifacts. Thus, system debugging is possible with these features. The complete slew PLL is made up of several blocks including the phase detector, the charge pump and an external Voltage Controlled Oscillator (VCO) which are described in the following sections. Phase lock loop frequency synthesis and lock logic are also described. PHASE ALIGNMENT EDGE RE-TIMING EDGE IN-PHASE CLOCK 0.8UI INPUT CLOCK WITH JITTER GS1522 OUTPUT DATA Fig. 15 Phase Detector Characteristics 0.2 PHASE (UI) INPUT 0.1 OUTPUT During pathological signals, the amount of jitter that the phase detector will add can be calculated. By choosing the proper loop bandwidth, the amount of phase detector induced jitter can also be limited. Typically, for a 1.41MHz loop bandwidth at 0.2UI input jitter modulation, the phase detector induced jitter is about 0.015UIp-p. This is not significant, even in the presence of pathological signals. 5.2. Charge Pump 0.0 SLEW PLL RESPONSE The charge pump in a slew PLL is different from the charge pump in a linear PLL. There are two main functions of the charge pump: to hold the frequency information of the input data and to provide a binary control voltage to the VCO. The charge pump holds the frequency information of the input data. This information is held by CCP1 which is connected between LFS (82) and LFS (84). CCP2, which is connected between LFS and LFA_VEE (89), is used to remove common mode noise. Both CCP1 and CCP2 should have the same value. The charge pump provides a binary control voltage to the VCO depending upon the phase detector output. The output pin LFA (90) controls the VCO. Internally there is a 500Ω pull-up resistor which is driven with a 100µA current called ΙP. Another analog current ΙF, with 5mA maximum drive proportional to the voltage across the CCP1, is applied at the same node. The voltage at the LFA node is VLFA_VCC - 500(ΙP+ΙF) at any time. Because of the integrator, ΙF changes very slowly whereas ΙP can change at the positive edge of the data transition as often as a clock period. In the locked position, the average voltage at LFA (VLFA_VCC – 500(ΙP/2+ΙF) is such that VCO generates frequency ƒ equal to the data rate clock frequency. Since ΙP is changing all the time between 0A and 100µA, there are two levels generated at the LFA output. 5.3. VCO 0.2 PHASE (UI) INPUT 0.1 OUTPUT 0.0 LINEAR (CONVENTIONAL) PLL RESPONSE Fig. 14 PLL Characteristics 5.1. Phase Detector The phase detector portion of the slew PLL used in the GS1522 is a bi-level digital phase detector. It indicates whether the data transition occurred before or after with respect to the falling edge of the internal clock. When the phase detector is locked, the data transition edges are aligned to the falling edge of the clock. The input data is then sampled by the rising edge of the clock, as shown in Figure 15. In this manner, the allowed input jitter is 1UI p-p in an ideal situation. However, due to setup and hold time, the GS1522 typically achieves 0.8UI p-p input jitter tolerance without causing any errors in this block. When the signal is locked to the internal clock, the control output from the phase detector is refreshed at the transition of each rising edge of the data input. During this time, the phase of the clock drifts in one direction. The GO1515 is an external hybrid VCO which has a centre frequency of 1.485GHz. It is guaranteed to provide 1.485/1.001GHz within the control voltage (3.1V – 4.65V) of the GS1522 over process, power supply and temperature. 10 of 20 GENNUM CORPORATION 522 - 26 - 03 The GO1515 is a very clean frequency source and, because of the internal high Q resonator, is an order of magnitude more immune to external noise as compared to on-chip VCOs. The VCO gain, Kƒ, is nominally 16MHz/V. The control voltage around the average LFA voltage is 500 x ΙP/2. This produces two frequencies off from the centre by ƒ = Kƒ x 500 x ΙP/2. 5.4. Phase Lock Loop Frequency Synthesis 6. LBCONT The LBCONT pin (91) is used to adjust the loop bandwidth by externally changing the internal charge pump current. For maximum loop bandwidth, connect LBCONT to the most positive power supply. For medium loop bandwidth, connect LBCONT through a pull-up resistor (RPULL-UP). For low loop bandwidth, leave LBCONT floating. The formula below shows the change in the loop bandwidth using RPULL-UP. ( 25k Ω + R PULL – UP ) LBW = LBW NOMINAL × ----------------------------------------------------( 5k Ω + R PULL – UP ) where LBWNOMINAL is the loop bandwidth when LBCONT is left floating. 7. LOOP BANDWIDTH OPTIMIZATION GS1522 The GS1522 requires the HDTV parallel clock (74.25 or 74.25/1.001MHz) to synthesize a serial clock which is 20 times the parallel clock frequency (1.485MHz) using a phase locked loop (PLL). This serial clock is then used to strobe the output serial data. Figure 16 illustrates this operation. The VCO is normally free-running at a frequency close to the serial data rate. A divide-by-20 circuit converts the free running serial clock frequency to approximately that of the parallel clock. Within the phase detector, the dividedby-20 serial clock is then compared to the reference parallel clock from the PCLK_IN pin (2). Based on the leading or lagging alignment of the divided clock to the input reference clock, the serial data output is synchronized to the incoming parallel clock. GS1522 PLL Since the feed back loop has only digital circuits, the small signal analysis does not apply to the system. The effective loop bandwidth scales with the amount of input jitter modulation index. The following table summarizes the relationship between input jitter modulation index and bandwidth when RCP1 and CCP3 are not used. See the Typical Application Circuit for the location of RCP1 and CCP3 . TABLE 1: Relationship Between Input Jitter Modulation Index and Bandwidth INPUT JITTER MODULATION INDEX 0.05 BW JITTER FACTOR (jitter modulation x BW) 282.9kHzUI 282.9kHzUI 282.9kHzUI 282.9kHzUI PCLK_IN PHASE DETECTOR BANDWIDTH 5.657MHz 2.828MHz 1.414MHz 565.7kHz DIVIDE-BY-20 GO1515 VCO 0.10 0.20 0.50 Fig. 16 Phase Lock Loop Frequency Synthesis 5.5. Lock Logic Logic is used to produce the PLL_LOCK (15) signal which is based on the LFS signal and phase lock signal. When there is no data input, the integrator charges and eventually saturates at either end. By sensing the saturation of the integrator, it is determined that no data is present. If there is no data present or phase lock is low, the lock signal is made LOW. Logic signals are used to acquire the frequency by sweeping the integrator. Injecting a current into the summing node of the integrator achieves the sweep. The sweep is disabled when phase lock is asserted. The direction of the sweep is changed when LFS saturates at either end. The product of the input jitter modulation (IJM) and the bandwidth (BW) is a constant. In this case, it is 282.9kHzUI. The loop bandwidth automatically reduces with increasing input jitter, which results in the cleanest signal possible. Using a series combination of RCP1 and CCP3 in parallel to an on-chip resistor (see the Typical Application Circuit) can reduce the loop bandwidth of the GS1522. The parallel combination of the resistors is directly proportional to the bandwidth factor. For example, the on-chip 500Ω resistor yields 282.9kHzUI. If a 50Ω resistor is connected in parallel, the effective resistance will be (50:500) 45.45Ω. This resistance yields a bandwidth factor of [282.9 x (45.45/500)] = 25.72kHzUI The capacitance CCP3 in series with the RCP1 should be chosen such that the RC factor is 50µF. For example, RCP1=50Ω requires CCP3=1µF. 11 of 20 GENNUM CORPORATION 522 - 26 - 03 The synchronous lock time increases with reduced bandwidth. Nominal synchronous lock time is equal to [ 0.25 × 2 /Bandwidth factor]. That is, the default bandwidth factor (282.9kHzUI) yields 1.25µs. For 25.72kHzUI, the synchronous lock time is 0.3535/25.72k = 13.75µs. Since the CCP1, CCP2 and CCP3 are also charged, it is measured to be about 11µs which is slightly less than the calculated value of 13.75µs. The Kƒ of the VCO (GO1515) is specified with a minimum of 11MHz/V and maximum of 21MHz/V which is about ±32% variation. The 500 x ΙP/2 varies about ±10%. The resulting bandwidth factor varies by approximately ±45% when no RCP1 and CCP3 are used. ΙP by itself may vary by 30% so the variability for lower bandwidths increases by an additional ±30%. The CCP1 and CCP2 capacitors should be changed with reduced bandwidths. Smaller CCP1 and CCP2 capacitors result in jitter peaking, lower stability, less probability of locking but at the same time lowering the asynchronous lock time. Therefore, there is a trade-off between asynchronous lock time and jitter peaking/stability. These capacitors should be as large as possible for the allowable lock time and should be no smaller than the allowed value. With the recommended values, jitter peaking of less than 0.1dB has been measured at the lower loop bandwidth as shown in Figure 17. At higher loop bandwidths, it is difficult to measure jitter peaking because of the limitation of the measurement unit. It has been determined that for 282.9kHzUI, the minimum value of the CCP1 and CCP2 capacitors should be no less than 0.5µF. For added margin, 1µF capacitors are recommended. The 1µF value gives a lock time of about 60ms in one attempt. For 25.72kHzUI, these capacitors should be no less than 5.6µF. This results in 340ms of lock time. If necessary, extra margin can be built by increasing these capacitors at the expense of a longer asynchronous lock time. Bandwidths lower than 129kHz at 0.2UI modulation have not been characterized, but it is believed that the bandwidth could be further lowered (contact Gennum’s Video Products Applications for further details). Since a lower bandwidth has less correction for noise, extra care should be taken to minimize board noise. Figures 18 and 19 show the two measured loop bandwidths at these two settings. Table 2 summarizes the two bandwidth settings. GS1522 Fig. 18 Typical Jitter Transfer Curve at Setting A in Table 2 Fig. 17 Typical Jitter Peaking However, because relatively larger CCP1 and CCP2 capacitors can be used, over-damping of the loop response occurs. An accurate jitter peaking measurement of 0.1dB for the GS1522 requires the modulation source to have a constant amount of jitter modulation index (within 0.1dB or 1.2%) over the frequency range beyond the loop bandwidth. Fig. 19 Typical Jitter Transfer Curve at Setting B in Table 2 12 of 20 GENNUM CORPORATION 522 - 26 - 03 TABLE 2: Loop Bandwidth Setting Options BW FACTOR 282.9kHz 25.72kHz BW at 0.2 UI JITTER MODULATION INDEX 1.41MHz 129kHz RCP1 CCP3 CCP1 CCP2 ASYNCHRONOUS SYNCHRONOUS A B Open 50 Open 1.0 1.0 5.6 1.0 5.6 60ms 340ms 1.25µs 11.0µs GS1522 8. PHASE LOCK 9. INPUT JITTER INDICATOR (IJI) The phase lock circuit is used to determine the phase locked condition. It is done by generating a quadrature clock by delaying the in-phase clock by 166ps (0.25UI at 1.5GHz) with the tolerance of 0.05UI. The in-phase clock is the clock whose falling edge is aligned to the data transition. When the PLL is locked, the falling edge of the inphase clock is aligned with the data edges as shown in Figure 20. The quadrature clock is in a logic HIGH state in the vicinity of input data transitions. The quadrature clock is sampled and latched by positive edges of the data transitions. The generated signal is low pass filtered with an RC network. The R is an on-chip 6.67kΩ resistor and CPL is an internal capacitor (31pF). The time constant is about 200ns. PHASE ALIGNMENT EDGE RE-TIMING EDGE This signal indicates the amount of excessive jitter which occurs beyond the quadrature clock window (greater than 0.5UI, see Figure 19). All the input data transitions occurring outside the quadrature clock window are captured and filtered by the low pass filter as mentioned in section 8, Phase Lock. The running time average of the ratio of the transitions inside the quadrature clock and outside the quadrature is available at the PLCAP/PLCAP pins (87 and 85). IJI, which is the buffered signal available at the PLCAP, is provided so that loading does not effect the filter circuit. The signal at IJI is referenced with the power supply such that the factor VIJI /V CC is a constant over process and power supply for a given input jitter modulation. The IJI signal has 10kΩ output impedance. Figure 21 shows the relationship of the IJI signal with respect to the sine wave modulated input jitter. TABLE 3: IJI Voltage as a Function of Sinusoidal Jitter IN-PHASE CLOCK P-P SINE WAVE JITTER IN UI 0.8UI IJI VOLTAGE 4.75 4.75 4.75 4.70 4.60 4.50 4.40 4.30 4.20 4.10 3.95 0.00 0.15 INPUT CLOCK WITH JITTER 0.30 0.25UI 0.39 0.45 QUADERATURE CLOCK 0.48 0.52 0.55 PLCAP SIGNAL 0.58 0.60 PLCAP SIGNAL 0.63 Fig. 20 PLL Circuit Principles If the signal is not locked, the data transition phase could be anywhere with respect to the internal clock or the quadrature clock. In this case, the normalized filtered sample of the quadrature clock is 0.5. When VCO is locked to the incoming data, data will only sample the quadrature clock when it is logic HIGH. The normalized filtered sample quadrature clock is 1.0. We chose a threshold of 0.66 to generate the phase lock signal. Because the threshold is lower than 1, it allows jitter to be greater than 0.5UI before the phase lock circuit reads it as “not phase locked”. 13 of 20 GENNUM CORPORATION 522 - 26 - 03 5.0 4.8 4.6 4.4 4.2 IJI SIGNAL (V) GS1522 4.0 3.8 3.6 0.00 0.20 0.40 0.60 0.80 INPUT JITTER (UI) Fig. 21 Input Jitter Indicator (Typical at TA = 25°C) 10. JITTER DEMODULATION (DM) Fig. 22 Jitter Demodulation Signal 11. MUTE The differential jitter demodulation (DM) signal is available at the DM pin (86). This signal is the phase correction signal of the PLL loop, which is amplified and buffered. If the input jitter is modulated, the PLL tracks the jitter if it is within loop bandwidth. To track the input jitter, the VCO has to be adjusted by the phase detector via the charge pump. Thus, the signal which controls the VCO contains the information of the input jitter modulation. The jitter demodulation signal is only valid if the input jitter is less than 0.5UIp-p. The DM signal has a 10kΩ output impedance, which can be low pass filtered with appropriate capacitors to eliminate high frequency noise. DFT_VEE (88) should be connected to GND to activate the DM signal. The DM signal can be used as a diagnostic tool. Assume there is an HDTV SDI source which contains excessive noise during the horizontal blanking because of the transient current flowing in the power supply. To discover the source of the noise, probe around the source board with a low frequency oscilloscope (Bandwidth < 20MHz) that is triggered with an appropriately filtered DM signal. The true cause of the modulation is synchronous and appears as a stationary signal with respect to the DM signal. Figure 22 shows an example of such a situation. An HDTV SDI signal is modulated with a signal causing about 0.2UI jitter (Channel 1). The GS1522 receives this signal and locks to it. Figure 22 (Channel 2) shows the DM signal. Notice the wave shape of the DM signal, which is synchronous to the modulating signal. The DM signal can also be used to compare the output jitter of the HDTV signal source. The logic controls the mute block when the PLL_LOCK (15) signal has a LOW logic state. When the mute signal is asserted, the previous state of the output is latched. 12. CABLE DRIVER The outputs of the GS1522 are complementary current mode cable driver stages. The output swing and impedance can be varied. Use Table 4 to select the RSET resistor for the desired output voltage level. Linear interpolation can be used to determine the specific value of the resistor for a given output swing at the load impedance. For linear interpolation, use either Figure 23 or the information in Table 4. Find the admittance and then, by inverting the admittance, a resistor value for the RSET can be found. The output can be used as dual 0.8V 75Ω cable drivers. It can also be used as a differential transmission line driver. In this case, the pull-up resistor should match the impedance of the transmission line because the pull-up resistor acts as the source impedance. To reduce the swing and save power, use a higher value of RSET resistor. There are HD-LINX™ products that can handle such low input swings. NOTE: For reliability, the minimum RSET resistor cannot be less than 50Ω because of higher current density. 14 of 20 GENNUM CORPORATION 522 - 26 - 03 1.0 SOURCE/END TERMINATED OUTPUT SWING (V) 0.8 0.6 75Ω 0.4 GS1522 50Ω 0.2 0.0 0.00 0.01 0.02 0.03 1/RSET (Ω) Fig. 23 Signal Swing for Various R SET Admittances When the outputs are used to differentially drive another device such as the GS1508, use 50Ω transmission lines with the smallest possible signal swing while allowing 10% variation at the output swing to select the correct RSET resistor. To drive the GS1508, the recommended RSET resistor is 150Ω. There is no need to compensate for the return-loss in this situation. The uncompensated waveform at the output is shown in Figure 24. Fig. 24 Uncompensated Output Eye Waveform Fig. 25 Compensated Output Eye Waveform NOTE: Figures 24 and 25 show the waveforms on an oscilloscope using a 75Ω to 50Ω pad. TABLE 4: RSET Values for Various Output Load Conditions ADMITTANCE (g) OF THE RSET RESISTOR (= 1/RSET RESISTOR) 0.0020 0.0067 0.0133 0.0187 0.0192 0.0200 TRANSMISSION LINE, TERMINATED AT THE END. (PULL-UP RESISTOR AT THE SOURCE = 75Ω) 0.094V 0.296V 0.569V 0.776V 0.796V 0.826V TRANSMISSION LINE, TERMINATED AT THE END. (PULL-UP RESISTOR AT THE SOURCE = 50Ω) 0.063V 0.197V 0.379V 0.517V 0.530V - RSET RESISTOR OUTPUT CURRENT 500.0Ω 150.0Ω 75.0Ω 53.6Ω 52.3Ω 49.9Ω 2.506mA 7.896mA 15.161mA 20.702mA 21.216mA 22.032mA 15 of 20 GENNUM CORPORATION 522 - 26 - 03 12. RETURN LOSS In an application where the GS1522 directly drives a cable, it is possible to achieve an output return loss (ORL) of about 17dB to 1.485GHz. PCB layout is very important. Use the EB1522 as a reference layout (see Figures 28 to 31). When designing high frequency circuits, use very small ‘0608’ surface mount components with short distances between the components. To reduce PCB parasitic capacitance, provide openings in the ground plane. For best matching, a 12nH inductor in parallel with a 75Ω resistor and a 1.5pF capacitor matches the 75Ω cable impedance. The inductor and resistor cancel the parasitic capacitance while the capacitor cancels the inductive effect of the bond wire. To verify the performance of any layout, measure the return loss by shorting the inductor with a piece of wire without the GS1522 installed. Unless the artwork is an exact copy of the recommended layout, verify every design for output return loss. Tweak the layout until a return loss of 25dB is attained while the GS1522 is not mounted and L1 is shorted. When the device is mounted, use different inductors to match the parasitic capacitance of the IC. When the correct inductor is used, maximum return loss of 5MHz to 800MHz is achievable. To increase the return loss 800MHz to 1.5GHz, use a shunt capacitor of 0.5pF to 1.5pF. The larger inductor causes slower rise/fall time. The larger shunt capacitor causes a kink in the output waveform. Therefore, the waveform must be verified to meet SMPTE 292M specifications. There are two levels at the output depending upon the output state (logic HIGH or LOW). When taking measurements, latch the outputs in both states. An interpolation is necessary because the actual output node voltages are different when a stream of data is passing as compared to the static situation created when measuring return loss. See the GS1508 Preliminary Data Sheet for more information. Fig. 26 Compensated Output Return Loss at Logic HIGH GS1522 Fig. 27 Compensated Output Return Loss at Logic LOW 16 of 20 GENNUM CORPORATION 522 - 26 - 03 TYPICAL APPLICATION CIRCUIT VCC L6 C45 L7 10µ C14 L4 10µ 100n C15 C13 100n C40 10µ 100n VCC C1 C5 10n 10n LBCONT VCC C48 VCC L3 VCC NOTE: L3 to L8 are 0Ω RESISTORS. USE 12nH INDUCTORS IN NOISY ENVIRONMENTS. C46 100n VCC CCP2 + 1µ C6 LFA LOOP FILTER COMPONENTS VCO C47 10µ 92 91 nc 102 nc 101 nc 100 nc 83 IJI 78 nc 73 nc 72 nc 71 nc 70 nc 69 nc 68 nc 67 OSC_VEE 64 A0 63 nc nc nc VEE2 60 59 RSET 61 62 LFS LFA 90 DM 86 PLCAP 85 84 LFA_VCC LBCONT LFA_VEE 89 DFT_VEE 88 PLCAP 87 D1_18 PDSUB_VEE 77 PD_VEE 76 VCO 75 VCO 74 D1_19 PD_VCC LFS 82 81 nc nc 80 79 nc 66 nc 65 D1_16 IJI nc 99 98 nc nc 97 96 SYNC_DETECT_DISABLE VEE3 95 VCC3 94 93 nc 106 DATA_IN[16] 107 DATA_IN[15] 108 nc NOTE: R36 IS AN OPTIONAL 0Ω RESISTOR. LEAVE FLOATING. VCC R36 JMP NOTE: R35 IS AN OPTIONAL 1k RESISTOR. LEAVE FLOATING. R35 JMP LBCONT 1V EE3 2 3 nc PCLK_IN 4 nc 5 nc 33 nc 34 nc 35 nc 36 nc 6 nc 7 nc 8 nc 9 nc 10 BUF_VEE 11 nc 12 nc 13 XDIV20 14 nc 15 PLL_LOCK 16 BYPASS R6 PLL_LOCK GS1522 522 - 26 - 03 All resistors in ohms, all capacitors in farads, unless otherwise shown. C21 OPTIONAL BYPASS 0 RESET PCLK 17 RESET 18 VEE2 19 nc 20 nc 21 VCC2 22 VCC2 23 VCC2 24 VCC2 25 VCC2 26 V EE2 27 VEE2 28 VEE2 29 V EE2 30 V EE2 31 SDO1_EN 32 nc C12 VCC 10n C16 470n 37 nc 38 nc GENNUM CORPORATION CCP1 + 1µ 10n VCC C4 10n VCC C8 10n R2 75 R3 75 C7 1p5 L1 12nH R4 SDO_nc 54 SDO0 53 75 R5 75 L2 nc 52 nc 51 12nH C11 1p5 SECOND PAIR OF BNC SHOWN IS FOR DUAL FOOTPRINT OPTION ON INPUT CONNECTORS VCC SET1 VCC L5 VCC C17 C20 C18 100n C19 10µ L8 10µ 100n SYNC_DETECT_DISABLE D1_17 103 DATA_IN[19] 104 DATA_IN[18] 105 DATA_IN[17] D1_15 J3 BNC_ANCHOR D1_14 D1_13 D1_12 RSET0 58 VCC2 57 V 52.3 CC 56 nc SDO0 55 J1 J2 BNC_ANCHOR 17 of 20 GS1522 D1_11 D1_10 D1_9 109 nc 110 DATA_IN[14] 111 DATA_IN[13] 112 DATA_IN[12] 113 DATA_IN[11] 114 DATA_IN[10] 115 DATA_IN[9] C9 + 4µ7 C10 + 4µ7 116 nc 117 nc J4 D1_8 D1_7 D1_6 D1_5 118 DATA_IN[8] 119 DATA_IN[7] 120 nc 121 nc 122 DATA_IN[6] 123 DATA_IN[5] nc 50 49 SDO1 48 SDO_nc 47 SDO1 46 nc VCC2 45 44 R nc nc 43 42 D1_4 D1_3 D1_2 D1_1 D1_0 124 DATA_IN[4] 125 DATA_IN[3] 126 DATA_IN[2] 127 DATA_IN[1] 128 DATA_IN[0] 41 nc nc 40 nc 39 TYPICAL APPLICATION CIRCUIT (continued) GO1515 VCO LFA POWER CONNECT C37 VCC 100n C38 + 10µ VCC 3 VCC + C41 10µ C44 RCP1 VCTR 1 2 100n GS1522 GND 50 8 CCP3 + 1µ 4 U2 GND GO1515 GND GS1522 LOCK DETECT VCC R22 R25 Q1 LED1 150 6 GND 5 O/P 7 nc VCO LOCK 22k GS1522 SYNC DETECT DISABLE (10BIT/8BIT) VCC HDR5 GS1522 SCRAMBLER BYPASS VCC GS1522 RESET CIRCUIT VCC 2 4 S1 SYNC_DETECT_DISABLE BYPASS HDR1 1 RESET 3 R20 4k7 All resistors in ohms, all capacitors in farads, unless otherwise shown. The figures above show the recommended application circuit for the GS1522. The external VCO is the GO1515 and is specifically designed to be used with the GS1522. Figures 28 through 31 show an example PC board layout of the GS1522 IC and the GO1515 VCO. This application board layout does not reflect every detail of the typical application circuit. It is provided as a general guide to the location of the critical parts. Fig. 28 Top Layer of EB1522 PCB Layout Fig. 29 Ground Layer of EB1522 PCB Layout 18 of 20 GENNUM CORPORATION 522 - 26 - 03 GS1522 Fig. 30 Power Layer of EB1522 PCB Layout Fig. 31 Bottom Layer of EB1522 PCB Layout APPLICATION INFORMATION Please refer to the EBHDTX documentation for more detailed application and circuit information on using the GS1522 with the GS1501 and GS1511 Formatters. 19 of 20 GENNUM CORPORATION 522 - 26 - 03 PACKAGE DIMENSIONS 23.20 ±0.25 20.0 ±0.10 18.50 REF GS1522 12 TYP 12.50 REF 17.20 ±0.25 0.75 MIN 0 -7 0.30 MAX RADIUS 14.0 ±0.10 0-7 0.13 MIN. RADIUS 1.6 REF 3.00 MAX 0.88 ±0.15 0.50 BSC 2.80 ±0.25 0.27 ±0.08 128 pin MQFP All dimensions are in millimetres. CAUTION ELECTROSTATIC SENSITIVE DEVICES DO NOT OPEN PACKAGES OR HANDLE EXCEPT AT A STATIC-FREE WORKSTATION DOCUMENT IDENTIFICATION 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. REVISION NOTES: Added Pb-free and green information. For latest product information, visit www.gennum.com 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 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. © Copyright May 2000 Gennum Corporation. All rights reserved. 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