Revised October 2004 FIN1217 • FIN1218 • FIN1215 • FIN1216 LVDS 21-Bit Serializers/De-Serializers General Description Features The FIN1217 and FIN1215 transform 21-bit wide parallel LVTTL (Low Voltage TTL) data into 3 serial LVDS (Low Voltage Differential Signaling) data streams. A phaselocked transmit clock is transmitted in parallel with the data stream over a separate LVDS link. Every cycle of transmit clock 21 bits of input LVTTL data are sampled and transmitted. ■ Low power consumption The FIN1218 and FIN1216 receive and convert the 3 serial LVDS data streams back into 21 bits of LVTTL data. Refer to Table 1 for a matrix summary of the Serializers and Deserializers available. For the FIN1217, at a transmit clock frequency of 85 MHz, 21 bits of LVTTL data are transmitted at a rate of 595 Mbps per LVDS channel. ■ Up to 595 Mbps per channel ■ 20 MHz to 85 MHz shift clock support ■ 50% duty cycle on the clock output of receiver ■ ±1V common-mode range around 1.2V ■ Narrow bus reduces cable size and cost ■ High throughput (up to 1.785 Gbps throughput) ■ Internal PLL with no external component ■ Compatible with TIA/EIA-644 specification ■ Devices are offered in 48-lead TSSOP packages These chipsets are an ideal solution to solve EMI and cable size problems associated with wide and high-speed TTL interfaces. Ordering Code: Package Number Package Description FIN1215MTD Order Number MTD48 48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1216MTD MTD48 48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1217MTD MTD48 48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1218MTD MTD48 48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide Devices also available in Tape and Reel. Specify by appending suffix letter “X” to the ordering code. © 2004 Fairchild Semiconductor Corporation DS500876 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 LVDS 21-Bit Serializers/De-Serializers October 2003 FIN1217 • FIN1218 • FIN1215 • FIN1216 TABLE 1. Serializers/De-Serializers Chip Matrix Part CLK Frequency LVTTL IN LVDS OUT FIN1217 85 21 3 FIN1218 85 FIN1215 66 21 3 FIN1216 66 LVDS IN LVTTL OUT 3 21 48 TSSOP 3 21 48 TSSOP 48 TSSOP Block Diagrams Transmitter Functional Diagram for FIN1217 and FIN1215 Receiver Functional Diagram for FIN1218 and FIN1216 www.fairchildsemi.com 2 Package 48 TSSOP Pin Descriptions Pin Names I/O Type Number of Pins Description of Signals TxIn I 21 LVTTL Level Inputs TxCLKIn I 1 LVTTL Level Clock Input The rising edge is for data strobe. TxOut+ O 3 Positive LVDS Differential Data Output TxOut− O 3 Negative LVDS Differential Data Output TxCLKOut+ O 1 Positive LVDS Differential Clock Output TxCLKOut− O 1 Negative LVDS Differential Clock Output PwrDn I 1 LVTTL Level Power-Down Input Assertion (LOW) puts the outputs in high-impedance state. Power Supply Pin for PLL PLL VCC I 1 PLL GND I 2 Ground Pins for PLL LVDS VCC I 1 Power Supply Pin for LVDS Outputs LVDS GND I 3 Ground Pins for LVDS Outputs VCC I 4 Power Supply Pins for LVTTL Inputs GND I 5 Ground pins for LVTTL Inputs NC No Connect Connection Diagram FIN1217 and FIN1215 (21:3 Transmitter) Pin Assignment for TSSOP 3 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 Transmitters FIN1217 • FIN1218 • FIN1215 • FIN1216 Receivers Pin Descriptions Pin Names I/O Type Number of Pins Description of Signals RxIn I 3 Negative LVDS Differential Data Inputs RxIn+ I 3 Positive LVDS Differential Data Inputs RxCLKIn− I 1 Negative LVDS Differential Clock Input RxCLKIn+ I 1 Positive LVDS Differential Clock Input RxOut O 21 LVTTL Level Data Outputs Goes HIGH for PwrDn LOW RxCLKOut O 1 LVTTL Clock Output PwrDn I 1 LVTTL Level Input Refer to Transmitter and Receiver Power-Up and Power-Down Operation Truth Table PLL VCC I 1 Power Supply Pin for PLL PLL GND I 2 Ground Pins for PLL Power Supply Pin for LVDS Inputs LVDS VCC I 1 LVDS GND I 3 Ground Pins for LVDS Inputs VCC I 4 Power Supply for LVTTL Outputs GND I 5 NC Ground Pins for LVTTL Outputs No Connect Connection Diagram FIN1218 and FIN1216 (3:21 Receiver) Pin Assignment for TSSOP www.fairchildsemi.com 4 Transmitter Truth Table Inputs Outputs TxIn TxCLKIn PwrDn (Note 1) TxOut± Active Active H L/H TxCLKOut± L/H Active L/H/Z H L/H X (Note 2) F Active H L L/H F F H L X (Note 2) X X L Z Z H = HIGH Logic Level L = LOW Logic Level X = Don’t Care Z = High Impedance F = Floating Note 1: The outputs of the transmitter or receiver will remain in a High Impedance state until VCC reaches 2V. Note 2: TxCLKOut± will settle at a free running frequency when the part is powered up, PwrDn is HIGH and the TxCLKIn is a steady logic level (L/H/Z). Receiver Truth Table Inputs Outputs RxIn± RxCLKIn± PwrDn (Note 3) RxOut RxCLKOut Active Active H L/H L/H Active F (Note 4) H P H F (Note 4) Active H H L/H F (Note 4) F (Note 4) H P (Note 5) H X X L L H H = HIGH Logic Level L = LOW Logic Level P = Last Valid State X = Don’t Care Z = High Impedance F = Failsafe Condition Note 3: The outputs of the transmitter or receiver will remain in a High Impedance state until VCC reaches 2V. Note 4: Failsafe condition is defined as the input being terminated and un-driven (Z) or shorted or open. Note 5: If RxCLKIn± is removed prior to the RxIn± data being removed, RxOut will be the last valid state. If RxIn± data is removed prior to RxCLKIn± being removed, RxOut will be HIGH. 5 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 Truth Tables FIN1217 • FIN1218 • FIN1215 • FIN1216 Absolute Maximum Ratings(Note 6) Recommended Operating Conditions Power Supply Voltage (VCC) -0.3V to +4.6V TTL/CMOS Input/Output Voltage −0.5V to +4.6V Supply Voltage (VCC) LVDS Input/Output Voltage -0.3V to +4.6V Operating Temperature (TA)(Note 6) LVDS Output Short Circuit Current (IOSD) Storage Temperature Range (TSTG) Continuous Maximum Supply Noise Voltage −65°C to +150 °C Maximum Junction Temperature (TJ) (VCCNPP) 150 °C Lead Temperature (TL) ESD Rating (HBM, 1.5 kΩ, 100 pF) >10.0 kV LVDS I/O to GND All Pins (FIN1215, FIN1217 only) 100 mVP-P (Note 7) Note 6: Absolute maximum ratings are DC values beyond which the device may be damaged or have its useful life impaired. The datasheet specifications should be met, without exception, to ensure that the system design is reliable over its power supply, temperature, and output/input loading variables. Fairchild does not recommend operation outside datasheet specifications. 260 °C (Soldering, 4 seconds) 3.0V to 3.6V −40°C to +85°C >6.5 kV Note 7: 100mV VCC noise should be tested for frequency at least up to 2 MHz. All the specification below should be met under such a noise. ESD Rating (MM, 0Ω, 200 pF) >400V (FIN1215, FIN1217 only) Transmitter DC Electrical Characteristics Over supply voltage and operating temperature ranges, unless otherwise specified. (Note 8) Symbol Parameter Test Conditions Min Typ Max Units V Transmitter LVTTL Input Characteristics VIH Input High Voltage 2.0 VCC VIL Input Low Voltage GND 0.8 V VIK Input Clamp Voltage −0.79 −1.5 V IIN Input Current 1.8 10.0 IIK = −18 mA VIN = 0.4V to 4.6V VIN = GND −10.0 0 µA Transmitter LVDS Output Characteristics (Note 9) VOD Output Differential Voltage ∆VOD VOD Magnitude Change from Differential LOW-to-HIGH 250 VOS Offset Voltage ∆VOS Offset Magnitude Change from Differential LOW-to-HIGH IOS Short Circuit Output Current VOUT = 0V −3.5 −5.0 mA IOZ Disabled Output Leakage Current DO = 0V to 4.6V, PwrDn = 0V ±1.0 ±10.0 µA 46.2 RL = 100 Ω, See Figure 1 1.125 1.25 450 mV 35.0 mV 1.375 V mV Transmitter Supply Current ICCWT 21:3 Transmitter Power Supply Current 33.0 MHz 28.0 for Worst Case Pattern (With Load) RL = 100 Ω, 40.0 MHz 29.0 51.7 (Note 10), (Note 11) See Figure 3 65.0 MHz 34.0 57.2 85.0 MHz 39.0 62.7 10.0 55.0 (85.0 MHz Specification for FIN1217 only) ICCPDT Powered Down Supply Current PwrDn = 0.8V mA µA Note 8: All Typical values are at TA = 25°C and with VCC = 3.3V. Note 9: Positive current values refer to the current flowing into device and negative values means current flowing out of pins. Voltage are referenced to ground unless otherwise specified (except ∆VOD and VOD). Note 10: The power supply current for both transmitter and receiver can be different with the number of active I/O channels. Note 11: The 16-grayscale test pattern tests device power consumption for a “typical” LCD display pattern. The test pattern approximates signal switching needed to produce groups of 16 vertical strips across the display. www.fairchildsemi.com 6 Over supply voltage and operating temperature ranges, unless otherwise specified. Symbol Parameter tTCP Transmit Clock Period tTCH Transmit Clock (TxCLKIn) HIGH Time tTCL Transmit Clock Low Time tCLKT TxCLKIn Transition Time (Rising and Failing) tJIT TxCLKIn Cycle-to-Cycle Jitter tXIT TxIn Transition Time Test Conditions See Figure 6 (10% to 90%) See Figure 7 Min Typ Max Units 11.76 T 50.0 ns 0.35 0.5 0.65 T 0.35 0.5 0.65 T 6.0 ns 1.0 1.5 3.0 ns 6.0 ns LVDS Transmitter Timing Characteristics tTLH Differential Output Rise Time (20% to 80%) tTHL Differential Output Fall Time (80% to 20%) tSTC TxIn Setup to TxCLNIn See Figure 6 tHTC TxIn Holds to TCLKIn (f = 85 MHz) (FIN1217 only) tTPDD Transmitter Power-Down Delay See Figure 13, (Note 12) 100 tTCCD Transmitter Clock Input to Clock Output Delay See Figure 9 5.5 Transmitter Clock Input to Clock Output Delay (TA = 25°C and with VCC = 3.3V) See Figure 4 0.75 1.5 ns 0.75 1.5 ns 2.5 ns 0 ns 2.8 6.8 ns ns Transmitter Output Data Jitter (f = 40 MHz) (Note 13) −0.25 0 0.25 ns a−0.25 a a+0.25 ns 1 2a−0.25 2a 2a+0.25 ns fx7 3a−0.25 3a 3a+0.25 ns Transmitter Output Pulse Position of Bit 4 4a−0.25 4a 4a+0.25 ns tTPPB5 Transmitter Output Pulse Position of Bit 5 5a−0.25 5a 5a+0.25 ns tTPPB6 Transmitter Output Pulse Position of Bit 6 6a−0.25 6a 6a+0.25 ns ns tTPPB0 Transmitter Output Pulse Position of Bit 0 tTPPB1 Transmitter Output Pulse Position of Bit 1 tTPPB2 Transmitter Output Pulse Position of Bit 2 tTPPB3 Transmitter Output Pulse Position of Bit 3 tTPPB4 See Figure 16 a= Transmitter Output Data Jitter (f = 65 MHz) (Note 13) −0.2 0 0.2 a−0.2 a a+0.2 ns 1 2a−0.2 2a 2a+0.2 ns fx7 3a−0.2 3a 3a+0.2 ns 4a−0.2 4a 4a+0.2 ns Transmitter Output Pulse Position of Bit 5 5a−0.2 5a 5a+0.2 ns Transmitter Output Pulse Position of Bit 6 6a−0.2 6a 6a+0.2 ns ns tTPPB0 Transmitter Output Pulse Position of Bit 0 tTPPB1 Transmitter Output Pulse Position of Bit 1 tTPPB2 Transmitter Output Pulse Position of Bit 2 tTPPB3 Transmitter Output Pulse Position of Bit 3 tTPPB4 Transmitter Output Pulse Position of Bit 4 tTPPB5 tTPPB6 See Figure 16 a= Transmitter Output Data Jitter (f = 85 MHz) (FIN1217 only) (Note 13) −0.2 0 0.2 a−0.2 a a+0.2 ns 1 2a−0.2 2a 2a+0.2 ns fx7 3a−0.2 3a 3a+0.2 ns 4a−0.2 4a 4a+0.2 ns Transmitter Output Pulse Position of Bit 5 5a−0.2 5a 5a+0.2 ns tTPPB6 Transmitter Output Pulse Position of Bit 6 6a−0.2 6a 6a+0.2 ns tJCC FIN1217 Transmitter Clock Out Jitter f = 40 MHz 350 370 tTPPB0 Transmitter Output Pulse Position of Bit 0 tTPPB1 Transmitter Output Pulse Position of Bit 1 tTPPB2 Transmitter Output Pulse Position of Bit 2 tTPPB3 Transmitter Output Pulse Position of Bit 3 tTPPB4 Transmitter Output Pulse Position of Bit 4 tTPPB5 tTPLLS See Figure 16 a= (Cycle-to-Cycle) f = 65 MHz 210 230 See Figure 19 f = 85 MHz (FIN1217 only) 110 150 Transmitter Phase Lock Loop Set Time (Note 14) See Figure 11, (Note 13) 10.0 ps ms Note 12: Outputs of all transmitters stay in 3-STATE until power reaches 2V. Both clock and data output begins to toggle 10ms after VCC reaches 3V and Power-Down pin is above 1.5V. Note 13: This output data pulse position works for both transmitter with 21 TTL inputs except the LVDS output bit mapping difference (see Figure 15). Figure 16 shows the skew between the first data bit and clock output. Also 2-bit cycle delay is guaranteed when the MSB is output from transmitter. Note 14: This jitter specification is based on the assumption that PLL has a ref clock with cycle-to-cycle input jitter less than 2ns. 7 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 Transmitter AC Electrical Characteristics FIN1217 • FIN1218 • FIN1215 • FIN1216 Receiver DC Electrical Characteristics Over supply voltage and operating temperature ranges, unless otherwise specified. (Note 15) Symbol Parameter Test Conditions Min Typ Max Units V LVTTL/CMOS DC Characteristics VIH Input High Voltage 2.0 VCC VIL Input Low Voltage GND 0.8 VOH Output High Voltage VOL Output Low Voltage IOL = 2 mA 0.3 V VIK Input Clamp Voltage IIK = −18 mA −1.5 V 10.0 µA IOH = −0.4 mA IIN Input Current VIN = 0V to 4.6V IOFF Input/Output Power Off Leakage Current VCC = 0V, IOS Output Short Circuit Current 2.7 3.3 −10.0 All LVTTL Inputs/Outputs 0V to 4.6V VOUT = 0V −60.0 V V ±10.0 µA −120 mA Receiver LVDS Input Characteristics VTH Differential Input Threshold HIGH Figure 2, Table 2 VTL Differential Input Threshold LOW Figure 2, Table 2 −100 100 mV VICM Input Common Mode Range Figure 2, Table 2 0.05 2.35 V IIN Input Current VIN = 2.4V, VCC = 3.6V or 0V ±10.0 µA VIN = 0V, VCC = 3.6V or 0V ±10.0 µA mV Receiver Supply Current ICCWR 3:21 Receiver Power Supply Current 33.0 MHz CL = 8 pF, 40.0 MHz 56.0 74.0 (Note 16) See Figure 3 65.0 MHz 75.0 102 85.0 MHz 92.0 125 NA 400 (85.0 MHz Specification for FIN1218 only) ICCPDR 66.0 for Worst Case Pattern (With Load) Powered Down Supply Current PwrDn = 0.8V (RxOut stays LOW) mA µA Note 15: All Typical Values are at TA = 25°C and with VCC = 3.3V. Positive current values refer to the current flowing into device and negative values means current flowing out of pins. Voltage are referenced to ground unless otherwise specified (except ∆VOD and VOD). Note 16: The power supply current for the receiver can be different with the number of active I/O channels. www.fairchildsemi.com 8 Over supply voltage and operating temperatures, unless otherwise specified Symbol Parameter Min Typ 10.0 11.0 See Figure 8 10.0 12.2 ns RxOut Valid Prior to RxCLKOut (Rising Edge Strobe) 6.5 11.6 ns (f = 40 MHz) 6.0 11.6 15.0 T tRCOL RxCLKOut LOW Time tRCOH RxCLKOut HIGH Time tRSRC Test Conditions Max Units ns tRHRC RxOut Valid After RxCLKOut tRCOP Receiver Clock Output (RxCLKOut) Period tRCOL RxCLKOut LOW Time See Figure 8 5.0 7.8 9.0 ns tRCOH RxCLKOut HIGH Time (Rising Edge Strobe) 5.0 7.3 9.0 ns (f = 65 MHz) 4.5 7.7 4.0 8.4 11.76 T ns 50.0 ns tRSRC RxOut Valid Prior to RxCLKOut tRHRC RxOut Valid After RxCLKOut ns tRCOP Receiver Clock Output (RxCLKOut) Period tRCOL RxCLKOut LOW Time See Figure 8 4.0 6.3 6.0 ns tRCOH RxCLKOut HIGH Time (Rising Edge Strobe) 4.5 5.4 6.5 ns (f = 85 MHz) (FIN1218 only) 3.5 6.3 3.5 6.5 ns 50.0 ns tRSRC RxOut Valid Prior to RxCLKOut tRHRC RxOut Valid After RxCLKOut tROLH Output Rise Time (20% to 80%) CL = 8 pF 2.2 5.0 ns tROHL Output Fall Time (80% to 20%) See Figure 5 2.1 5.0 ns tRCCD Receiver Clock Input to Clock Output Delay See Figure 10 (Note 18) 6.9 7.5 ns 1.0 µs TA = 25°C and VCC = 3.3V 3.5 See Figure 14 ns ns tRPDD Receiver Power-Down Delay tRSPB0 Receiver Input Strobe Position of Bit 0 1.0 2.15 ns tRSPB1 Receiver Input Strobe Position of Bit 1 4.5 5.8 ns tRSPB2 Receiver Input Strobe Position of Bit 2 See Figure 17 8.1 9.15 ns tRSPB3 Receiver Input Strobe Position of Bit 3 (f = 40 MHz) 11.6 12.6 ns tRSPB4 Receiver Input Strobe Position of Bit 4 15.1 16.3 ns tRSPB5 Receiver Input Strobe Position of Bit 5 18.8 19.9 ns tRSPB6 Receiver Input Strobe Position of Bit 6 22.5 23.6 ns tRSPB0 Receiver Input Strobe Position of Bit 0 0.7 1.4 ns tRSPB1 Receiver Input Strobe Position of Bit 1 2.9 3.6 ns tRSPB2 Receiver Input Strobe Position of Bit 2 See Figure 17 5.1 5.8 ns tRSPB3 Receiver Input Strobe Position of Bit 3 (f = 65 MHz) 7.3 8.0 ns tRSPB4 Receiver Input Strobe Position of Bit 4 9.5 10.2 ns tRSPB5 Receiver Input Strobe Position of Bit 5 11.7 12.4 ns tRSPB6 Receiver Input Strobe Position of Bit 6 13.9 14.6 ns tRSPB0 Receiver Input Strobe Position of Bit 0 0.49 1.19 ns tRSPB1 Receiver Input Strobe Position of Bit 1 2.17 2.87 ns tRSPB2 Receiver Input Strobe Position of Bit 2 3.85 4.55 ns tRSPB3 Receiver Input Strobe Position of Bit 3 See Figure 17 5.53 6.23 ns tRSPB4 Receiver Input Strobe Position of Bit 4 (f = 85 MHz) (FIN1218 only) 7.21 7.91 ns tRSPB5 Receiver Input Strobe Position of Bit 5 8.89 9.59 ns tRSPB6 Receiver Input Strobe Position of Bit 6 10.57 11.27 ns tRSKM RxIn Skew Margin f = 40 MHz; See Figure 18 490 (Note 17) f = 65 MHz; See Figure 18 400 f = 85 MHz (FIN1218 only); See Figure 18 tRPLLS Receiver Phase Lock Loop Set Time ps 252 See Figure 12 10.0 ms Note 17: Receiver skew margin is defined as the valid sampling window after considering potential setup/hold time and minimum/maximum bit position. Note 18: Total channel latency from serializer to deserializer is (T + tTCCD) + (2*T + tRCCD). There is the clock period. 9 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 Receiver AC Electrical Characteristics FIN1217 • FIN1218 • FIN1215 • FIN1216 FIGURE 1. Differential LVDS Output DC Test Circuit Note A: For all input pulses, tR or tF < = 1 ns. Note B: CL includes all probe and jig capacitance. FIGURE 2. Differential Receiver Voltage Definitions and Propagation Delay and Transition Time Test Circuit TABLE 2. Receiver Minimum and Maximum Input Threshold Test Voltages Applied Voltages (V) Resulting Differential Input Voltage Resulting Common Mode Input Voltage (mV) (V) VID VIC 1.15 100 1.2 1.25 −100 1.2 2.4 2.3 100 2.35 2.3 2.4 −100 2.35 0.1 0 100 0.05 0 0.1 −100 0.05 1.2 VIA VIB 1.25 1.15 1.5 0.9 600 0.9 1.5 −600 1.2 2.4 1.8 600 2.1 1.8 2.4 −600 2.1 0.6 0 600 0.3 0 0.6 −600 0.3 www.fairchildsemi.com 10 Note: The worst case test pattern produces a maximum toggling of digital circuits, LVDS I/O and LVTTL/CMOS I/O. Depending on the valid strobe edge of transmitter, the TxCLKIn can be either rising or falling edge data strobe. FIGURE 3. “Worst Case” Test Pattern FIGURE 4. Transmitter LVDS Output Load and Transition Times FIGURE 5. Receiver LVTTL/CMOS Output Load and Transition Times FIGURE 6. Transmitter Setup/Hold and HIGH/LOW Times (Rising Edge Strobe) FIGURE 7. Transmitter Input Clock Transition Time 11 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms (Continued) FIGURE 8. Receiver Setup/Hold and HIGH/LOW Times FIGURE 9. Transmitter Clock In to Clock Out Delay (Rising Edge Strobe) FIGURE 10. Receiver Clock In to Clock Out Delay (Falling Edge Strobe) www.fairchildsemi.com 12 FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms (Continued) FIGURE 11. Transmitter Phase Lock Loop Set Time FIGURE 12. Receiver Phase Lock Loop Set Time FIGURE 13. Transmitter Power-Down Delay 13 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms (Continued) FIGURE 14. Receiver Power-Down Delay Note: This output data pulse position works for both transmitter with 21 TTL inputs except the LVDS output bit mapping difference. All the information in this diagram tells that the skew between the first data bit and clock output. Also 2-bit cycle delay is guaranteed when the MSB is output from transmitter. FIGURE 15. 21 Parallel LVTTL Inputs Mapped to 3 Serial LVDS Outputs FIGURE 16. Transmitter Output Pulse Bit Position www.fairchildsemi.com 14 FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms (Continued) FIGURE 17. Receiver Input Strobe Bit Position Note: tRSKM is the budget for the cable skew and source clock skew plus ISI (Inter-Symbol Interference). Note: The minimum and maximum pulse position values are based on the bit position of each of the 7 bits within the LVDS data stream across PVT (Process, Voltage Supply, and Temperature). FIGURE 18. Receiver LVDS Input Skew Margin 15 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 AC Loading and Waveforms (Continued) Note: This jitter pattern is used to test the jitter response (Clock Out) of the device over the power supply range with worst jitter ±3ns (cycle-to-cycle) clock input. The specific test methodology is as follows: • Switching input data TxIn0 to TxIn20 at 0.5 MHz, and the input clock is shifted to left −3ns and to the right +when data is HIGH (by switching between CLK1 and CLK2 in Figure 11) • The ±3ns cycle-to-cycle input jitter is the static phase error between the two clock sources. Jumping between two clock sources to simulate the worst case of clock edge jump (3 ns) from graphical controllers. Cycle-to-cycle jitter at TxCLK out pin should be measured cross VCC range with 100mV noise (VCC noise frequency <2 MHz). FIGURE 19. www.fairchildsemi.com 16 48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide Package Number MTD48 Fairchild does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and Fairchild reserves the right at any time without notice to change said circuitry and specifications. LIFE SUPPORT POLICY FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein: 2. A critical component in any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and (c) whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. www.fairchildsemi.com 17 www.fairchildsemi.com FIN1217 • FIN1218 • FIN1215 • FIN1216 LVDS 21-Bit Serializers/De-Serializers Physical Dimensions inches (millimeters) unless otherwise noted