TAXIchipTM Integrated Circuits Transparent Asynchronous Transmitter/Receiver Interface Am7968/Am7969-125 Am7968/Am7969-175 Data Sheet and Technical Manual 1994 1994 Advanced Micro Devices, Inc. Advanced Micro Devices reserves the right to make changes in its products without notice in order to improve design or performance characteristics. This publication neither states nor implies any warranty of any kind, including but not limited to implied warrants of merchantability or fitness for a particular application. AMD assumes no responsibility for the use of any circuitry other than the circuitry in an AMD product. The information in this publication is believed to be accurate in all respects at the time of publication, but is subject to change without notice. AMD assumes no responsibility for any errors or omissions, and disclaims responsibility for any consequences resulting from the use of the information included herein. Additionally, AMD assumes no responsibility for the functioning of undescribed features or parameters. Trademarks AMD and the AMD logo are registered trademarks of Advanced Micro Devices, Inc. TAXIchip and TAXI are trademarks of Advanced Micro Devices, Inc. Product names used in this publication are for identification purposes only and may be trademarks of their respective companies. TABLE OF CONTENTS Am7968/Am7969 TAXIchip Integrated Circuits Am7968/Am7969 Data Sheet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Am7968/Am7969 Technical Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 Chapter 1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 1.1 The Am7968 TAXITM Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 1.2 The Am7969 TAXI Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 Chapter 2 Using the TAXIchip Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 2.1 Data and Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 2.2 Operational Modes: Local, Cascade and Test . . . . . . . . . . . . . . . . . . . . . . . . 53 Chapter 3 Data Encoding, Violation and Syncs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1 Data Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2 Violation Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3 TAXI PLL Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 53 57 57 Chapter 4 Clock Generation and Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 TAXI Transmitter Clock Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.1 Local Mode Transmitters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2 TAXI Receiver Clock Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.1 Cascade Mode Receivers (Am7969-125 only) . . . . . . . . . . . . . . . . . . 59 59 60 60 61 Chapter 5 Interfacing with the Serial Media . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1 Very Short Link, DC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2 Terminated, DC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3 Terminated, AC Coupled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.4 Baseline Wander and the AC Coupling Capacitor . . . . . . . . . . . . . . . . . . . . . 5.5 Interfacing to Fiber Optic Transmitters/Receivers . . . . . . . . . . . . . . . . . . . . . 5.5.1 DC-Coupled TAXl-Fiber Optic Transceiver Interface . . . . . . . . . . . . . 5.5.2 AC-Coupled TAXl-Fiber Optic Transceiver Interface . . . . . . . . . . . . . 5.6 Interfacing to Coaxial Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.7 Interfacing to Twisted-Pair Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 62 63 63 64 66 66 68 68 70 Chapter 6 Board Layout Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1 Printed Circuit Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1.1 Rules for Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2 Layout using Fiber Optic Data Links . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71 71 71 73 Table of Contents iii AMD Chapter 7 Cascade Mode Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1 Transmit Cascaded Data with a Single TAXI Transmitter . . . . . . . . . . . . . . . 7.2 Receivers In Cascade Mode: Connections (Am7969-125 only) . . . . . . . . . . . 7.3 Auto-Repeat Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3.1 Receiver Connections in Auto-Repeat Configuration . . . . . . . . . . . . . 7.3.2 Timing Limitations of the Auto-Repeat Configuration . . . . . . . . . . . . . 7.4 Unbalanced Configuration (Am7968/Am7969-125 only) . . . . . . . . . . . . . . . . 74 76 79 81 81 84 85 Chapter 8 Test Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1 Transmitter Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2 Receiver Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3 Timing Relationships in Test Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 87 89 89 Appendix A Optical Components Manufacturers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 Appendix B Error Detection Efficiency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 Appendix C TAXI TIPs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 iv Table of Contents FINAL Am7968/Am7969 TAXIchipTM Integrated Circuits (Transparent Asynchronous Xmitter-Receiver Interface) Advanced Micro Devices DISTINCTIVE CHARACTERISTICS ■ ■ ■ Parallel TTL bus interface — Eight Data and four Command Pins — or nine Data and three Command Pins ■ ■ ■ ■ ■ — or ten Data and two Command Pins ■ Transparent synchronous serial link — +5 V ECL Serial I/O — AC or DC coupled — NRZI 4B/5B, 5B/6B encoding/decoding ■ Drive coaxial cable or twisted pair directly Easy interface with fiber optic data links 32–140 Mbps (4–17.5 Mbyte/s) data throughput Asynchronous input using STRB/ACK Automatic MUX/DEMUX of Data and Command Complete on-chip PLL, Crystal Oscillator Single +5 V supply operation 28-pin PLCC or DIP or LCC GENERAL DESCRIPTION The Am7968 TAXIchip Transmitter and Am7969 TAXIchip Receiver Chipset is a general-purpose interface for very high-speed (4–17.5 Mbyte/s, 40–175 Mbaud serially) point-to-point communications over coaxial or fiber-optic media. The TAXIchip set emulates a pseudo-parallel register. They load data into one side and output it on the other, except in this case, the “other” side is separated by a long serial link. The speed of a TAXIchip system is adjustable over a range of frequencies, with parallel bus transfer rates of 4 Mbyte/s at the low end, and up to 17.5 Mbyte/s at the high end. The flexible bus interface scheme of the TAXIchip set accepts bytes that are either 8, 9, or 10 bits wide. Byte transfers can be Data or Command signaling. BLOCK DIAGRAM Am7968 Data Command N Strobe (STRB) Acknowledge (ACK Strobe & Acknowledge M Input Latch X1 X2 Clock (CLK) Oscillator and Clock Gen. Data Mode Select (DMS) Test Serial In (TSERIN) Serial Interface Encoder Latch Data Encoder Shifter Media Interface (SEROUT+) Serial Out + (SEROUT–) Serial Out – Test/Local Select (TLS) Note: N can be 8, 9, or 10 bits; total of N + M = 12. 07370F-1 Publication# 07370 Rev. F Issue Date: April 1994 Amendment /0 AMD BLOCK DIAGRAM (continued) Am7969 (X1) Serial In+ (SERIN+) Media Interface Serial In– (SERIN–) Oscillator and Clock Gen. Shifter (X2) PLL Clock Generator Decoder Latch (DMS) Data Mode Select Data Decoder (CNB) Catch Next Byte (IGM) I-Got-Mine Byte Sync Logic (CLK) Clock Output Latch N (VLTN) Violation M (DSTRB) Data Strobe Data Command (CSTRB) Command Strobe Note: N can be 8, 9, or 10 bits Total of N + M = 12 07370F-2 CONNECTION DIAGRAMS Top View Am7968 DIPs LCC/PLCC STRB DI4 SEROUT+ 3 26 DI3 SEROUT– 4 25 DI2 VCC2 (ECL) 5 24 DI1 VCC1 (TTL) 6 23 DI0 VCC2 (ECL) 5 25 DI2 VCC3 (CML) 7 22 GND1 (TTL) VCC1 (TTL) 6 24 DI1 RESET 8 21 GND2 (CML) VCC3 (TTL) 7 23 DI0 8 22 GND1 (TTL) 1 28 27 26 DI3 2 DI4 3 DI5 4 DMS 9 20 X1 RESET TLS 10 19 X2 DMS 9 21 GND2 (CML) TSERIN 11 18 CLK TLS 10 20 X1 CI0 12 17 DI6 TSERIN 11 19 X2 CI1 13 16 DI7 DI9/CI2 14 15 DI8/CI3 Note: Pin 1 is marked for orientation. Am7968/Am7969 CLK DI6 DI7 DI8/CI3 DI9/CI2 CI1 CI0 12 13 14 15 16 17 18 07370F-3 2 ACK DI5 27 STRB 28 2 SEROUT+ 1 SEROUT- ACK 07370F-4 AMD CONNECTION DIAGRAMS (continued) Top View Am7969 LCC/PLCC DO5 DO1 26 DO6 DO0 4 25 DO7 IGM 5 24 CNB RESET 6 23 VCC1 (TTL) 7 VCC2 (CML) 4 3 2 1 28 27 26 DO6 27 3 DO5 2 DO4 DO2 DO3 DO4 DO2 28 DO1 1 6 24 CNB X2 VCC1 (TTL) 7 23 X2 22 X1 VCC2 (CML) 8 22 X1 8 21 GND2 (CML) SERIN+ 9 21 GND2 (CML) SERIN+ 9 20 GND1 (TTL) SERIN- 10 20 GND1 (TTL) SERIN– 10 19 CLK DMS 11 19 CLK DMS 11 18 DO8/CO3 12 13 14 15 16 17 18 DSTRB 12 17 DO9/C02 CSTRB 13 16 CO1 VLTN 14 15 CO0 CO1 DO8/CO3 RESET DO9/CO2 DO7 CO0 25 VLTN 5 CSTRB IGM DSTRB DO3 DO0 DIPs 07370F-6 07370F-5 Note: Pin 1 is marked for orientation. LOGIC SYMBOLS Am7968 TLS DMS Am7969 RESET 12 CNB DIn/CIm DMS RESET 2 2 12 SEROUT+ SERIN+ DOn/COm VLTN STRB ACK DSTRB X1 X1 CSTRB X2 TSERIN X2 CLK IGM CLK 07370F-7 07370F-8 VCC = Power Supply (3) VCC = Power Supply (2) GND = Ground (2) GND = Ground (2) Am7968/Am7969 3 AMD ORDERING INFORMATION Standard Products AMD standard products are available in several packages and operating ranges. The ordering number (Valid Combination) is formed by a combination of: AM7968 AM7969 –125 D C TEMPERATURE RANGE C = Commerical (0°C to +70°C) PACKAGE TYPE D = 28-Pin Ceramic DIP (CD 028) J = 28-Pin Plastic Leaded Chip Carrier (PL 028) SPEED OPTION -125 = Max Serial Encoded Transmission Rate is 125 MHz -175 = Max Serial Encoded Transmission Rate is 175 MHz DEVICE NUMBER/DESCRIPTION Am7968 TAXIchip Transmitter Am7969 TAXIchip Receiver Valid Combinations AM7968-125 AM7969-125 AM7968-175 AM7969-175 4 Valid Combinations Valid Combinations list configurations planned to be supported in volume for this device. Consult the local AMD sales office to confirm availability of specific valid combinations and to check on newly released combinations. DC, JC Am7968/Am7969 AMD MILITARY ORDERING INFORMATION CPL Products AMD products for Aerospace and Defense applications are available in several packages and operating ranges. CPL (Controlled Products List) products are compliant with MIL-STD-883C requirements with exceptions for VCC or operating temperature. The order number (Valid Combination) is formed by a combination of: AM7968 AM7969 -125 /L K C C = Controlled Product List TEMPERATURE RANGE K = –30°C to 125°C M = –55°C to 125°C PACKAGE TYPE D = 28-Pin Ceramic DIP (CD 028) L = 28-Pin Ceramic Leadless Chip Carrier (CL 028) SPEED OPTION -125 = Max Serial Encoded Transmission Rate is 125 MHz DEVICE NUMBER/DESCRIPTION Am7968 – TAXIchip Transmitter (Local Mode only) Am7969 – TAXIchip Receiver (Local Mode only) Valid Combinations Valid Combinations list configurations planned to be supported in volume for this device. Consult the local AMD sales office to confirm availability of specific valid combinations and to check on newly released combinations. Group A Tests Group A tests consist of Subgroups 1, 2, 3, 7, 8, 9, 10, 11. Valid Combinations Pkg Temps (TC) VCC CPL Part Number LCC –30°C to 125°C 4.5 V to 5.5 V AM7968-125/LKC LCC –55°C to 125°C 4.75 V to 5.5 V DIP –30°C to 125°C 4.5 V to 5.5 V DIP –55°C to 125°C 4.75 V to 5.5 V LCC –30°C to 125°C 4.5 V to 5.5 V LCC –55°C to 125°C 4.75 V to 5.5 V DIP –30°C to 125°C 4.5 V to 5.5 V DIP –55°C to 125°C 4.75 V to 5.5 V SMD Part Number APL Part Number 5962-9052701M3A AM7968-125V/B3A 5962-9052701MXA AM7968-125V/BXA 5962-9052801M3A AM7969-125V/B3A 5962-9052801MXA AM7969-125V/BXA AM7968-125/DKC AM7969-125/LKC AM7969-125/DKC Am7968/Am7969 5 AMD Command. When it is wired to VCC, the Am7968 Transmitter will assume Data to be nine bits wide, with three bits of Command. If DMS is left floating (or terminated to 1/2 VCC), the Am7968 will assume Data to be ten bits wide, with two bits of Command. PIN DESCRIPTION Am7968 TAXIchip Transmitter ACK Input-Strobe Acknowledge (TTL Output) ACK High signifies that the Am7968 is ready to accept new Data and Command. The timing of ACK’s response to STRB depends on the condition of the Input Latch (in given CLK cycle). If the Input Latch is empty, data is immediately stored and ACK closely follows STRB. If the Input Latch contains previously stored data when STRB is asserted, ACK is delayed until the next falling edge of CLK. Note that for ACK to rise STRB must maintain HIGH for both of the above conditions. CI0 – CI1 Parallel Command In (TTL Inputs) These two inputs accept parallel command information from the host system. If one or more command bits are logic “1”, the command bit pattern is latched, encoded, and transmitted in place of any pattern on the Data inputs. GND1, GND2 Ground Pins GND1 is a TTL I/O Ground and GND2 is an internal Logic and Analog Ground. RESET PLL RESET (Input) This pin is normally left open, but can be momentarily grounded to force the internal PLL to reactivate lock. This allows for correction in the unlikely occurrence of PLL lockup on application of power. RESET has an internal pull-up resistor which causes it to float high when left unconnected (50 K ohm nominal). If this board is driven by a board Reset signal, an open drain (or open collector) style output should be used to insure the High level signal is at VCC. SEROUT+, SEROUT– CLK Differential Serial Data Out (Differential Open Emitter ECL Outputs) Clock (TTL I/O) CLK is an I/O pin that supplies the byte-rate clock reference to drive all internal logic. When TLS is connected to ground (Local mode), CLK is enabled as a free-running (byte-rate) clock output which runs at the Crystal Oscillator frequency; this output can be used to drive the X1 input of TAXIchip Receivers or other system logic. In Test mode CLK becomes an input. In Test Mode 1 CLK is a Byte rate input and in Test Mode 2 it is a Bit rate input. DI0 – DI7 Parallel Data In (TTL Inputs) These eight inputs accept parallel data from the host system, to be latched, encoded and transmitted. These differential ECL outputs generate data at ECL voltage levels referenced to +5.0 V. When connected to appropriated pull down resistors, they are capable of driving 50-Ω terminated lines, either directly or through isolating capacitors. STRB Input Strobe Signal (TTL Input) A rising edge on the STRB input causes the Data (DI0 – DI9) or the Command (CI0 – CI3) inputs to be latched into the Am7968 Transmitter. The STRB signal is normally taken LOW after ACK has risen. TLS DI8/CI3 Test/Local Select (Input) Parallel Data (8) In or Command (3) In (TTL Input) TLS input determines the mode of operation. When TLS is wired to GND, the Am7968 Transmitter assumes a Local mode connection to the media. It will output NRZI encoded data, and will enable its CLK output driver. The TLS pin should always be grounded during normal operation. DI8/CI3 input is either Data or Command, depending upon the state of DMS. DI9/CI2 Parallel Data (9) In or Command (2) In (TTL Input) DI9/CI2 input is either Data or Command, depending upon the state of DMS. DMS When TLS is wired to VCC (Test Mode 1),the serial data is NRZ, CLK becomes an input, and ACK timing is modified. This mode is only used for Automatic Test Equipment (ATE) testing at full speed. Data Mode Select (Input) Data Mode Select input determines the Data pattern width. When it is wired to GND, the Am7968 Transmitter will assume Data to be eight bits wide, with four bits of 6 When this input is left unconnected, it floats to an intermediate level which puts the Am7968 Transmitter into its Test Mode 2. In Test Mode 2, the internal clock Am7968/Am7969 AMD multiplier is switched out, and the internal logic is clocked directly from the CLK pin. Test Mode 2 is included to ease Automatic Test Equipment (A.T.E.) testing by making the internal logic of the Transmitter synchronous to the external clock instead of the internal PLL. TSERIN Test Serial Input (Pseudo ECL Input) This pin is left unconnected in Local Mode operation. TSERIN can be used to input serial data patterns into the Shifter in Test Mode 1 operation. X1, X2 Crystal Oscillator Inputs (Inputs) The two crystal input pins connect to an internal parallel mode oscillator which operates at the fundamental frequency of the external crystal. The byte rate matches the crystal frequency. During normal operation, the byte rate is set by the crystal frequency. Alternatively, X1 can be driven by an external TTL frequency source. In multiple TAXI systems this external source could be another Am7968’s CLK output. VCC1, VCC2, VCC3 Power Supply VCC1, VCC2, and VCC3 are +5.0 volt nominal power supply pins. VCC1 powers TTL I/O, VCC2 powers ECL and VCC3 powers internal Logic and Analog circuitry. Am7968/Am7969 7 AMD Am7969 TAXIchip Receiver CLK DO0 – DO7 Clock (TTL Output) These eight outputs reflect the most recent Data received by the Am7969 Receiver. Parallel Data Out (TTL Outputs) This is a free-running clock output which runs at the byte rate, and is synchronous with the serial input. It falls at the time that the Decoder Latch is loaded from the Shifter, and rises at mid-byte. The CLK output of the Receiver is not suitable as a frequency source for another TAXI Transmitter or Receiver. It is intended to be used by the host system as a clock synchronous with the received data. DO8/CO3 Parallel Data (8) Out or Command (3) Out (TTL Output) DO8/CO3 output will be either a Data or Command bit, depending upon the state of DMS. DO9/CO2 Parallel Data (9) Out or Command (2) Out (TTL Output) CNB Catch Next Byte Input (TTL Input) If this input is connected to the CLK output, the Receiver will be in the Local mode, and each received byte will be captured, decoded and latched to the outputs. DO9/CO2 output will be either a Data or Command bit, depending upon the state of DMS. If the CNB input is HIGH, it allows the Am7969 Receiver to capture the first byte after a sync. The Am7969 Receiver will wait for another sync before latching the data out, and capturing another. If CNB is toggled LOW, it will react as if it had decoded a sync byte. Output Data Strobe (TTL Output) In Cascade mode, CNB input is typically connected to an upstream Am7969’s IGM output. The first Am7969 Receiver in line will have its CNB input connected to VCC. For Am7969-175 applications, an inverter is required between CLK and CNB for speeds above 140 MHz. See Figure 3 and Timing Specifications T47A, T47B, T48, and T49. CO0 – CO1 Parallel Command Out (TTL Output) These two outputs reflect the most recent Command data received by the Am7969 Receiver. DSTRB The rising edge of this output signals the presence of new Data on the DO0 – DO9 lines. Data is valid just before the rising edge of DSTRB. GND1, GND2 Ground GND1 is a TTL I/O Ground, GND2 is an internal Logic and Analog Ground. IGM I-Got-Mine (TTL Output) This pin signals cascaded Am7969 Receivers that their upstream neighbor has captured its assigned data byte. IGM falls at the mid-byte when the first half of a sync byte is detected in the Shifter. It rises at mid-byte when it detects a non-sync pattern. During Local mode operation the IGM signal is undefined. RESET CSTRB PLL RESET (Input) Command Data Strobe (TTL Output) This pin is normally left open, but can be momentarily grounded to force the internal PLL to reactivate lock. This allows for correction in the unlikely occurance of PLL Lockup on application of power. The rising edge of this output signals the presence of new Command data on the CO0 – CO3 lines. Command bits are valid just before the rising edge of CSTRB. RESET has an internal pull-up resistor (50 K nominal) which causes it to float high when left unconnected. DMS Data Mode Select (Input) DMS selects the Data pattern width. When it is wired to GND, the Am7969 Receiver will assume Data to be eight bits wide, with four bits of Command. When it is wired to VCC the Am7969 Receiver will assume Data to be nine bits wide, with three bits of Command. If DMS is left floating (or terminated to 1/2 VCC), the Am7969 Receiver will assume Data to be ten bits wide, with two bits of Command. 8 If this board is driven by a board Reset signal, an open drain (or open collector) style output should be used to insure the High level signal is at VCC. SERIN+, SERIN– Differential Serial Data In (ECL Inputs) Data is shifted serially into the Shifter. The SERIN+ and SERIN– differential ECL inputs accept ECL voltage Am7968/Am7969 AMD swings, which are referenced to +5.0 V. When SERIN– is grounded, the Am7969 is put into Test Mode; SERIN+ becomes a single-ended ECL input, the PLL clock generator is bypassed, and X1 determines the bit rate (rather than the byte rate). Both pins have internal pull down resistors which cause unterminated inputs to stay low. VCC1, VCC2 Power Supply VCC1 and VCC2 are +5.0 volt nominal power supply pins. VCC1 powers TTL I/O, and VCC2 powers internal Logic and Analog circuitry. same time DOi or COi change and will be followed by either DSTRB or CSTRB. This pin goes LOW when the next valid byte is decoded. X1, X2 Crystal Oscillator Inputs (Inputs) These two crystal input pins connect to an internal parallel/mode oscillator which oscillates at the fundamental frequency external crystal. During normal operation, the byte rate is set by the crystal frequency. Alternatively, X1 can be driven by an external frequency source. In multiple TAXI systems, this external source could be a TAXI Transmitter’s CLK output or an external TTL frequency source. VLTN Violation (TTL Output) The rising edge of this output indicates that a transmission error has been detected. It changes state at the Am7968/Am7969 9 AMD FUNCTIONAL DESCRIPTION System Configuration The TAXIchip system provides a means of connecting parallel data systems over a serial link (Figure 2). In LOCAL Mode (normal operation mode) each TX/RX pair is connected over a serial link which can be a Fiber Optic or Copper Media (Figure 3). The Am7968 Transmitter accepts inputs from a sending host system using a simple STRB/ACK handshake. Parallel bits are saved by the Am7968’s input latch on the rising edge of a STRB input. The input latch can be updated on every CLK cycle; if it still contains previously stored data when a second STRB pulse arrives, Data is stored in the input latch, and the second ACK response is delayed until the next CLK cycle. The inputs to an Am7968 Transmitter can be either Data or Command and may originate from two different parts of the host system. A byte cycle may contain Data or Command, but not both. Data represents the normal data channel message traffic between host systems. Commands can come from a communication control section of the host system. Commands occur at a relatively infrequent rate but have priority over Data. Examples include communication specific commands such as REQUEST-TO-SEND or CLEAR-TO-SEND; or application specific commands such as MESSAGEADDRESS-FOLLOWS, MESSAGE-TYPE-FOLLOWS, INITIALIZE YOUR SYSTEM, ERROR, RETRANSMIT, HALT, etc. The Am7968 Transmitter switches between Data and Command by examining Command input patterns. All 0s on Command input pins cause information on the Am7968’s Data input pins to be latched into the device on the rising edge of STRB. All other Command patterns cause a Command symbol to be sent in response to an input strobe. The pattern on the Data inputs is ignored when a Command symbol is sent. In either case, if there is no STRB before the next byte boundary, a Sync symbol will be transmitted. The sync pattern maintains link synchronization and provides an adequate signal transition density to keep the Receiver Phase-Locked-Loop (PLL) circuits in lock. It was chosen for its unique pattern which never occurs in any Data or Command messages. This feature allows Sync to be used to establish byte boundaries. The Sync pattern utilized by TAXIchip set keeps the automatic gain control (AGC) fiber-optic transceiver circuits in their normal range because the pattern has zero DC offset. The Am7969 Receiver detects the difference between Data and Command patterns and routes each to the proper Output Latch. When a new Data pattern enters the output latch, DSTRB is pulsed and Command 10 information remains unchanged. If a Command pattern is sent to the output latch or if Sync is received, CSTRB is pulsed and Data outputs remain in their previous state. Reception of a Sync pattern clears the Command outputs to all 0’s, since Sync is a legal command. Noise-induced bit errors can distort transmitted bit patterns. The Am7969 Receiver logic detects most noiseinduced transmission errors. Invalid bit patterns are recognized and indicated by the assertion of the violation (VLTN) output pin. This signal rises to a logic “1” state at the same time that Data or Command outputs change and remains HIGH until a valid pattern is detected by the Data Decoder. The error detection method used in the Receiver cannot identify bit errors which transform one valid Command or Data pattern to another. Fault-sensitive systems should use additional error checking mechanisms to guarantee message integrity. Am7968 Transmitter The Transmitter accepts messages from its parallel input pins (Command or Data). Once latched into an Am7968, a parallel message is encoded, serialized, and shifted out to the serial link. The idle time between transmitted bytes (evident by lack of STRB) is filled with Sync bytes. Am7969 Receiver Receivers accept differential signals on the SERIN+/ SERIN– input pins. This information, previously encoded by an Am7968 Transmitter, is loaded into a decoder. When serial patterns are received, they are decoded and routed to the appropriate outputs. If the received message is a Command, it is stored in the output latch, appears at the Command output pins, and CSTRB is pulsed; Data output pins continue holding the last Data byte and DSTRB stays inactive. If a Data message follows the reception of a Command, Command output pins continue holding the previous Command byte and CSTRB stays inactive. The command outputs will retain their states until another Command signal is received (Sync is considered to be a valid command which, when decoded, sets Command outputs to “0” and issues a resulting CSTRB). Byte Width The TAXIchip set has twelve parallel interface pins which are designated to carry either Command or Data bits. The Data Mode Select (DMS) pin on each chip can be set to select one of three modes of operation: eight Data and four Command bits, nine Data and three Command, or ten Data and two Command. This allows the system designer to select the byte-width which best suits system needs. Am7968/Am7969 AMD Am7968 Encoder/Am7969 Decoder To guarantee that the Am7969’s PLL can stay locked onto an incoming bit stream, the data encoding scheme must provide an adequate number of transitions in each data pattern. This implies a limit on the maximum time allowed between transitions. The TAXIchip set encoding scheme is based on the ANSI X3T9.5 (FDDI) committee’s 4-bit/5-bit (4B/5B) code. An ANSI X3T9.5 system used an 8-bit parallel data pattern. This pattern is divided into two 4-bit nibbles which are each encoded into a 5-bit symbol. Of the thirty-two patterns possible with these five bits, sixteen are chosen to represent the sixteen input Data patterns. Some of the others are used as Command symbols. Those remaining represent invalid patterns that fail either the run-length test or DC balance tests. Transmitters in 8-bit mode use two 4B/5B encoders to encode eight Data bits into a 10-bit pattern. In 9-bit mode, Transmitters use one 5B/6B encoder and one 4B/5B encoder to code nine Data bits into an 11-bit pattern. In 10-bit mode, two 5B/6B encoders are used to change ten bits of Data into a 12-bit pattern (see Tables 1 and 2 for encoding patterns). The Am7968 Transmitter further encodes all symbols using NRZI (Non Return to Zero, Invert on Ones). NRZI represents a “1” by a transition and a “0” by the lack of transition. In this system a “1” can be a HIGH-to-LOW or LOW-to-HIGH transition. This combination of 4B/5B and NRZI encoding ensures at least two transitions per symbol and permits a maximum of three consecutive non-transition bit times. The Am7969 then uses the same method to decode incoming symbols so that the whole encoding/decoding process is transparent to the user. Most Serially transmitted data patterns with this code will have the same average amount of HIGH and LOW times. This near DC balance minimizes pattern-sensitive decoding errors which are caused by jitter in ACcoupled systems. Operational Modes In normal operational mode, a single Transmitter/ Receiver pair is used to transfer 8, 9, or 10 bits of parallel Data over a private serial link. (On the Am7968, the TLS pin is tied to ground and TSERIN is left unconnected). On the Am7969, CNB must be connected to the CLK output. The Am7969 Receiver continuously deserializes the incoming bit stream, decodes the resulting patterns, and saves parallel data at its output latches (see Figure 3). Local mode provides a fast and efficient parallel throughout because data can be transferred on every clock cycle. On the other hand, it is not necessary for the host to match the byte rate set by the Transmitter’s crystal oscillator; the Am7968 automatically sends a Sync pattern during each clock cycle in which no new Data or Command messages are being transmitted. Cascade Mode (for –125 only) For very wide parallel buses, TAXI Receiver’s (commercial temperature parts only) can be Cascaded. The Am7969 Receivers all have their SERIN+ and SERIN– pins connected to the media (or an optical data link). IGM of each Am7969 is connected to CNB of its downstream neighbor or is left unconnected on the Receiver farthest downstream. CNB of the first Receiver is tied HIGH, making this device the only Receiver in the chain that can act on the first non-Sync pattern in a message (see below). Each TAXIchip Receiver monitors the serial link and a special acknowledgment scheme is used to direct symbols into each of the Am7969s. When a Catch-NextByte (CNB) input is HIGH, the Receiver will capture the next non-Sync symbol from the serial link. At this point, the device forces its I-Got-Mine (IGM) pin HIGH to tell the downstream Receiver to capture the next symbol. The Receiver then waits for the Sync symbol or for its CNB to be set LOW before transferring the message to its output latch. IGM is forced LOW whenever a Sync byte is detected or when CNB goes LOW. This IGMCNB exchange continues down the chain until the last Receiver captures its respective byte. The next byte to appear on the serial link will be a Sync symbol which is detected by all of the cascaded Am7969s. On the following Clock cycle their messages are transferred to the output latch of each device and sent to the receiving host. IGM pins on all Receivers are also set LOW when the first half of the Sync symbol is detected. Asynchronous Operation Inputs to the Am7968 Transmitter Input Latch can be asynchronous to its internal clock. Data STRB will latch data into the Am7968 Transmitter and an internal clock will transfer the data to the Encoder Latch at the first byte boundary. Data can be entered at any rate less than the maximum transfer rate without regard to actual byte boundaries. As data rates approach the TAXI BYTE RATE, care must be taken to insure that the 2 BYTE FIFO inside TAXI Transmitter is not over filled. STRB/ACK handshake will assure that every byte is transferred correctly. At higher byte rates, where delays and setup/hold times make the STRB/ACK handshake impractical, STRB should be synchronized with CLK. Synchronous Operation The Transmitter may be strobed synchronous by tying the strobe to the input clock. When doing this a provision should be make to inhibit the strobe periodically to ensure proper byte alignment. In the absence of a strobe, Syncs will be transmitted on the serial link which will allow the receiver to re-align the byte boundaries. In addition it is essential that the delay between the falling edge Am7968/Am7969 11 AMD of the internal byte clock (CLK) and the rising edge of strobe does not violate tBB specification shown in the SWITCHING CHARACTERISTICS Section. The internal byte clock controls the flow of data from the input register through the shift register. The falling edge of the internal byte clock delineates the end of one byte from the start of the next. Due to various tolerances in the PLL, the period of the internal byte clock may vary slightly. This effect may cause a shift in the location of the byte boundary with respect to the falling edge of the clock. This variation may move the byte boundary and therefore creates a window during which the part should not be strobed. This window called the t6 window, is shown in the figure below. If the part is strobed during the t6 window data will not be lost however, a sync may be added and the transmitter latency will be increased by one byte time. Strobe Stayout Area (t6 window) CLK –9/8(t1/n) + 9 ns 20 ns Nominal Byte Boundary 07370F-9 data) from having clocks which are too narrow, the output logic will stretch an output pulse when the pulse would have been less than a byte-time long. The data being processed just prior to this re-acquisition of sync will be lost. The Sync symbol, and all subsequent data will be processed correctly. TAXI User Test Modes TLS input can be used to force the Am7968 Transmitter into either of the two Test modes. If TLS is open or terminated to approximately VCC/2 (Test Mode 2), the internal VCO is switched out and everything is clocked directly from the CLK input. The serial output data rate will be at the CLK bit rate and not at 10X, 11X, or 12X, as is the case in normal operation. Test Mode 2 will allow testing of the logic in the Latches, Encoder, and Shifter without having to first stabilize the PLL clock multiplier. In Test Mode 1 (TLS wired to VCC), the PLL is enabled and the chip operates normally, except that the output is an NRZ stream (CLK is an input & ACK function is slightly modified). This will allow testing of all functions at full rate without needing to perform match loop tests to accommodate the data inversion characteristics of NRZI. Differential SERIN+/SERIN– inputs can be used to force the Am7969 Receiver into its Test mode. This will allow testing of the logic in the Latches, Decoder, and Shifter without having to first stabilize the the PLL. If SERIN– is tied to ground, the internal VCO is switched out and X1 becomes the internal bit rate clock. The serial data rate will be at the CLK bit rate, not at 10X, 11X, or 12X, as is the case in normal operation. In this mode, SERIN+ becomes a single-ended serial data input with nominal 100K ECL threshold voltages (Referenced to +5 volts). Sync Acquisition In case of errors which cause Am7969 Receivers to lose byte/symbol sync, and on power-up, internal logic detects this loss-re-acquisition of sync and modifies the CLK output. CLK output is actually a buffered version of the signal which controls Data transfers inside the Am7969 Receiver on byte boundaries. Byte boundaries move when the Am7969 Receiver loses, and reacquires sync. To protect slave systems (which may use this output as a clock synchronous with the incoming 12 These Test Mode switches make the parts determinate, synchronous systems, instead of statistical, asynchronous ones. An automatic test system will be able to clock each part through the functional test patterns at any rate or sequence that is convenient. After the logic has been verified, the part can be put back into the normal mode, and the PLL functions verified knowing that the rest of the chip is functional. Am7968/Am7969 AMD Oscillator The Am7968 and Am7969 contain an inverting amplifier intended to form the basis of a parallel mode oscillator. The design of this oscillator considered several factors related to its application. The first consideration is the desired frequency accuracy. This may be subdivided into several areas. An oscillator is considered stable if it is insensitive to variations in temperature and supply voltage, and if it is unaffected by individual component changes and aging. The design of the TAXIchip set is such that the degree to which these goals are met is determined primarily by the choice of external components. Various types of crystal are available and the manufacturers’ literature should be consulted to determine the appropriate type. For good temperature stability, zero temperature coefficient capacitors should be used (Type NPO). The mechanism by which a crystal resonates is electromechanical. This resonance occurs at a fundamental frequency (1st harmonic) and at all odd harmonics of this frequency (even harmonic resonance is not mechanically possible). Unless otherwise constrained, crystal oscillators operate at their fundamental frequencies. A typical crystal specification for use in this circuit is: Fundamental Frequency 3.3 MHz–17.5 MHz ± 0.1% Resonance: Mode Parallel Load Capacitor (Correlation) 30 pF Operating Temperature Range 0°C to 70°C Temperature Stability ±100 ppm Drive Level (Correlation) 2 mW Effective Series Resistance 25 Ω (max) Holder Type Low profile Aging for 10 years ±10 ppm It is good practice to ground the case of the crystal to eliminate stray pick-up and keep all connections as short as possible. RESET Am7968 or, Am7969 X1 Power On RESET (Optional) X2 C C 07370F-10 C* = 220 pF for 4.0–12.5 MHz crystal, 150 pF for a 12.5–17.5 MHz Crystal. *C determined by crystal specifications and trace capacities. Values shown are typical. Figure 1. Connections for 4.0 MHz–17.5 MHz Am7968/Am7969 13 AMD Table 1. TAXIchip Encoder Patterns 4B/5B Encoder Scheme 5B/6B Encoder Scheme HEX Data 4-Bit Binary Data 5-Bit Encoded Symbol HEX Data 5-Bit Binary Data* 6-Bit Encoded Symbol 0 1 2 3 4 5 6 7 8 9 A B C D E F 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 11110 01001 10100 10101 01010 01011 01110 01111 10010 10011 10110 10111 11010 11011 11100 11101 00 01 02 03 04 05 06 07 08 09 0A 0B 0C 0D 0E 0F 00000 00001 00010 00011 00100 00101 00110 00111 01000 01001 01010 01011 01100 01101 01110 01111 110110 010001 100100 100101 010010 010011 010110 010111 100010 110001 110111 100111 110010 110011 110100 110101 10 11 12 13 14 15 16 17 18 19 1A 1B 1C 1D 1E 1F 10000 10001 10010 10011 10100 10101 10110 10111 11000 11001 11010 11011 11100 11101 11110 11111 111110 011001 101001 101101 011010 011011 011110 011111 101010 101011 101110 101111 111010 111011 111100 111101 * Note: HEX data is parallel input data which is represented by the 4- or 5-bit binary data listed in the column to the immediate right of HEX data. Binary bits are listed from left to right in the following order. 8-Bit Mode: D7, D6, D5, D4, (4-Bit Binary), and D3, D2, D1, D0, (4-Bit Binary) 9-Bit Mode: D8, D7, D6, D5, D4, (5-Bit Binary), and D3, D2, D1, D0, (4-Bit Binary) 10-Bit Mode: D8, D7, D6, D5, D4, (5-Bit Binary), and D9,D3, D2, D1, D0, (5-Bit Binary) Serial bits are shifted out with the most significant bit of the most significant nibble coming out first. 14 Am7968/Am7969 AMD Table 2. TAXIchip Command Symbols Am7969 Receiver Am7968 Transmitter Command Input Command Output Binary Encoded Symbol Mnemonic HEX Binary 0 0000 XXXXX XXXXX Data No STRB (Note 1) 1 2 3 4 5 6 7 8 (Note 3) 9 A (Note 3) B C D (Note 3) E (Note 3) F (Note 3) No STRB (Note 1) 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 11000 10001 JK (8-bit Sync) No Change (Note 2) 0 No Change (Note 2) 0000 I I TT TS IH TR SR SS HH HI HQ RR RS QH QI QQ 1 2 3 4 5 6 7 8 9 A B C D E F 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 No Change (Note 2) 000 HEX 8-Bit Mode 11111 01101 01101 11111 01101 11001 11001 00100 00100 00100 00111 00111 00000 00000 00000 11111 01101 11001 00100 00111 00111 11001 00100 11111 00000 00111 11001 00100 11111 00000 9-Bit Mode 0 000 XXXXXX XXXXX Data No STRB (Note 1) 1 2 3 4 5 6 7 No STRB (Note 1) 001 010 011 100 101 110 111 011000 10001 LK (9-bit Sync) No Change (Note 2) 0 I’I T’T T’S I’ H T’R S’R S’S 1 2 3 4 5 6 7 001 010 011 100 101 110 111 0 00 XXXXXX XXXXXX Data No STRB (Note 1) 1 2 3 No STRB (Note 1) 01 10 11 011000 100011 LM (10-bit Sync) No Change (Note 2) 0 No Change (Note 2) 00 111111 111111 011101 011101 011101 111001 I’I’ T’T’ T’S’ 1 2 3 01 10 11 111111 011101 011101 111111 011101 111001 111001 11111 01101 11001 00100 00111 00111 11001 10-Bit Mode Notes: 1. Command pattern Sync cannot be explicitly sent by Am7968 Transmitter with any combination of inputs and STRB, but is used to pad between user data. 2. A strobe with all Os on the Command input lines will cause Data to be sent. See Table 1. 3. While these Commands are legal data and will not disrupt normal operation if used occasionally, they may cause data errors if grouped into recurrent fields. Normal PLL operation cannot be guaranteed if one or more of these commands is continuously repeated. Am7968/Am7969 15 AMD CLK (input is multiplied by ten (8-bit mode), eleven (9-bit mode), or twelve (10-bit mode), using the internal PLL to create the bit rate. Am7968 Transmitter Functional Block Description (Refer to page 1) Crystal Oscillator/Clock Generator The serial link speed is derived from a master frequency source (byte rate). This source can either be the built-in Crystal Oscillator, or a clock signal applied through the X1 pin. This signal is buffered and sent to the CLK output when Am7968 Transmitter is in Local mode. The working frequency can be varied between 3.3 MHz and 17.5 MHz. The crystal frequency required to achieve the maximum 175 Mbaud on the serial link, and the resultant usable data transfer rate will be: Mode Crystal Frequency Am7968-125 Input and Am7969-125 Maximum Parallel Throughput 8-Bit 12.50 MHz 80 ns/pattern (100 Mbit/sec) 125/10 9-Bit 11.36 MHz 88 ns/pattern (102 Mbit/sec) 125/11 10-Bit 10.42 MHz 96 ns/pattern (104 Mbit/sec) 125/12 Mode Crystal Frequency 8-Bit 17.50 MHz 57.1 ns/pattern (140 Mbit/sec) 175/10 9-Bit 15.90 MHz 62.8 ns/pattern (143 Mbit/sec) 175/11 10-Bit 14.58 MHz 68.5 ns/pattern (145 Mbit/sec) 175/12 Am7968-175 Input and Am7969-175 Maximum Parallel Throughput Internal Divide Ratio Internal Divide Ratio Input Latch Data Encoder The Am7968’s Input Latch accommodates asynchronous strobing of Data and Command by being divided into two stages. Encodes twelve data inputs (8, 9, 10 Data bits or 4, 3, 2 Command inputs) into 10, 11, or 12 bits. The Command data inputs control the transmitted symbol. If all Command inputs are LOW, the symbol for the Data bits will be sent. If Command inputs have any other pattern then the symbol representing that Command will be transmitted. If STRB is asserted when both stages are empty, Data or Command bits are transferred directly to the second stage of the Input Latch and ACK rises shortly after STRB. This pattern is now ready to move to the Encoder Latch at the next falling edge of CLK. An input pattern is strobed into the first stage of the Input Latch only when the second stage is BUSY (contains previously stored data). The Transmitter will be BUSY when STRB is asserted a second time in a given CLK cycle. Contents of the first stage are not protected from subsequent STRBs within the same CLK cycle. At the falling edge of CLK, previously stored data is transferred from the second stage to the Encoder Latch and the new data is clocked into the second stage of the Input Latch. If in Local mode, ACK will rise at this time. Encoder Latch Input to the Encoder Latch is clocked by an internal signal which is synchronous with the shifted byte being sent on the serial link. Whenever a new input pattern is strobed into the Input Latch, the data is transferred to the Encoder Latch at the next opportunity. 16 Shifter The Shifter is parallel-loaded from the Encoder at the first available byte boundary, and then shifted until the next byte boundary. The Shifter is being serially loaded at all times. As data is being shifted out of the Transmitter, the shifter fills from the LSB. If parallel data is available at the end of the byte, it is parallel-loaded into the Shifter and begins shifting out during the next clock cycle. Otherwise, the serially loaded data fills the next byte. The serial data which loads into the Shifter is generated by an internal state machine which generates a repeating Sync pattern. Media Interface The Media Interface is differential ECL, referenced to +5 V. It is capable of driving lines terminated with 50 Ω to (VCC - 2.0) volts. Am7968/Am7969 AMD when the first byte after a Sync symbol is transferred. Parallel outputs are made on a byte boundary, after CNB falls, or when Sync is detected. Am7969 Receiver Functional Block Description (Refer to page 1) Crystal Oscillator/Clock Generator The data recovery PLL in the Am7969 must be supplied with a reference frequency at the expected byte rate of the data to be recovered. The source of this frequency can either be the built-in Crystal Oscillator, or an external clock signal applied through the X1 pin. The reference frequency source is then multiplied by ten (8-bit mode), eleven (9-bit mode) or twelve (10-bit mode) using an internal PLL. Media Interface SERIN+, SERIN– inputs are to be driven by differential ECL voltages, referenced to +5 V. Serial data at these inputs will serve as the reference for PLL tracking. PLL Clock Generator A PLL Clock recovery loop follows the incoming data and allows the encoded clock and data stream to be decoded into a separated clock and data pattern. It uses the crystal oscillator and clock generator to predict the expected frequency of data and will track jittered data with a characteristically small offset frequency. Shifter The Shifter is serially loaded from the Media Interface, using the bit clock generated by PLL. Byte Sync Logic The incoming data stream is a continuous stream of data bits, without any significant signal which denotes byte boundaries. This logic will continuously monitor the data stream, and upon discovering the reserved code used for Am7969 Receiver Sync, will initialize a synchronous counter which counts bits, and indicates byte boundaries. The logic signal that times data transfers from the Shifter to the Decoder Latch is buffered and sent to the CLK output. CLK output from the Receiver is not suitable as a frequency source for another TAXI Transmitter or Receiver. It is intended to be used by the host system as a clock synchronous with the received data. This output is synchronous with the byte boundary and is synchronous with the Receiver’s internal byte clock. Byte Sync Logic is responsible for generating the internal strobe signals for Parallel Output Latches. It also generates the IGM (I-Got-Mine) signal in Test mode The I-Got-Mine (IGM) signal will fall when the first half of a Sync is detected in the Shifter or when CNB goes LOW. It will remain LOW until the first half of a non-Sync byte is detected in the Shifter, whereupon it will rise (assuming that the CNB input is HIGH). A continuous stream of normal data or command bytes will cause IGM to go HIGH and remain HIGH. A continuous stream of Sync’s will cause IGM to stay LOW. IGM will go HIGH during the byte before data appears at the output. This feature could be used to generate an early warning of incoming data. Decoder Latch Data is loaded from the Shifter to this latch at each symbol/byte boundary. It serves as the input to the Data Decoder. Data Decoder Decodes ten, eleven, or twelve data inputs into twelve outputs. In 8-bit mode, data is decoded into either an 8-bit Data pattern or a 4-bit Command pattern. In 9-bit mode, data is decoded into either a 9-bit Data pattern or a 3-bit Command pattern. In 10-bit mode, data is decoded into either a 10-bit Data pattern or a 2-bit Command pattern. The decoder separates Data symbols from Command symbols, and causes the appropriate strobe output to be asserted. Parallel Output Latch Output Latch will be clocked by the byte clock, and will reflect the most recent data on the link. Any Data pattern will be latched to the Data outputs and will not affect the status of the Command outputs. Likewise, any Command pattern will be latched to the Command outputs without affecting the state of the Data outputs. Any data transfer, either Data or Command will be synchronous with an appropriate output strobe. However, there will be CSTRBs when there is no active data on the link, since Sync is a valid Command code. Any pattern which does not decode to a valid Command or Data pattern is flagged as a violation. The output of the decoder during these violations is indeterminate and will result in either a CSTRB or DSTRB output when the indeterminate pattern is transferred to the output latch. Am7968/Am7969 17 AMD Command Source M Message Transfer Control Logic Data Source M Command Signals Command Signals STRB CSTRB Am7968 ACK VLTN Am7969 Transmission Media N DSTRB N Data Signals Data Signals Command Destination Data Path Control Logic Data Destination 07370F-11 Note: N can be 8, 9, or 10 bits of parallel data; total of N + M = 12. Figure 2. TAXIchip System Block Diagram 18 Am7968/Am7969 AMD Message Transfer Control Logic Data Source Message Transfer Control Logic Data Source Command Source 8 9 4 DI0 – DI7 CI0 – CI3 STRB SEROUT+ SEROUT– (Note (Note1)1) TLS DMS 3 DI0 – DI8 ACK CI0 – CI2 SEROUT+ SEROUT– TAXI TX #1 X2 X1 Command Source CLK TLS STRB ACK TAXI TX #2 X2 X1 DMS CLK * (Note 2) 3.3 MHz to 17.5 MHz To Other Stages (Note 4) (Note 4) 3.3 MHz to 17.5 MHz 3.3 MHz to 17.5 MHz * * SERIN+ SERIN– X1 CNB TAXI RX #1 DSTRB DO0– DO7 8 Data Destination X2 DMS CO0 – CO3 CLOCK IGM VLTN CSTRB SERIN+ SERIN– DO0 – DO8 9 4 Command Destination X2 DMS CLOCK TAXI RX #2 CNB DSTRB X1 Data Destination Data Path Control Logic IGM VLTN CO0 – CO2 CSTRB 3 Command Destination Data Path Control Logic Notes: 1. DMS = GND = 8 Bit Mode TLS = GND = Local Mode Pin 11 = Don’t Connect = Local Mode TLS = GND = Local Mode Pin 11 = Don’t Connect = Local Mode 2. DMS = VCC = 9 Bit Mode 3. Two 8-bit local mode systems in parallel will result in an effective data rate of 200 Mbps. 4. Use inverter for operation above 140 MHz only. *Alternatively, the X1 inputs may be driven by external TTL frequency sources. 07370F-12 Figure 3. TAXIchip System in Local Mode Am7968/Am7969 19 AMD From Serial Media SERIN– SERIN+ RX1 VCC SERIN– SERIN+ RX2 DMS Am7969 Primary RX CNB X2 RX3 DMS Am7969 IGM CLK SERIN– SERIN+ CNB X1 DMS Am7969 IGM X2 X1 CNB IGM X2 X1 07370F-13 Crystal OSC Figure 4. Cascaded Receiver Clock Connections (Commercial –125 only) 20 Am7968/Am7969 N/C AMD Am7968/Am7969-125 ABSOLUTE MAXIMUM RATINGS OPERATING RANGES StorageTemperature . . . . . . . . . . . . –65°C to +150°C Ambient Temperature Under Bias . . . . . . . . . . . . . . . . . . . –55°C to +125°C Supply Voltage to Ground Potential Continuous . . . . . . . . . . . . –0.5 V to +7.0 V Commercial (C) Devices Temperature (TA) . . . . . . . . . . . . . . . . . 0°C to +70°C Supply Voltage (VCC) . . . . . . . . . . . . +4.5 V to +5.5 V Operating ranges define those limits between which the functionality of the device is guaranteed. DC Voltage Applied to Outputs . . . . . . . . . . . . . . . . . . . . . –0.5 V to VCC Max DC Input Voltage . . . . . . . . . . . . . . . –0.5 V to +5.5 V DC Output Current . . . . . . . . . . . . . . . . . . . ±100 mA DC Input Current . . . . . . . . . . . . . –30 mA to +5.0 mA Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device reliability. Am7968/Am7969-125 21 AMD DC CHARACTERISTICS over operating range unless otherwise specified Am7968-125 TAXIchip Transmitter Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK VOH1 Output HIGH Voltage ACK VCC = Min, IOH = –1 mA VIN = 0 or 3 V 2.4 V VOH2 Output HIGH Voltage CLK VCC = Min, IOH = –3 mA VIN = 0 or 3 V 2.4 V VOL Output LOW Voltage ACK, CLK VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V All Inputs Except CLK 50 µA CLK Input 150 µA –15 –85 mA ISC Output Short Circuit Current ACK, CLK 0.45 2.0 (Note 4) V V Serial Interface Signals: SEROUT+, SEROUT– VOH Output HIGH Voltage VCC = Min ECL Load VCC –1.025 VCC –0.88 V VOL Output LOW Voltage VCC = Min ECL Load VCC –1.81 VCC –1.62 V Miscellaneous Signals: X1, VCC1, VCC2, VCC3 VIHX Input HIGH Voltage X1 VILX Input LOW Voltage X1 IILX Input LOW Current X1 IIHX ICC 2.0 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current SEROUT = ECL Load, DMS = 0 VCC1 = VCC2 = VCC3 = Max Pin VCC1 (TTL) 20 mA Pin VCC2 (ECL) 45 mA Pin VCC3 (CML) 200 mA *See notes following end of Switching Characteristics tables. 22 V Am7968/Am7969-125 AMD Am7969-125 TAXIchip Receiver Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DO0–DO7, DO8/CO3, DO9/CO2, CO0–CO1, DSTRB, CSTRB, IGM, CLK, CNB, VLTN VOH Output HIGH Voltage VCC = Min, IOH = –1 mA VIN = 0 or 3 V VOL Output LOW Voltage VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min, IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V 50 µA –15 –85 mA ISC 2.4 V 0.45 2.0 Output Short Circuit Current (Note 4) V V Serial Interface Signals: SERIN+, SERIN– VIHS Input HIGH Voltage SERIN+ (Notes 9, 21) VCC –1.165 VCC –0.88 V VILS Input LOW Voltage SERIN+ (Notes 9, 21) VCC –1.81 VCC –1.475 V VTHT Test Mode Threshold SERIN– VCC = Max 0.25 V VDIF Differential Input Voltage 0.3 1.1 V VICM Input Common Mode Voltage (Note 6) 3.05 VCC –0.55 V IIL Input LOW Current VCC = Max, VIN = VCC –1.81 V 0.5 IIH Input HIGH Current VCC = Max, VIN = VCC –0.88 V µA 220 µA Miscellaneous Signals: X1, VCC1, VCC2 VIHX Input HIGH Threshold X1 VILX Input LOW Threshold X1 IILX Input LOW Current X1 IIHX ICC 2.0 V 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current VCC1 = VCC2 = Max Pin VCC1 (TTL) 50 mA DMS = 0 V 300 mA Pin VCC2 (CML) Am7968/Am7969-125 23 AMD SWITCHING CHARACTERISTICS (Note 20) Am7968-125 TAXIchip Transmitter (Notes 10, 13, 22) No. Parameter Symbol Parameter Description Test Conditions Min Max Units 25n ns Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK 1 tP CLK Period 8n 2 tPW CLK Pulse Width HIGH 30 ns 3 tPW CLK Pulse Width LOW 30 ns 4 tPW STRB Pulse Width HIGH (Note 7) 15 ns 5 tPW STRB Pulse Width LOW 15 ns 6 tBB Internal Byte Boundary to CLK↓ (Note 11) 9 tS Data–STRB Setup Time 5 ns 10 tH Data–STRB Hold Time 15 ns 11 tH ACK↑ to STRB↓ Hold (Note 8) TTL Output Load 0 ns 12 tH ACK↓ to STRB↑ Hold TTL Output Load 0 ns 13 tPD STRB↑ to ACK↑ (Note 18) TTL Output Load 14 tPD STRB↓ to ACK↓ 15 tPD CLK↓ to ACK↑ (Note 18) –9t1 8n +9 20 ns 40 ns TTL Output Load 23 ns TTL Output Load 3t1 n + 33 ns Serial Interface Signals: SEROUT+, SEROUT– (Note 2) 22 tSK✝ SEROUT± Skew ECL Output Load –200 +200 ps 23 ✝ SEROUT± Output Rise Time ECL Output Load .45 2 ns ✝ 2 ns tR 24 tF SEROUT± Output Fall Time ECL Output Load .45 26 tPW✝ SEROUT ± Pulse Width LOW ECL Output Load t1 n – 5% t1 n + 5% ns 27 tPW✝ SEROUT ± Pulse Width HIGH ECL Output Load t1 t1 n – 5% n + 5% ns Miscellaneous Signals: X1 (Note 15) 24 29 tPW X1 Pulse Width HIGH (Note 12) TTL Output Load on CLK 35 ns 30 tPW X1 Pulse Width LOW (Note 12) TTL Output Load on CLK 35 ns 32 tPD X1 ↑ to CLK↑ TTL Load 32 ns 33 tPD X1 ↓ to CLK↓ TTL Load 32 ns Am7968/Am7969-125 AMD Am7969-125 TAXIchip Receiver (Notes 13, 14, 22) No. Parameter Symbol Bus Interface Signals: Parameter Description Test Conditions Min Max Unit DO0–DO7,DO8/CO3,DO9/CO2,CO0–CO1,DSTRB,CSTRB, IGM,CLK,CNB,VLTN 35 tP CLK Period (Note 24) 36 tPD Data Valid to STRB↑ Delay TTL Output Load 37 tPD CLK↓ to STRB↑ TTL Output Load 38 tPD CLK↑ to STRB↓ TTL Output Load 38a tPD STRB↑ to CLK↑ (Note 23) TTL Output Load 39 tPD CLK↓ to Data Valid Delay TTL Output Load 40 tPW STRB Pulse Width HIGH TTL Output Load 5t35 2n 41 tPW CLK Pulse Width HIGH TTL Output Load 5t35 n –15 ns 42 tPW CLK Pulse Width LOW TTL Output Load 5t35 n –15 ns 43 tPD SERIN to CLK↓ Delay TTL Output Load t35 2t35 2n +17 n +26 ns 44 tPD CLK↑ to IGM↓ TTL Output Load 2t35 n +7 ns 45 tPD CLK↑ to IGM↑ TTL Output Load 2t35 n +10 ns 46 tPD CNB↓ to IGM↓ TTL Output Load 20 ns 8n 2t35 n t35 n –7 3t35 n –14 tS CNB↑ to CLK↑ Setup Time (Note 5) 47A tS CNB↓ to CLK↑ Setup Time (Note 19) - 48 tH CNB↓ to CLK↑ Hold 49 tPW ns ns ns - 47 ns ns 2t35 n +15 2t35 - n –32 CNB Pulse Width LOW 25n t35 n +23 ns 5t35 n ns ns t35 n –31 ns 2t35 n +5 ns 2t35 n ns Serial Interface Signals: SERIN+, SERIN– 57 tJ✝ SERIN± Peak to Peak Input Jitter Tolerance (Note 16) 5 ns Miscellaneous Signals: X1 (Note 15) 60 tPW X1 Pulse Width HIGH 35 ns 61 tPW X1 Pulse Width LOW 35 ns Am7968/Am7969-125 25 AMD (Page intentionally left blank) 26 Am7968/Am7969-175 AMD Am7968/Am7969-175 ABSOLUTE MAXIMUM RATINGS OPERATING RANGES StorageTemperature . . . . . . . . . . . . –65°C to + 50°C Ambient Temperature Under Bias . . . . . . . . . . . . . . . . . . . –55°C to +125°C Supply Voltage to Ground Potential Continuous . . . . . . . . . . . . –0.5 V to +7.0 V Commercial (C) Devices Temperature (TC) . . . . . . . . . . . . . . 0°C to +70°C Supply Voltage (VCC) . . . . . . . . . +4.5 V to +5.5 V Operating ranges define those limits between which the functionality of the device is guaranteed. DC Voltage Applied to Outputs . . . . . . . . . . . . . . . . . . . . . –0.5 V to VCC Max DC Input Voltage . . . . . . . . . . . . . . . –0.5 V to +5.5 V DC Output Current . . . . . . . . . . . . . . . . . . . +100 mA DC Input Current . . . . . . . . . . . . . –30 mA to +5.0 mA Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device reliability. Am7968/Am7969-175 27 AMD DC CHARACTERISTICS over operating range unless otherwise specified Am7968-175 TAXIchip Transmitter Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK VOH1 Output HIGH Voltage ACK VCC = Min, IOH = –1 mA VIN = 0 or 3 V 2.4 V VOH2 Output HIGH Voltage CLK VCC = Min, IOH = –3 mA VIN = 0 or 3 V 2.4 V VOL Output LOW Voltage ACK, CLK VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V All Inputs Except CLK 50 µA CLK Input 150 µA –15 –85 mA ISC Output Short Circuit Current ACK, CLK 0.45 2.0 (Note 4) V V Serial Interface Signals: SEROUT+, SEROUT– VOH Output HIGH Voltage VCC = Min ECL Load VCC –1.025 VCC –0.88 V VOL Output LOW Voltage VCC = Min ECL Load VCC –1.81 VCC –1.62 V Miscellaneous Signals: X1, VCC1, VCC2, VCC3 VIHX Input HIGH Voltage X1 VILX Input LOW Voltage X1 IILX Input LOW Current X1 IIHX ICC 2.0 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current SEROUT = ECL Load, DMS = 0 VCC1 = VCC2 = VCC3 = Max Pin VCC1 (TTL) 20 mA Pin VCC2 (ECL) 45 mA Pin VCC3 (CML) 200 mA *See notes following end of Switching Characteristics tables. 28 V Am7968/Am7969-175 AMD Am7969-175 TAXIchip Receiver Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DO0–DO7, DO8/CO3, DO9/CO2, CO0–CO1, DSTRB, CSTRB, IGM, CLK, CNB, VLTN VOH Output HIGH Voltage VCC = Min, IOH = –1 mA VIN = 0 or 3 V VOL Output LOW Voltage VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min, IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V 50 µA –15 –85 mA ISC 2.4 V 0.45 2.0 Output Short Circuit Current (Note 4) V V Serial Interface Signals: SERIN+, SERIN– VIHS Input HIGH Voltage SERIN+ (Notes 9, 21) VCC –1.165 VCC –0.88 V VILS Input LOW Voltage SERIN+ (Notes 9, 21) VCC –1.81 VCC –1.475 V VTHT Test Mode Threshold SERIN– VCC = Max 0.25 V VDIF Differential Input Voltage 0.3 1.1 V VICM Input Common Mode Voltage (Note 6) 3.05 VCC –0.55 V IIL Input LOW Current VCC = Max, VIN = VCC –1.81 V 0.5 IIH Input HIGH Current VCC = Max, VIN = VCC –0.88 V µA 220 µA Miscellaneous Signals: X1, VCC1, VCC2 VIHX Input HIGH Threshold X1 VILX Input LOW Threshold X1 IILX Input LOW Current X1 IIHX ICC 2.0 V 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current VCC1 = VCC2 = Max Pin VCC1 (TTL) 50 mA DMS = 0 V Pin VCC2 (CML) 300 mA Am7968/Am7969-175 29 AMD SWITCHING CHARACTERISTICS (Note 20) Am7968-175 TAXIchip Transmitter (Notes 10, 13, 22) No. Parameter Symbol Parameter Description Test Conditions Min Max 5.7 n 8n Units Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK 1 tP CLK Period 2 tPW CLK Pulse Width HIGH 20 ns 3 tPW CLK Pulse Width LOW 20 ns 4 tPW STRB Pulse Width HIGH (Note 7) 15 ns 5 tPW STRB Pulse Width LOW 15 ns 6 tBB Internal Byte Boundary to CLK↓ (Note 11) 9 tS Data–STRB Setup Time 5 ns 10 tH Data–STRB Hold Time 15 ns 11 tH ACK↑ to STRB↓ Hold (Note 8) TTL Output Load 0 ns 12 tH ACK↓ to STRB↑ Hold TTL Output Load 0 ns 13 tPD STRB↑ to ACK↑ (Note 18) TTL Output Load 14 tPD STRB↓ to ACK↓ 15 tPD CLK↓ to ACK↑ (Note 18) –9t1 8n +9 20 ns ns 40 ns TTL Output Load 23 ns TTL Output Load 3t1 n + 33 ns Serial Interface Signals: SEROUT+, SEROUT– (Note 2) 22 tSK✝ SEROUT± Skew ECL Output Load –200 +200 ps 23 ✝ SEROUT± Output Rise Time ECL Output Load .45 2 ns ✝ 2 ns tR 24 tF SEROUT± Output Fall Time ECL Output Load .45 26 tPW✝ SEROUT ± Pulse Width LOW ECL Output Load t1 n – 5% t1 n + 5% ns 27 tPW✝ SEROUT ± Pulse Width HIGH ECL Output Load t1 t1 n – 5% n + 5% ns Miscellaneous Signals: X1 (Note 15) 30 29 tPW X1 Pulse Width HIGH (Note 12) TTL Output Load on CLK 24 ns 30 tPW X1 Pulse Width LOW (Note 12) TTL Output Load on CLK 24 ns 32 tPD X1↑ to CLK↑ TTL Load 32 ns 33 tPD X1↓ to CLK↓ TTL Load 32 ns Am7968/Am7969-175 AMD Am7969-175 TAXIchip Receiver (Notes 13, 14, 22) No. Parameter Symbol Bus Interface Signals: Parameter Description Test Conditions Min Max Unit DO0–DO7, DO8/CO3, DO9/CO2, CO0–CO1, DSTRB, CSTRB, IGM, CLK, CNB, VLTN 35 tP CLK Period (Note 24) 36 tPD Data Valid to STRB↑ Delay TTL Output Load 37 tPD CLK↓ to STRB↑ TTL Output Load 38 tPD CLK↑ to STRB↓ TTL Output Load t35 n –5 ns 38a tPD STRB↑ to CLK↑ (Note 23) TTL Output Load 3t35 n –10 ns 39 tPD CLK↓ to Data Valid Delay TTL Output Load 40 tPW STRB Pulse Width HIGH TTL Output Load 5t35 2n 41 tPW CLK Pulse Width HIGH TTL Output Load 5t35 n –7 ns 42 tPW CLK Pulse Width LOW TTL Output Load 5t35 n –4 ns 43 tPD SERIN to CLK↓ Delay TTL Output Load t35 2t35 2n +17 n +26 ns 47A tS CNB↓ to CLK↑ Setup Time (Note 19) 47B tS CNB↑ to CLK↓ Setup Time 48 tH CNB↓ to CLK↑ Hold 49 tPW 5.7 n CNB Pulse Width LOW 8 n 2t35 –2 n ns 2t35 n +15 - - ns ns t35 n +23 ns 5t35 n ns t35 n –31 ns 29 2t35 n –3 ns 2t35 n ns ns Serial Interface Signals: SERIN+, SERIN– 57 tJ✝ SERIN± Peak to Peak Input Jitter Tolerance (Note 16) 2 ns Miscellaneous Signals: X1 (Note 15) 60 tPW X1 Pulse Width HIGH 21 ns 61 tPW X1 Pulse Width LOW 21 ns Am7968/Am7969-175 31 AMD (Page intentionally left blank) 32 Am7968/Am7969-125 Military AMD Am7968/Am7969-125 MILITARY ABSOLUTE MAXIMUM RATINGS StorageTemperature . . . . . . . . . . . . –65°C to +150°C Ambient Temperature Under Bias . . . . . . . . . . . . . . . . . . . –55°C to +125°C Supply Voltage to Ground Potential Continuous . . . . . . . . . . . . –0.5 V to +7.0 V DC Voltage Applied to Outputs . . . . . . . . . . . . . . . . . . . . . –0.5 V to VCC Max DC Input Voltage . . . . . . . . . . . . . . . –0.5 V to +5.5 V DC Output Current . . . . . . . . . . . . . . . . . . . ±100 mA DC Input Current . . . . . . . . . . . . . –30 mA to +5.0 mA Stresses above those listed under Absolute Maximum Ratings may cause permanent device failure. Functionality at or above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device reliability. OPERATING RANGES Military (SMD) Devices 5962-9052701M3A 5962-9052701MXA 5962-9052801M3A 5962-9052801MXA Temperature (TC) . . . . . . . . . . . . –55°C to +125° C Supply Voltage (VCC) . . . . . . . . . . . +4.75 V to +5.5 V Military (CPL) Devices Am7968-125/LKC Am7968-125/DKC Am7969-125/LKC Am7969-125/DKC Temperature (TC) . . . . . . . . . . . . . –30°C to +125° C Supply Voltage (VCC) . . . . . . . . . . . . +4.5 V to +5.5 V Operating ranges define those limits between which the functionality of the device is guaranteed. Am7968/Am7969-125 Military 33 AMD DC CHARACTERISTICS over operating range unless otherwise specified (for CPL Products Group A, Subgroups 1, 2, 3 are tested unless otherwise noted) Am7968-125 Military TAXIchip Transmitter Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK VOH1 Output HIGH Voltage ACK VCC = Min, IOH = –1 mA VIN = 0 or 3 V 2.4 V VOH2 Output HIGH Voltage CLK VCC = Min, IOH = –1 mA VIN = 0 or 3 V 2.4 V VOL Output LOW Voltage ACK, CLK VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V All Inputs Except CLK 50 µA CLK Input 150 µA –15 –85 mA ISC Output Short Circuit Current ACK, CLK 0.45 TC = –30 to +125°C TC = –55 to +125°C (Note 4) 2.0 2.1 V V V Serial Interface Signals: SEROUT+, SEROUT– VOH Output HIGH Voltage VCC = Min ECL Load VCC –1.165 VCC –0.88 V VOL Output LOW Voltage VCC = Min ECL Load VCC –1.81 VCC –1.62 V Miscellaneous Signals: X1, VCC1, VCC2, VCC3 VIHX Input HIGH Voltage X1 VILX Input LOW Voltage X1 IILX Input LOW Current X1 IIHX ICC VCC = Max (Note 9) TC = –30 to +125°C TC = –55 to +125°C V V 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current SEROUT = ECL Load, DMS = 0 VCC1 = VCC2 = VCC3 = Max Pin VCC1 (TTL) 30 mA Pin VCC2 (ECL) 45 mA Pin VCC3 (CML) 215 mA *See notes following end of Switching Characteristics tables. 34 2.0 2.1 Am7968/Am7969-125 Military AMD Am7969-125 Military TAXIchip Receiver Parameter Symbol Parameter Description Test Conditions (Note 1) Min Max Unit Bus Interface Signals: DO0–DO7, DO8/CO3, DO9/CO2, CO0–CO1, DSTRB, CSTRB, IGM, CLK, CNB, VLTN VOH Output HIGH Voltage VCC = Min, IOH = –1 mA VIN = 0 or 3 V VOL Output LOW Voltage VCC = Min, IOL = 8 mA VIN = 0 or 3 V VIH Input HIGH Voltage VCC = Max (Note 9) VIL Input LOW Voltage VCC = Max (Note 9) 0.8 V VI Input Clamp Voltage VCC = Min, IIN = –18 mA –1.5 V IIL Input LOW Current VCC = Max, VIN = 0.4 V –400 µA IIH Input HIGH Current VCC = Max, VIN = 2.7 V 50 µA II Input Leakage Current VCC = Max, VIN = 5.5 V 50 µA –15 –85 mA ISC 2.4 V 0.45 2.0 Output Short Circuit Current (Note 4) V V Serial Interface Signals: SERIN+, SERIN– VIHS Input HIGH Voltage SERIN+ (Notes 9, 21) VCC –1.165 VCC –0.88 V VILS Input LOW Voltage SERIN+ (Notes 9, 21) VCC –1.81 VCC –1.475 V VTHT Test Mode Threshold SERIN– VCC = Max 0.25 V VDIF Differential Input Voltage 0.3 1.1 V VICM Input Common Mode Voltage (Note 6) 3.05 VCC –0.55 V IIL Input LOW Current VCC = Max, VIN = VCC –1.81 V 0.5 IIH Input HIGH Current VCC = Max, VIN = VCC –0.88 V µA 220 µA Miscellaneous Signals: X1, VCC1, VCC2 VIHX Input HIGH Threshold X1 VILX Input LOW Threshold X1 IILX Input LOW Current X1 IIHX ICC 2.0 V 0.8 V VIN = 0.45 V –900 µA Input HIGH Current X1 VIN = 2.4 V +600 µA Supply Current VCC1 = VCC2 = Max Pin VCC1 (TTL) 55 mA DMS = 0 V 335 mA Pin VCC2 (CML) Am7968/Am7969-125 Military 35 AMD SWITCHING CHARACTERISTICS over operating range unless otherwise specified (Note 20) (for CPL Products Group A, Subgroups 9, 10, and 11 are tested unless otherwise noted) Am7968-125 Military TAXIchip Transmitter (Notes 10, 13, 22) No. Parameter Symbol Parameter Description Test Conditions Min Max Units Bus Interface Signals: DI0–DI7, DI8/CI3, DI9/CI2, CI0–CI1, STRB, ACK, CLK 1 tP CLK Period 2 tPW CLK Pulse Width HIGH 25 ns 3 tPW CLK Pulse Width LOW 25 ns 4 tPW STRB Pulse Width HIGH (Note 7) 20 ns 5 tPW STRB Pulse Width LOW 20 ns 6 tBB Internal Byte Boundary to CLK↓ (Note 11) 9 tS Data–STRB Setup Time 10 ns 10 tH Data–STRB Hold Time 15 ns 11 tH ACK↑ to STRB↓ Hold (Note 8) TTL Output Load 0 ns 0 8n –9t1 8n +3 25 n 25 ns ns 12 tH ACK↓ to STRB↑ Hold TTL Output Load 13 tPD STRB↑ to ACK↑ (Note 18) TTL Output Load 45 ns ns 14 tPD STRB↓ to ACK↓ TTL Output Load 25 ns 15 tPD CLK↓ to ACK↑ (Note 18) TTL Output Load 3t1 n + 43 ns Miscellaneous Signals: X1 (Note 15) 36 29 tPW X1 Pulse Width HIGH (Note 12) TTL Output Load on CLK 35 ns 30 tPW X1 Pulse Width LOW (Note 12) TTL Output Load on CLK 35 ns 32 tPD X1↑ to CLK↑ TTL Load 32 ns 33 tPD X1↓ to CLK↓ TTL Load 32 ns Am7968/Am7969-125 Military AMD Am7969-125 Military TAXIchip Receiver (Notes 13, 14, 22) No. Parameter Symbol Bus Interface Signals: Parameter Description Test Conditions Min Max Unit DO0–DO7, DO8/CO3, DO9/CO2, CO0–CO1, DSTRB, CSTRB, IGM, CLK, CNB, VLTN 35 tP CLK Period (Note 24) 36 tPD Data Valid to STRB↑ Delay TTL Output Load 37 tPD CLK↓ to STRB↑ TTL Output Load 38 tPD CLK↑ to STRB↓ TTL Output Load t35 n –7 ns 38a tPD STRB↑ to CLK↑ (Note 23) TTL Output Load 3t35 n –14 ns 39 tPD CLK↓ to Data Valid Delay TTL Output Load 40 tPW STRB Pulse Width HIGH TTL Output Load 5t35 2n 41 tPW CLK Pulse Width HIGH TTL Output Load 5t35 n –15 ns 42 tPW CLK Pulse Width LOW TTL Output Load 5t35 2n –15 ns 43 tPD SERIN to CLK↓ Delay TTL Output Load t35 2t35 2n +17 n +26 ns 8n 25 n 2t35 n ns ns 2t35 n +15 - ns t35 n +23 ns 5t35 n ns Serial Interface Signals: SERIN+, SERIN– 57 tJ✝ SERIN± Peak to Peak Input Jitter Tolerance (Note 16) 5 ns Miscellaneous Signals: X1 (Note 15) 60 tPW X1 Pulse Width HIGH 35 ns 61 tPW X1 Pulse Width LOW 35 ns Note: CLK (pin 19) must be connected to CNB (pin 24). Am7968/Am7969-125 Military 37 AMD Notes:* 1. For conditions shown as Min or Max use the appropriate value specified under operating range. 2. The clock fall to serial output delay is typically 3 bit times. 4. Not more than one output should be shorted at a time. Duration of the short circuit test should not exceed one second. 5. If the CNB↑ to CLK↑ setup time is violated, IGM will stay LOW. 6. Voltage applied to either SERIN± pins must not be above VCC nor below +2.5 V to assure proper operation. 7. t4 guarantees that data is latched. ACK (t11) timing may not be valid. 8. If t11 is not met, ACK response and timing are not guaranteed, but data will still be latched on STRB↑ (see t4). 9. Measured with device in Test mode while monitoring output logic states. 10. For the TAXI Transmitter, “n” is determined by the following table: DMS TLS OPEN GND GND/VCC OPEN VCC GND/VCC Open or 1 2 VCC OPEN GND/VCC “n” n = 1; 8 Bit Test Mode 2 8 Bit n = 10; Local/Test Mode 1 9 Bit n = 1; Test Mode 2 9 Bit n = 11; Local/Test Mode 1 10 Bit Test Mode 2 10 Bit n = 12; Local/Test Mode 1 n = 1; 11. t6 (Internal Byte Boundary to CLK↓) is created by the variation of internal STRB propagation delays relative to internal byte boundaries over temperatures and VCC. The internal byte boundary determines the byte in which data will come out (SEROUT±). If STRB occurs before the byte boundary, then the data will be sent out two bytes later. If STRB occurs after the byte boundary, then the output data will be delayed by one additional byte. 12. X1 Pulse Width is measured at a point where CLK output equals t2 or t3. 13. For the TAXI Transmitter, ‘Data’ is either DI0 – DI7, DI8/CI3, DI9/CI2, CI0 – CI1. For the TAXI Receiver, ‘STRB’ is either CSTRB or DSTRB and ‘Data’ is either DO0 – DO7, DO8/CO3, DO9/CO2, CO0 – CO1. 14. For the TAXI Receiver, ‘n’ is determined by the state of the DMS and SERIN– inputs. When SERIN– is held below VTHT max or left open, n=1. When SERIN– is held above 0.25 V and when: DMS SERIN– < VTHTMAX or OPEN n = 1; > 2.5 V n = 10; GND < VTHTMAX or OPEN VCC > 2.5 V Open or 1 2 VCC 38 “n” 8 Bit Test Mode 8 Bit Local Mode 9 Bit n = 1; Test Mode 9 Bit n = 11; Local Mode < VTHTMAX or OPEN n = 1; > 2.5 V n = 12; Am7968/Am7969 10 Bit Test Mode 10 Bit Local Mode AMD 15. Jitter on X1 input must be less than ±0.2 ns to ensure that automatic test equipment can properly measure device switching characteristics. The X1 input frequency will determine the byte rate reference for the receiver byte clock. 16. This specification is the sum of Data Dependent Jitter, Duty Cycle Distortion, and Random Jitter. 18. ACK delay is determined by t13 when the input latch is empty or by t15 when the latch is full (Busy mode). Also note that ACK will not rise if STRB does not remain HIGH until ACK rises. 19. If t47A (CNBØ to CLK≠ setup) is violated, then output data will occur one byte time later. 20. All timing references are made with respect to +1.5 V for TTL–level signals or to the 50% point between VOH and VOL for ECL signals. ECL input rise and fall times must be 2 ns ± 0.2 ns between 20% and 80% points. TTL input rise and fall times must be 2 ns between 1 V and 2 V. 21. Device thresholds on the SERIN (+/–) pin(s) are verified during production test by ensuring that the input threshold is less than VIHS (min) and greater than VILS (max). The figure below shows the acceptable range (shaded area) for the transition voltage. VCC VCC = 0.88 V VCC = 1.165 V Input threshold transition voltage VCC = 1.475 V VCC = 1.81 V 22. Switching Characteristics are tested during 8-bit local mode operation. 23. The limit for this parameter cannot be derived from t37 and t42. 24. This specification does not apply during reacquisition when CLK stretch can occur. ✝ This parameter is guaranteed but is not included in production tests. * Notes listed correspond to the respective references made in the DC Characteristics and the Switching Characteristics tables. Am7968/Am7969 39 AMD SWITCHING TEST CIRCUITS VCC R1 VOUT VOUT 50 Ω CL 2.4K 30 pF VCC – 2 V 07370F-14 07370F-15 TTL Output Load ECL Output Load Notes: 1. R1 = 500 Ω for the IOL = 8 mA Notes: 1. CL < 3 pF includes scope probe, wiring and stray capacitances without device in test fixture. 2. All diodes IN916 or IN3064, or equivalent 3. CL = 30 pF includes scope probe, wiring and stray capacitances without device in test fixture. 4. AMD uses constant current (A.T.E.) load configurations and forcing functions. This figure is for reference only. 40 2. AMD uses Automatic test equipment load configurations and forcing functions. This figure is for reference only. Am7968/Am7969 AMD SWITCHING TEST WAVEFORMS 3.0 V 2.0 V 1.5 V 1.0 V 0V 2 ± 0.2 ns 2 ± 0.2 ns 07370F-16 TTL Input Waveform VCC – 0.9 V 80% 50% 20% VCC – 1.7 V 2 ± 0.2 ns 2 ± 0.2 ns 07370F-17 ECL Input Waveform KEY TO SWITCHING WAVEFORMS WAVEFORM INPUTS OUTPUTS Must Be Steady Will Be Steady May Change from H to L Will Be Changing from H to L May Change from L to H Will Be Changing from L to H Don’t Care Any Change Permitted Changing State Unknown Does Not Apply Center Line is High Impedence “Off” State Am7968/Am7969 KS000010 41 42 Am7968/Am7969 9 13 6 4 11 14 10 3 1 29 Note: 2. The clock fall to serial output delay is typically 3 bit times. SEROUT- SEROUT+ ACK STRB DATA OR COMMAND DATA IN CLK X1 30 2 5 Note 2 12 Am7968 TAXIchip Transmitter AC 32 33 15 23 23 22 24 26 27 07370F-18 24 27 26 AMD SWITCHING WAVEFORMS Am7968/Am7969 43 39 1 1 37 1 36 1 42 1 0 40 45 Note 1 DATA=XX 38A 0 DATA=02 35 38 0 47B 48 1 60 41 0 57 46 1 49 0 Note 2 0 1 0 1 DATA=02 0 DATA=34 0 Note 1 1 0 1 1 0 0 0 0 DATA=34 1 DATA=SYNC (JK) Am7969 TAXIchip Receiver AC This diagram illustrates how timing relationships are measured. Functional operation is clarified on following pages. Notes: 1. IGM rises because CNB = 1 and SERIN = first half of non-sync byte. 2. IGM falls because CNB falls. 3. IGM falls because SERIN = first half of sync byte. IGM CNB DSTRB OR CSTRB STRB DO M OR CO N DATA OUT CLK SERIN+ X1 61 0 44 Note 3 0 1 1 1 1 1 0 0 1 COMMAND=0 47A 1 DATA=02 0 0 1 1 DATA=02 0 07370F-19 0 AMD SWITCHING WAVEFORMS 43 44 Am7968/Am7969 SYNC 11 000 100 0 1 SYNC DATA 1 DATA 1 DATA 2 DATA 2 SYNC 11 0001 00 01 SYNC 11 000 100 0 1 SYNC DATA 2 DATA 4 DATA 1 DATA 3 (NOTE 1) DATA 4 5 DATA 3 DATA 3 4 DATA 2 3 *Internal Signals STRB to SEROUT Timing (8-Bit Local Mode) Note: 1. The input Latch is BUSY when the second STRB comes in; the internal STRB-ACK is delayed until the next CLK window. Refer to Figure 3. SYNC SYNC NRZ DATA* SEROUT SERIAL OUTPUT DATA SYNC 11 000 100 0 1 SYNC SHIFTER* DATA 2 DATA 2 2 DATA 1 DATA 1 DATA 1 1 ENCODER LATCH* INPUT LATCH* ACK OUT STRB INPUT DATA/COMMAND INPUT CLK OUTPUT INT CLK* TAXIchip Transmitter 07370F-20 DATA 3 DATA 3 DATA 3 DATA 4 6 AMD SWITCHING WAVEFORMS Am7968/Am7969 CSTRB OUT COMMAND OUT DSTRB OUT DATA OUT DECODER LATCH* CLK OUT = CNB NRZ DATA* SERIN SERIAL DATA INTERNAL CLOCK* SYNC NO CHANGE DATA N SYNC 3 DATA 1 DATA 1 DATA 1 4 CMD 1 CMD 1 CMD 0 NO CHANGE TAXIchip Receiver Timing (8-Bit Local Mode) NO CHANGE DATA N-1 DATA N-2 NO CHANGE DATA N 2 SYNC 11 0 00 10 0 0 1 DATA N-1 1 DATA N DATA N 11 0 0 0 1 0 0 0 1 TAXIchip Receiver NO CHANGE DATA 1 CMD 1 5 DATA 3 DATA 3 07370F-21 CMD 1 NO CHANGE DATA 3 6 DATA 4 DATA 4 AMD SWITCHING WAVEFORMS 45 46 Am7968/Am7969 DATA N DATA N-1 NO CHANGE DATA N SYNC (Note 7) (Note 6) DATA N SYNC (Note 5) (Note 4) DATA 1 DATA 1 (Notes 1 & 2) NO CHANGE (Lost) 11 0 00 10 0 0 1 SYNC 11 0 0 0 1 0 0 0 1 NO CHANGE SYNC DATA 1 (Note 3) DATA 2 DATA 2 DATA 1 NO CHANGE DATA 2 DATA 3 DATA 3 TAXIchip Receiver Timing (8-Bit Mode/Local) Showing External Effect of SYNC Error Notes: *Internal Signals 1. Sync detected in Shifter, but not synchronized with internal state machine. 2. State machine re-cycled to new sync position. 3. Clock output delayed to new position. 4. The LOW time or HIGH time gets stretched depending on what state of the internal machine is reset. 5. IGM rises at the 6.5th state of the state machine. 6. Strobe falls at the rising edge of the clock out. 7. Strobe may be shifted one bit time if the state machine is reset at state 1. DSTRB OUT DATA OUT CSTRB OUT COMMAND OUT DECODER LATCH* IGM CLK OUT = CNB NRZ DATA* SERIN SERIAL DATA DATA N INTERNAL CLOCK* 07370F-22 DATA 2 NO CHANGE DATA 3 * * * * * * 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 0 1 23 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 56 7 8 9 0 1 2 3 4 5 6 7 8 9 AMD SWITCHING WAVEFORMS Am7968/Am7969 *Internal Signals DSTRB OUT DATA OUT CSTRB OUT COMMAND OUT DSTRB OUT DATA OUT CSTRB OUT COMMAND OUT IGM TAXI #1 = CNB TAXI #2 CNB TAXI #1 = 1 NO CHANGE NO CHANGE NO CHANGE NO CHANGE 3 1 CLK OUT SYNC DATA N NRZ DATA SYNC NO CHANGE NO CHANGE NO CHANGE NO CHANGE 4 DATA 1 DATA 1 DATA N NO CHANGE DATA N-1 NO CHANGE TAXIchip Receiver Timing (8-Bit Cascade Mode) NO CHANGE NO CHANGE NO CHANGE NO CHANGE 2 11 0 0 0 1 0 0 0 1 1 1 0 0 0 1 0 0 0 1 SYNC DATA N 11 0 0 0 1 0 0 0 1 1 1 0 0 0 1 0 0 0 1 SERIN SERIAL DATA INTERNAL CLOCK* TAXI #1 TAXI #2 TAXIchip Receiver NO CHANGE NO CHANGE NO CHANGE COMMAND 0 5 DATA 2 DATA 2 07370F-23 NO CHANGE NO CHANGE NO CHANGE NO CHANGE 6 SYNC 11 0 0 0 1 0 0 0 1 SYNC 11 0 0 0 1 0 0 0 1 AMD SWITCHING WAVEFORMS 47 AMD PHYSICAL DIMENSIONS* CD 028 28-Pin Ceramic DIP (measured in inches) 1.435 1.490 .098 MAX .565 .605 1 .050 .065 .005 MIN .100 BSC TOP VIEW .590 .615 .008 .012 .160 .220 .015 .060 .125 .160 .150 MIN 0° 15° .700 MAX .015 .022 SIDE VIEW 06837D BZ13 CD 028 1/8/91 c dc END VIEW PL 028 28-Pin Plastic Leaded Chip Carrier (measured in inches) .042 .048 .020 MIN .050 REF .042 .056 .025 R .045 .026 .032 .013 .021 .300 .390 REF .430 .485 .450 .495 .456 .009 .015 .450 .456 .485 .495 TOP VIEW .165 .180 .090 .120 06751F BV 8 PL 028 12/31/91 c dc SIDE VIEW *For reference only. All dimensions measured in inches. BSC is an ANSI standard for Basic Space Centering. 48 Am7968/Am7969 AMD PHYSICAL DIMENSIONS CLT028 28-Pin Ceramic Leadless Chip Carrier (measured in inches) .300 BSC .150 BSC .050 BSC .022 .028 .300 BSC .150 BSC .006 .022 SIDE VIEW .015 MIN .045 .055 .054 .065 .064 .075 TOP VIEW .442 .458 .040 X 45° REF. (3x) (OPTIONAL) .442 .458 .430 MAX .430 MAX PLANE 2 PLANE 1 07703D CS47 CLT 028 04/28/94 ae INDEX CORNER .020 X 45° REF. (OPTIONAL) BOTTOM VIEW Am7968/Am7969 49 TAXIchipTM Integrated Circuits Technical Manual 1.0 INTRODUCTION Modern electronic systems move data from point-to-point across physical layer boundaries using either serial or parallel data links. Parallel data links provide fast data transfers and are compatible with most computer architectures. However, conventional parallel data links are burdened with cost/performance issues such as costly multi-conductor cables, crosstalk, RFI, bit-to-bit skew and other concerns associated with multiple wire interfaces. Serial data links, although simpler and less costly, have not provided sufficient bandwidth to compete with the high data transfer rates of parallel links. Recent technological advances have altered the cost performance trade-off between serial and parallel data transfer techniques. A new chip set from Advanced Micro Devices offers a high performance integrated alternative to traditional serial/parallel data transfer techniques. The TAXlchip set (Transparent Asynchronous Xmitter-Receiver Interface) provides the means to establish a transparent high speed serial link between two high performance parallel buses. The TAXlchip set consists of a Transmitter, which takes parallel data and transmits it serially at up to 175 MHz, and a Receiver, which converts the serial data stream back to parallel form. TAXlchips provide a simple parallel interface through a high speed serial link, while maintaining the data bandwidth required by the system. 1.1 The Am7968 TAXI Transmitter The TAXITM Transmitter consists of an input latch, an encoder, a parallel to serial shift register, a multiplying Phase Locked Loop (PLL), and some control logic (Figure 1-1). Data are input to the latch, encoded, and shifted out at the serial data rate. The encoding used is the efficient 4B/5B scheme specified for the ANSI X3T9.5 Fiber Distributed Data Interface (FDDI specification). This encoding divides an 8-bit byte into two, 4-bit nibbles. Each nibble is encoded into a 5-bit symbol. The 10-bit encoded byte is formatted into an NRZI data stream for output to the media. This 4B/5B encoding is 80% efficient, using a 125 Mbaud transmission rate to send 100 Mbps of data. The Am7968 Transmitter has differential pseudo-ECL (referenced to +5 V) outputs which can drive 50 Ω lines. This capability makes it easy to directly interface with shielded twisted pair or coaxial cables. The pseudo-ECL outputs are also compatible with the ECL interface of optical components used to drive fiber optic cable. In addition to providing high bandwidth and low attenuation, fiber optic data transmission also offers noise immunity, eliminates RFI and provides data security. Declining optical components costs are bringing the advantages of fiber optic data transmission to an ever wider range of applications, from process control to avionics. The TAXlchip set is the ideal complement for fiber optic interfaces. 50 Publication# 12330 Rev. E Issue Date: April 1994 Amendment /0 AMD Figure 1-1 Am7968 TAXI Transmitter Block Diagram Data Command N Strobe (STRB) Acknowledge (ACK Strobe & Acknowledge M Input Latch X1 X2 Oscillator and Clock Gen. Encoder Latch Clock (CLK) Data Mode Select (DMS) Test Serial In (TSERIN) Data Encoder Shifter Serial Interface Media Interface (SEROUT+) Serial Out + (SEROUT–) Serial Out – Test/Local Select (TLS) 12330E-1 Note: N can be 8, 9, or 10 bits. Total of N + M = 12. Figure 1-2 Am7969 TAXI Receiver Block Diagram (X1) (SERIN+) Serial In + (SERIN–) Serial In – Media Interface Oscillator and Clock Gen. Shifter (X2) PLL Clock Generator Decoder Latch (DMS) Data Mode Select Data Decoder Byte Sync Logic Output Latch N (VLTN) Violation M (CNB) Catch Next Byte (IGM) I-Got-Mine (CLK) Clock (DSTRB) Data Strobe Data Command (CSTRB) Command Strobe Note: N can be 8, 9, or 10 bits. Total of N + M = 12. TAXIchip Integrated Circuits Technical Manual 12330E-2 51 AMD 1.2 The Am7969 TAXI Receiver The TAXI Receiver (Figure 1-2) accepts the encoded data stream into a serial-to-parallel converter, decodes and outputs the received data with an accompanying strobe. An on-chip data tracking PLL performs the necessary clock recovery from the input serial data stream. 2.0 USING THE TAXIchip SET The current TAXlchip set has a maximum effective data throughput of 140 Mbps, over ten times faster than the data rate of conventional RS-422 drivers and receivers. The TAXlchip set has a frequency range of 40 MHz to 175 MHz corresponding to a parallel data transfer rate of 4 to 17.5 Mbyte/sec. Data rates of less than 4 Mbyte/sec are accommodated by the automatic insertion of Sync symbols in the absence of new data or commands. The TAXI Transmitter accepts parallel input data with a simple Strobe/Acknowledge handshake, while the Receiver asserts an output strobe when data is available at its parallel outputs. The high speed serial-to-parallel conversions and data encoding/decoding are transparent to the user, who sees only an effective parallel transfer rate of up to 17.5 Mbyte/sec (see Figure 2-1). Appendix C, TAXI TIP # 89-07 addresses the use of synchronous and asynchronous strobes. It is important to note here that the user is not forced to supply data at the maximum byte rate equivalent of the serial data rate. Data or Commands are sent down the serial link only when the user strobes the Transmitter. For those byte clock cycles when the Transmitter is not strobed, it automatically sends a special Sync symbol down the link. The Sync symbol is a unique bit pattern which cannot be confused with any other valid pattern. For this reason, Sync is used to establish byte framing at the Receiver. See Appendix C, TAXI TIP # 89-03 proper use of TAXI Sync. It also keeps the link active when no other symbols are being sent, maintaining Receiver PLL lock. Sync will not over-write data already present in the receiver’s output data latch. The serial rate is, therefore, truly transparent to the user; at input data rates less than the equivalent serial bit rate, the TAXI Transmitter will fill the gaps with Syncs, which do not disturb Receiver output data. 2.1 Data and Command The Am7968 TAXI Transmitter and the Am7969 TAXI Receiver interface directly to an 8, 9, or 10 bit data bus. Each TAXlchip has 12 parallel interface lines which are designated as either Command or Data bits. Command bits implement user defined system supervisory functions, such as Initialize Your System, Re-try, Halt, or Error which cannot be embedded in the ordinary data path. 52 TAXIchip Integrated Circuits Technical Manual AMD Figure 2-1 Basic TAXIchip Operation 6. The Data comes out the RX and Data Strobe is Raised 1. Parallel Data is Entered by the User 4. The Serial Data is Sent Out Data Strobe Data In Am7968 Transmitter Am7969 Receiver Data Out Strobe Acknowledge 2. The Data is Strobed in by the User 3. The Data is Encoded and then Converted into a Serial Stream 5. The Receiver takes the Serial Data and Converts it Back to Parallel Data and then Decodes it 12330E-3 Three different widths are possible: 8 Data and 4 Command bits, 9 Data and 3 Command bits, and 10 Data and 2 Command bits. This choice of data and control bus widths allows flexibility to meet different system bus width requirements, while providing the capability of merging control and data into a common data stream. 2.2 Operational Modes: Local, Cascade and Test A TAXIchip set point-to-point link can be operated in one of three modes: Local, Cascade, or Test. Local mode consists of a single Transmitter communicating with a single Receiver over the serial medium. Cascade mode for Am7968/7969-125 consists of a single Transmitter driving two or more daisy chained (cascaded) Receivers over a single serial medium. Cascade Operation for Am7968/Am7969-175 consists of a single Transmitter driving a single Receiver as shown in Appendix C, TAXI TIPs #13 and #14. Cascade mode permits direct interface with 16-bit, 32-bit and wider busses. The link may be operated in any of the above modes using the TAXl’s internal PLL for bit rate generation and tracking, or the link may be run in Test Mode with external frequency multiplying and data tracking PLLs. 3.0 DATA ENCODING, VIOLATION AND SYNCS 3.1 Data Encoding Any form of serial data transmission requires some form of encoding before the data are output to the transmission medium. Encoding is the process of converting a set of m data bits to a set of n code bits. The purpose of the encoding operation is to include clock information in the data stream. Without this timing information, the Receiver would not be able to distinguish adjacent bits of the same value. For example, if we transmit a thousand ONEs followed by a ZERO, the Receiver might detect only 999 ONEs, or perhaps 1001 ONEs, followed by one or two ZEROs. An accurate clock is needed to tell the Receiver when to sample the incoming bit stream to determine if the bit is a ONE or a ZERO. Since the Transmitter and Receiver have only one data path between them, the clock (timing) information must be included in the serial data stream. TAXIchip Integrated Circuits Technical Manual 53 AMD The TAXIchip set uses 4B/5B or 5B/6B coding, so that m is either 4 or 5, and n is either 5 or 6. In 8-bit mode, each 4-bit nibble is presented to one of two 4B/5B encoders to produce 10 code bits, 5 from each encoder. In 9-bit mode, the more significant 4B/5B encoder is replaced with a 5B/6B encoder to yield a total of 11 code bits. In 10-bit mode, both encoders are replaced with 5B/6B encoders, yielding a total of 12 code bits. The TAXIchip set can encode two types of data: either 8, 9, or 10-bit Data, or Commands. Commands are special symbols which are typically used as control functions at the receiving end of the link. Commands may be four, three, or two bits wide, corresponding to a Data width of eight, nine, or ten bits respectively. The presence of any non-ZERO bits on the Command inputs when STRB is asserted will cause a Command symbol to be sent, regardless of the state of the Data lines. The Command bits are encoded into 10,11, or 12 bit groupings which are special cases of the 4B/5B or 5B/6B code not used for Data. In the absence of Data or Commands, a unique symbol (Sync) is automatically generated to maintain link synchronization. If the user has not supplied a STRB during a byte, a Sync symbol is sent. NRZI stands for Non-Return to Zero, Invert on one. Logic ONEs are indicated by a transition, while logic ZEROs produce no transition. Further encoding the 4B/5B encoded data in this way ensures that the Receiver PLL will get a transition at least every three clock times (the maximum number of ZEROs in the 4B/5B code). Since a PLL can make a phase comparison and initiate a correction only at a transition, maximizing the number of transitions helps to keep the loop solidly in lock. 54 TAXIchip Integrated Circuits Technical Manual AMD Table 3-1 TAXlchip Encoder Patterns 4B/5B ENCODER SCHEME 4-Bit 5-Bit HEX Binary Encoded Data Data Symbol 0 0000 11110 1 0001 01001 2 0010 10100 3 0011 10101 4 0100 01010 5 0101 01011 6 0110 01110 7 0111 01111 8 1000 10010 9 1001 10011 A 1010 10110 B 1011 10111 C 1100 11010 D 1101 11011 E 1110 11100 F 1111 11101 5B/6B ENCODER SCHEME 5-Bit 6-Bit HEX Binary Encoded Data Data* Symbol 00 00000 110110 01 00001 010001 02 00010 100100 03 00011 100101 04 00100 010010 05 00101 010011 06 00110 010110 07 00111 010111 08 01000 100010 09 01001 110001 0A 01010 110111 0B 01011 100111 0C 01100 110010 0D 01101 110011 0E 01110 110100 0F 01111 110101 10 11 12 13 14 15 16 17 18 19 1A 1B 1C 1D 1E 1F 10000 10001 10010 10011 10100 10101 10110 10111 11000 11001 11010 11011 11100 11101 11110 11111 111110 011001 101001 101101 011010 011011 011110 011111 101010 101011 101110 101111 111010 111011 111100 111101 * Notes: HEX data is parallel input data which is represented by the 4- or 5-bit binary data listed in the column to the immediate right of HEX data. Binary bits are listed from left to right in the following order. 8-Bit Mode: D7, D6, D5, D4, (4-Bit Binary), and D3, D2, D1, D0, (4-Bit Binary) 9-Bit Mode: D8, D7, D6, D5, D4, (5-Bit Binary), and D3, D2, D1, D0, (4-Bit Binary) 10-Bit Mode: D8, D7, D6, D5, D4, (5-Bit Binary), and D9,D3, D2, D1, D0, (5-Bit Binary) Serial bits are shifted out with the most significant bit of the most significant nibble coming out first. Table 3-2 TAXIchip Command Symbols TAXIchip Integrated Circuits Technical Manual 55 AMD Am7969 Receiver Am7968 Transmitter Command Input HEX 8-Bit Mode 0 No STRB (Note 1) 1 2 3 4 5 6 7 8 (Note 3) 9 A (Note 3) B C D (Note 3) E (Note 3) F (Note 3) 9-Bit Mode 0 No STRB (Note 1) 1 2 3 4 5 6 7 10-Bit Mode 0 No STRB (Note 1) 1 2 3 Command Output Binary Encoded Symbol Mnemonic HEX Binary 0000 XXXXX XXXXX Data No STRB (Note 1) 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 11000 10001 JK (8-bit Sync) No Change (Note 2) 0 No Change (Note 2) 0000 11111 11111 01101 01101 01101 11001 11111 00100 01101 00111 11001 00111 11001 11001 00100 00100 00100 11111 00100 00000 00111 00111 00111 11001 00000 00100 00000 11111 00000 00000 I I TT TS IH TR SR SS HH HI HQ RR RS QH QI QQ 1 2 3 4 5 6 7 8 9 A B C D E F 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 000 XXXXXX XXXXX Data No STRB (Note 1) 001 010 011 100 101 110 111 011000 10001 LK (9-bit Sync) No Change (Note 2) 0 No Change (Note 2) 000 111111 11111 011101 01101 011101 11001 111111 00100 011101 00111 111001 00111 111001 11001 I’I T’T T’S I’H T’R S’R S’S 1 2 3 4 5 6 7 001 010 011 100 101 110 111 00 XXXXXX XXXXXX Data No STRB (Note 1) 01 10 11 011000 100011 111111 111111 011101 011101 011101 111001 No Change (Note 2) LM (10-bit Sync) 0 I’I ’ T’T’ T’S’ 1 2 3 No Change (Note 2) 00 01 10 11 Notes: 1. Command pattern Sync cannot be explicitly sent by Am7968 Transmitter with any combination of inputs and STRB, but is used to pad between user data. 2. A strobe with all Os on the Command input lines will cause Data to be sent. See Table 3-1. 3. While these Commands are legal data and will not disrupt normal operation if used occasionally, they may cause data errors if grouped into recurrent fields. Normal PLL operation cannot be guaranteed if one or more of these Commands is continuously repeated. 56 TAXIchip Integrated Circuits Technical Manual AMD 3.2 Violation Logic The TAXI Receiver logic has been designed to detect the most common types of transmission errors. It detects these errors by completely decoding the incoming data patterns, and recognizes the following types of VIOLATIONS: 1. Illegal, reserved or unused data patterns (pure Violations). 2. Unused COMMAND combinations. 3. COMMAND in Upper half and DATA in Lower half pattern. 4. DATA in Upper half and COMMAND in Lower half pattern. Type 1 and 2 VIOLATIONS are decoded and interpreted as either DATA or COMMAND outputs with the appropriate STRB output. Type 3 & 4 VIOLATIONS are decoded as COMMAND outputs with a CSTROBE output (even though one half would have been transformed DATA/COMMAND or COMMAND/DATA by an error), since there is no information available to the TAXI Receiver to indicate where the error lies. The user needs to be aware of this possible transposition (possible with all four types of VIOLATION), since the system must account for it. VIOLATION will always be the flag for these detectable errors. This method of detection is not 100% effective. As Appendix B shows, it will detect approximately 50% of the possible double bit errors in Data. Double bit errors in Command will be detected 99.8% of the time or more, depending upon the pattern width. Appendix B contains a more detailed treatment of the efficiency of the violation logic for the various data bit modes. The method of detecting violations, is effective enough to be used to give an early warning of transmission problems before the host’s error detection system would detect the errors. It should not be used alone in fault sensitive systems, since it misses a significant number of transmission errors which cause one valid DATA pattern to alias to another VALID DATA PATTERN. 3.3 TAXI PLL Characteristics The Phase Locked Loop in the TAXI Receiver is used to recover the data encoded in the serial bit stream sent by the TAXI Transmitter. In order to ensure accurate data recovery, the Receiver PLL must lock on to the underlying code rate of the Transmitter, and must track minor changes in frequency and phase while rejecting noise superimposed on the bit stream. This noise includes both amplitude and phase/frequency disturbances. Amplitude variations are dealt with in the Receiver’s input amplifier (SERIN+/-), and are not passed through to the PLL, except for phase effects. Phase/frequency noise, or jitter, can come from many sources, and can have many different characteristics. Jitter can be introduced by the Transmitter, the Receiver, the media interface or by the media itself. Examples of media induced jitter include reflections and edge perturbations caused by improper line termination, pulse width spreading due to frequency dependent cable attenuation, and pulse dispersion caused by fiber optic cable effects. Examples of media interface jitter include low light effects in optical receivers and pulse width distortion caused by baseline shift (changing DC offset) in AC coupled amplifiers. The TAXI PLL has been optimized to allow correct data recovery in the presence of the largest jitter possible. To this end, the PLL parameters, most notably loop bandwidth, have been chosen to enhance the jitter tolerance of the TAXI Receiver. TAXIchip Integrated Circuits Technical Manual 57 AMD This optimization is at the expense of lock-up time. In TAXI systems, lock-up time is relatively unimportant, since the system must achieve lock only during system power-up. If the PLL achieves proper lock within a few tens, or even hundreds of microseconds, its startup will be similar to the start-up characteristics of the system power supply. The actual time to lock begins during power-up, when both Transmitter and Receiver are marginally powered and the entire link is marginally functional. Transient effects other than PLL characteristics, which typically occur during power-up, can either lengthen or shorten the apparent lock time. These effects are a function of actual implementation and are not discussed here. The discussion which follows assumes that both Transmitter and Receiver are fully powered, and that the link is fully operational. The only effects included are PLL transient effects. If there is no data on the link (if the Transmitter is off, or if there is a quiet line) the data recovery PLL will drift to its natural oscillation frequency. This frequency is determined by component values and tolerances inside the Am7969 receive PLL, and will vary slightly from both the Receiver reference frequency (at X1 of the Receiver) and the Transmitter data frequency (X1 of the Transmitter). When data appears on the line, the receive PLL must achieve phase lock from its resting frequency. The structure of the PLL used in the TAXIchip set ensures that this resting frequency will be no more than a few percent (typically less than 3%) from the reference frequency applied at X1. This is in addition to the specified Transmitter/Receiver frequency mismatch allowed by the crystal tolerance specification of +0.1%. Figure 3-1 Calculated Receiver Lock-Up Time 80 70 60 HQ JK II Lock-Up Time 50 (µs) 40 30 20 10 0 0.1 1 2 Percent Offset Frequency at 125 MHz 12330E-4 Neglecting frequency variations in the Transmitter and jitter in the data stream, the time to lock is related to the PLL loop bandwidth and damping factor, and to the transition density. The loop parameters are set by the internal component values and tolerance of the TAXIchip set. A plot of calculated lock-up time vs Transmitter to Receiver frequency offset and transition density is given in the Figure 3-1. Note that low transition density causes longer lock times. In fact, at very low transition densities (1 transition per 10 bit times of the HQ symbol), and large offset frequencies, the PLL may not be able to acquire lock at all, even though the lock equation used to produce the graph seems to indicate a solution. As the limits are approached, lock time may grow to several times the value predicted by the lock equation. 58 TAXIchip Integrated Circuits Technical Manual AMD 4.0 CLOCK GENERATION AND DISTRIBUTION The serial baud rate for the Am7968 Transmitter is derived from a byte rate frequency source. The TAXI Receiver must run at the same frequency as the TAXI Transmitter. The relationship between serial baud rate and data byte rate depends on the width of the transmitted data. For 8-bit data, the byte rate is multiplied by 10 to obtain the serial clock rate. Since the maximum operating frequency is 125 MHz and the minimum frequency is 40 MHz, the byte rate frequency range for 8-bit data is between 4.0 and 12.5 MHz. The multipliers for 9 and 10 bit data widths are 11 and 12 respectively. The following table summarizes the byte rate frequency ranges for each data width selected. Am7968/Am7969-125 Data Width PLL Multiplier Byte Rate 8 9 10 10 11 2 4.00 – 12.50 MHz 3.64 – 11.36 MHz 3.33 – 10.42 MHz Am7968/Am7969-175 Data Width PLL Multiplier Byte Rate 8 9 10 10 11 12 12.5 –17.5 MHz 11.37 – 15.90 MHz 10.42 – 14.58 MHz The source of byte rate frequency can be either from the built-in crystal oscillator or from a TTL clock signal. The maximum allowable mismatch between Transmitter and Receiver frequency sources is ±0.1%. This tolerance is derived from the PLL architecture in the TAXI Receiver, and from considerations of crystal accuracy. More information on crystal specifications and available distributors can be found in Appendix C, TAXI TIP #89-05, TAXIchip set crystal specification. When there is no incoming data, the Receiver PLL has no serial data stream to track. This situation can arise if the Transmitter has not been powered up, or if the transmission medium is disconnected. In this case the VCO will drift to a frequency determined by internal component tolerances. When data appears at the Receiver serial input, the loop must acquire lock from this resting frequency. The worst case frequency offset and the capture range of the PLL are designed to allow frequency mis-matching between Transmitter and Receiver of ±0.1%, since this accuracy is achievable with inexpensive available crystals. 4.1 TAXI Transmitter Clock Connections The byte rate frequency source drives a multiplying PLL to create an internal bit rate clock which is used for timing all internal logic. The X1 and X2 pins are used to input the byte rate frequency source to the Transmitter. Their exact usage will vary, depending on type of frequency source (crystal or external TTL) and mode of TAXI Transmitter operation (Local or Test). TAXIchip Integrated Circuits Technical Manual 59 AMD 4.1.1 Local Mode Transmitters In Local mode, X1 and X2 are the crystal oscillator inputs. The external component connections are shown in Figure 4-1. Zero temperature coefficient capacitors (type NPO) should be used for good temperature stability. Typical Crystal Specification Fundamental Frequency Resonant Mode Load Capacitor (Correlation) Operating Temperature Range Temperature Stability Drive Level (Correlation) Effective Series Resistance Holder Type Aging for 10 Years Figure 4-1 4.0 MHz –17.5 MHz +0.1% Parallel 30 pF 0°C to 70°C ±1.00 ppm 2 mW 25 Ω (max) Low Profile ±10 ppm TAXlchip Crystal Connection RESET Am7968 or, Am7969 X1 X2 C C 12330E-5 C = 150 pF for a 12.5 – 17.5 MHz Crystal, 220 pF for a 4 MHz–12.5 MHz Crystal The Transmitter may also be run in local mode by applying a TTL frequency source to X1 and grounding X2. The TTL source may be either from a crystal oscillator module, or from a neighboring TAXI Transmitter CLK output. In local mode, CLK is the buffered output of the internal crystal oscillator. Connecting the CLK output of a TAXI Receiver directly to the X1 input of a TAXI Transmitter is not recommended, because the Transmitter’s clock stability and jitter requirements are not satisfied by the Receiver CLK output. 4.2 TAXI Receiver Clock Connections The considerations and connections for the TAXI Receiver are similar to those for the TAXI Transmitter. The Receiver X1 and X2 inputs connect to an on-chip oscillator, whose frequency is determined by a parallel resonant crystal, or is driven by an external TTL frequency source. The oscillator provides the reference, which sets the expected center frequency for the data synchronizing PLL. The synchronizing PLL tracks the incoming data and generates a bit clock from the serial data stream. All of the internal TAXI Receiver logic, including the logic that generates the CLK output, runs on this bit rate clock. This recovered clock is as stable as possible in both frequency and phase, as it tracks the incoming data stream. In addition to the bit synchronization accomplished by the PLL, the logic will maintain byte synchronization (framing) with the incoming data 60 TAXIchip Integrated Circuits Technical Manual AMD using the Sync symbol to define byte boundaries. If the byte boundaries must be re-aligned (on power-up or re-acquisition of signal), the logic will ensure that the CLK is stretched (never shortened) upon re-sync to the new byte alignment. Due to this behavior, the CLK output from the Receiver is not suitable as a direct frequency reference for another TAXI Transmitter or Receiver. CLK is intended to be used by the host system as a clock synchronous with the received data. Figure 4-2 Cascaded Receiver Clock Connections From Serial Media SERIN– SERIN+ RX1 VCC SERIN– SERIN+ RX2 DMS Am7969 (Primary Receiver) CNB X2 RX3 DMS Am7969 IGM CLK SERIN– SERIN+ CNB X1 DMS Am7969 IGM CNB X2 X1 12.5 MHz Crystal OSC IGM N/C X2 X1 12330E-6 4.2.1 Cascade Mode Receivers (Am7969-125 Only) When using an on-board TTL clock source, Receivers which are in Cascade mode should have their X1 pin tied to the Crystal Oscillator and their X2 pin grounded. Figure 4-2 shows a typical cascaded Receiver clock connection. The frequency source for the Local mode Receiver should be either a crystal oscillator (as shown) or another external TTL source. It should not be the CLK output of another Receiver. As discussed above, the CLK output from the Receiver is not suitable as a frequency source for other TAXI Receivers. 5.0 INTERFACING WITH THE SERIAL MEDIA The Am7968/Am7969 TAXlchip set is capable of providing a high speed point-to-point serial link over fiber-optic, coaxial, or twisted pair media. The choice of the appropriate medium depends primarily on line length and data rate. This chapter discusses the issues involved in media choice and the requirements for driving different types of media. Any TAXIchip set to media interface design must first take into account the electrical properties of the TAXI Transmitter and TAXI Receiver. The Transmitter serial output drivers are open emitter, emitter followers which generate pseudo-ECL (PECL) levels when terminated by pull-down resistors to a voltage more negative than V OL. PECL is ECL referenced to the +5 V supply, so that VOH = (5–0.8) and VOL = (5–1.8) volts. A safe termination voltage which guarantees meeting VOL is 3 V or less. The Receiver input is a long-tailed pair which will switch on 50 mV differential input voltage, with a large TAXIchip Integrated Circuits Technical Manual 61 AMD common mode range. The average DC value of the input signal is therefore relatively unimportant. There are three broad classes of TAXl-to-media interface: 1. Very short (<3″ link length), usually DC coupled. 2. Terminated, DC coupled. 3. Terminated, AC coupled. The short link is typical of a TAXIchip set to optical components connection. The terminated cases are used for driving cables, also optical or other components with incompatible power supply and/or logic level requirements may sometimes need circuits and layout that exceed 3″. 5.1 Very Short Link, DC Coupled For DC coupled inter-connections in which the distance between the serial pins and the next device is less than 3″, transmission line terminations are not necessary. All that is required is an appropriate PECL pull-down resistor, RE. Elimination of reflections is not required for these short line lengths because the round-trip propagation is significantly less than the 2 ns TAXIchip set rise and fall time. The effect of media mismatch in this case is distortion and slowing of the transition due to the addition of the reflection to the still changing edge. Figure 5-1a Standard Load Circuit IOH VOH = 4.1 V 50 Ω VCC –2 V = 3 V Figure 5-1b 12330E-7 Pull-Down with IOH Matched to Standard Load C VOH = 4.1 V IOH RE 12330E-8 The lower limit for RE is that value which produces the maximum value of l OH. In a standard PECL load circuit (Figure 5-1a) lOH max is given by: (VOH – (VCC –2))/50 = (4.1–3)/50 = 22 mA If we return RE to ground instead of 3 V (Figure 5-1b), the minimum value of RE becomes 4.1 V/22 mA, or 186 Ω. Reflections due to mismatch can be minimized by locating the pull-down resistor at the end of the line, rather than the source. A mismatched line termination will give a reflection coefficient less than one while leaving the end of the line open will give a reflection coefficient of one (maximum reflection). Note that the supply voltage and logic 62 TAXIchip Integrated Circuits Technical Manual AMD level of the optical components must match those of the TAXIchip set in order for the DC connection to work. If the supply voltage or the logic levels are incompatible, an AC connection must be used. 5.2 Terminated, DC Coupled The parallel termination shown in Figure 5-2 may be used for a DC connection of a TAXI Transmitter to a TAXI Receiver. The parallel termination provides both the line termina′ tion (R1llR2 = Z0 = line characteristic impedance) and a pull-down voltage. The Thevenin equivalent of this termination is Z0 pulled down to VCC–2 V, assuring both matched termination and adequate VOL. Using VCC and a voltage divider provides pull-down voltage without the need for a separate power supply. Figure 5-2 Parallel Termination VCC TAXI TX Pseudo-ECL Driver TAXI RX R1 Copper Media SEROUT Z0 SERIN R2 VCC R1 ′ Thevenin Equivalent 12330E-9 R1 | / R2 = Z0 R2 (R1 + R2) VCC = VCC – 2 V R2 5.3 Terminated, AC Coupled AC coupling is the connection of choice for many TAXIchip set applications. The typical arrangement for an AC coupled link is shown in Figure 5-3. RE is returned to ground to provide the PECL (pseudo-ECL) pull-down for the driver. The capacitor C blocks the DC voltage, and R1 and R2 terminate the transmission line and provide a DC bias level for the Receiver. Since only AC variations are passed through the coupling capacitor, the bias level at the termination should be set to the midpoint of the signal swing expected by the Receiver input stage. Note that this bias level is not the same as that which is recommended for the DC coupled case. The minimum value of RE was previously established as 186 Ω, to avoid exceeding IOH max. The maximum value of RE must be small enough to supply the transmission line with enough current to avoid cutting off the output driver. When switching from a HIGH to the LOW state, the transmission line may cause the emitter voltage of the driver to fall more slowly than the base voltage, causing the output transistor to turn off. When the output transistor turns off, its output impedance becomes very high, causing the falling edge rate to be controlled by the external load (RE and the transmission line). This variation in edge rate cannot be tolerated until the falling edge crosses the TAXIchip Integrated Circuits Technical Manual 63 AMD threshold level of the receiver’s differential amplifier. Once the Receiver recognizes the state change, variations in the falling edge are not significant. To avoid edge rate variations due to driver turn-off, we must equate the voltage to which the driver is taken at turn-off with a point in the logic swing which will guarantee that the Receiver changes state. Since PECL logic swings are 800 mV, we may safely choose a 500 mV change at the driver (100 mV past the midpoint) as a guaranteed state change at the Receiver. If the driver turns off instantly, we require the voltage divider formed by RE and Z0 to produce a 500 mV change from VOH. We can write: VOH RE/(RE + Z0) = VOH – 0.5 4.1 x RE/(RE + Z0) = 3.6 RE = 7.33 Z0 As a general rule, we may then say that: 186 < RE < 7.33 Z0 Figure 5-3 Pull-Down and Termination for AC Coupled Link TAXI TX TAXI RX VCC Pseudo-ECL Driver R1 C Copper Media SEROUT SERIN R2 RE 12330E-10 Figure 5-4 Serial Link with Output Driver Model TAXI TX TAXI RX VCC Pseudo-ECL Driver (Model) R1 R0 VOH C B Copper Media SWI RE R2 SERIN 12330E-11 5.4 Baseline Wander and the AC Coupling Capacitor The 4B/5B and 5B/6B data encoding schemes which are used by the TAXIchip set are run-length limited to a maximum of 3 consecutive LOW states (non-transitions in NRZI). This type of encoding ensures that on average there will be less than ±10% variation in the DC component of the encoded data. When the encoded data is passed through an AC coupled link, the high-pass filtering of the AC coupling will introduce jitter because of the fluctuating threshold caused by the variation in DC component. This undesired side-effect of AC coupling is often described 64 TAXIchip Integrated Circuits Technical Manual AMD as baseline wander effect and is illustrated in Figure 5-5. In Figure 5-5a, the average DC fluctuates between 40% and 60% of the maximum level (+10% of midpoint). After the signal is capacitively coupled (Figure 5-5b), the average DC component is lost due to high-pass filtering, causing an undesired shift in the signal levels. This shift in the signal levels, coupled with non-zero rise and fall times of the serial stream cause pulse width distortion and thus apparent jitter and possible increased error rates. This DC shifting effect can be minimized if the values of the AC coupling components are chosen appropriately. The DC level of the data will fluctuate at a data-dependent frequency, fb, called the baseline wander frequency. The 3 dB corner frequency of the AC coupling, f3dB=1/(2πRC), should be chosen below the minimum baseline wander frequency of the data. This allows most DC variations to pass through the AC coupling high-pass filtering, minimizing the DC shift in the signal. To minimize f3dB we must maximize R and C. The resistance R is generally determined either by the termination required by the transmission line or by biasing requirements on both sides of the link. Hence, only the coupling capacitor C can be maximized to keep f3dB as low as possible. The largest value capacitor that can be used is limited by the fact that it must be an RF capacitor. RF capacitors are generally of the ceramic type (NPO and X7R dielectrics) and are limited to a maximum value of approximately 1.0 µF. 0.1 µF capacitors have proven to be sufficient in laboratory tests of TAXIchip set systems. For a 0.1 µF capacitor, we must verify that the capacitive reactance at the lowest fundamental frequency possible is less than 1Ω. The lowest fundamental frequency possible is the frequency that results when the TAXIchip set is running at it’s lowest BAUD rate (40 Mbaud) and the command or data pattern with the least number of transitions is being sent. This pattern turns out to be the HQ command (FDDI terminology) which has only 1 transition per command, or 1 transition per 10 bits when the command is encoded. If a continuous stream of HQ commands are sent at 40 Mbaud, the resultant fundamental frequency of the signal is 2 MHz. At 2 MHz, the capacitive reactance of a 0.1 µF capacitor is calculated as follows: XC = 1 2πfC = 1 2π (2*106) (0.1*10-6) = 0.8 Ω Hence, in the worst case a 0.1 µF capacitor will give a reactance of less than 1 Ω, as desired. In summary, the largest value RF capacitor available should be used to optimize the performance of the TAXlchip link. Figure 5-5 Baseline Wander Average DC Level Varies with Data Pattern a) Data Before AC Coupling Varying DC is Filtered Out Causing an Undesired DC Shift in the Data b) Data After AC Coupling TAXIchip Integrated Circuits Technical Manual 12330E-12 65 AMD 5.5 Interfacing to Fiber Optic Transmitters/Receivers The TAXlchip set can be used in conjunction with optical components and optical fiber to form a simple fiber optic communication link. Optical transmission has many advantages over conventional electrical transmission. These include: immunity to EMI/RFI, low attenuation, electrical isolation, data security, and wide bandwidth. Because of these features, use of optical fiber as the serial media will result in optimum performance of the TAXIchip set link. Depending on the type of fiber and the optical components used, TAXI links using optical fiber can cover distances of up to several kilometers. Figure 5-6 shows a block diagram of a complete TAXI fiber optic link. The optical components transmitters and receivers can be obtained from one of the sources listed in Appendix A of this manual. The interface between the TAXlchips and the optical components will be the subject of this section. Figure 5-6 TAXl-Based Fiber Optic Link Data Fiber Optic Transmitter Optical Source: LED or Laser Diode Fiber Optic Cable Optical Connectors Command 4, 3, 2 8, 9, 10 Source Driver Electronics Am7968 Transmitter Transceiver TAXI /Optical Interface Fiber Optic Receiver Optical Detector: PIN or Avalanche Photodiode Am7969 Receiver Receiver Electronics 8, 9, 10 Data 4, 3, 2 Command 12330E-13 5.5.1 DC-Coupled TAXl-Fiber Optic Transceiver Interface When passing data between the TAXIchip set and an optical module, care must be taken to assure that the logic levels of the TAXIchip set and the optical components are matched. If the supply voltages of the optical components do not match those of the TAXIchip set, then the logic levels will probably differ and the interface will require AC coupling to isolate these different levels. However, if the power supply requirements match those of the TAXIchip set (i.e. VCC = +5 V, VEE = GND) and if the two components are connected to the same power and ground planes, a DC coupled interconnection may be sufficient. 66 TAXIchip Integrated Circuits Technical Manual AMD For DC-coupled interconnections in which the distance between the TAXIchip set and the optical module is less than 3″, transmission line terminations are not necessary. All that is required is the appropriate ECL pull-down as shown in Figure 5-7(1) . On these short line lengths, elimination of line reflections is not critical. However, without any increase in complexity or power consumption, line reflections can be reduced simply by locating the pull-down resistor, RE, at the end of the line instead of at the beginning. This reduces the reflection coefficient at the end of the line, and therefore, reducing the magnitude of the reflections. Figure 5-7 DC-Coupled TAXl-Fiber Optic Interface (Unterminated) +5 V +5 V Optical Fiber TAXI TX ODL TX L < 3″, Z0 + – + – RE ODL RX 186 ≤ RE ≤ 7.2 (Z0) TAXI RX L < 3″, Z0 + – + – RE RE RE 12330E-14 Note: If the DC-coupled interconnection is longer than 3″, transmission line terminations are necessary. For this case, the suggested configuration is shown in Figure 5-8. Note that the line termination network also provides the desired pull-down to VCC – 2 V, sufficiently below the output LOW level of VCC – 1.8 V Figure 5-8 DC-Coupled TAXl-Fiber Optic Interface +5 V +5 V R1 TAXI TX Optical Fiber R1 ODL TX L>3″, Z0 + – ODL RX R2 R1 R1R2 = Z0 R1+ R2 TAXI RX + – + – + – R2 R1 L>3″, Z0 R2 R2 5R2 =3V R1+ R2 12330E-15 Note: If the optical and TAXI power and ground planes are decoupled as shown in Chapter 6, AC coupling is always recommended to allow for variations in power and ground plane voltages. AC coupling is discussed in Section 5.5.2. (1) Adequate bypass capacitors have been omitted from this and the following figures to simplify the drawings. TAXIchip Integrated Circuits Technical Manual 67 AMD 5.5.2 AC-Coupled TAXl-Fiber Optic Transceiver Interface Some applications will require the TAXIchip set to optical transceiver interconnection to be AC-coupled. AC coupling should be used in the following situations: a) when the TAXIchip set and optical components are driven by a common power supply but the supply pins are decoupled using the scheme recommended in Chapter 6, and b) when the TAXIchip set and optical components operate on different power supplies. AC coupling via capacitors along with the necessary design equations is shown in Figure 5-9. In this configuration, RE is the ECL output pull-down resistor, C provides the AC coupling, the connection is made with a transmission line (coax, twisted pair, microstrip) of length L and characteristic impedance, Z0, and R1 and R2 provide a matched line termination and voltage bias to the midpoint of the optical component’s logic swing (Vbb). The configuration shown in Figure 5-9 is recommended for any line length, L, which separates the TAXIchip set and the optical module. Although the matched line termination is not necessary for L<3″, the Vbb bias voltage is always needed for AC-coupled links. Therefore, even for line lengths where matched line terminations are not necessary (less than 3″), the resistors R1 and R2 can be chosen to give a matched load without any added complexity. Figure 5-9 AC-Coupled TAXl-Fiber Optical Interface VCC +5 V R1 R1 TAXI TX ODL TX L, Z0 C + – + – Vbb C RE R2 R1R2 R3R4 = Z0 R1+ R2 = R3+ R4 R2 RE VIH + VIL Vbb = Midpoint of ODL = Signal Swing 2 VEE Optical Fiber 5R4 Midpoint of PseudoR3+ R4 = ECL Signal Swing = 3.7 V VCC 186 < RE < 7.2 (Z0) +5 V R3 R3 TAXI RX L, Z0 ODL RX C + – = VEE + (VCC – VEE) R2 R1 + R2 C = Largest RF Capacitor Available + – C R4 RE RE R4 12330E-16 VEE 5.6 Interfacing to Coaxial Cable In many applications, system cost can be reduced by using coaxial cable as the serial media. Unlike optical fiber, which requires optical components between the fiber and the TAXIchip set, coaxial cable can be connected directly to the TAXI SEROUT pins, giving lower system costs. 68 TAXIchip Integrated Circuits Technical Manual AMD Because of the resultant lower system costs, coaxial cable is the recommended serial medium for short-to-moderate length links. At longer lengths, the advantages of fiber optic transmission (low attenuation, immunity to EMI and ground loops, etc.) make it the media of choice. The maximum length possible for a coaxial cable TAXI link depends on the type of coaxial cable used and the data rate. Higher data rates will tend to limit link lengths because attenuation and pulse dispersion on coaxial cable increases with frequency. Many different types of coaxial cables are available. Some have far less attenuation than others however, with low loss generally comes increased size and rigidity. RG-58 is a commonly used, readily available type of coaxial cable. In lab tests using this type of cable, it was found that the TAXlchip link could operate with a byte error rate of better than 10–10 with a confidence limit of 95%, at byte rates of up to 12.5 MHz, at distances of up to 200 feet. The confidence limit accounts for the statistical nature in which errors occur in a digital system and it implies that we can be 95% sure that, under the given circumstances, the byte error rate will be 10–10 or better. Note that a byte error could have been due to a single bit error or more hence, the bit error rate may not be equal to the byte error rate divided by ten. Using the TAXlchip set in conjunction with coaxial cable as the serial media is quite simple. Appropriate line terminations are required and AC coupling is strongly recommended to eliminate ground loops. The recommended configuration, including the necessary design equations, is shown in Figure 5-10. Each of the components that make up the interface serve the same purpose as in the AC-coupled TAXl-fiber optic interface shown in Figure 5-9. Note that two coaxial cables comprise the link, one for each of the differential pseudo ECL signals. These two lines should be calibrated for a propagation delay difference of less than 0.2 ns. Figure 5-10 Coaxial Cable Interface +5 V +5 V TAXI TX L, Z0 R1 C + + C – RE TAXI RX R1 – R2 R2 RE R1R2 = Z0 R1+ R2 5R2 = Midpoint of Pseudo-ECL Signal Swing = 3.7 R1+ R2 186 ≤ RE ≤ 7.2 (Z0) 12330E-17 C = Largest RF Capacitor Available TAXIchip Integrated Circuits Technical Manual 69 AMD Sample Values Using RG-58A/U, 50 Ω coaxial cable, a successful TAXI link was established using the following component values: R1 = 68 Ω R2 = 200 Ω RE = 300 Ω C = 0.1 µF 5.7 Interfacing to Twisted-Pair Cable Another low cost alternative twisted pair cable. Twisted pair cable is generally more lossy than coaxial cable making it suitable only for short distances. To reduce the possibility of noise being induced along the line, the shielded twisted-pair cable is recommended. Using the TAXlchip set with shielded-twisted-pair as the serial medium is very similar to using it with coaxial cable. The recommended configuration is shown in Figure 5-11, where each of the components that make up the interface serve the same purpose as in the AC-coupled TAXl-fiber optic interface shown in Figure 5-9. Note that with shielded-twisted-pair, only one cable is required to form the link. The twisted-pair conductors carry the differential pseudo-ECL signals and the shield is grounded at the Receiver. Figure 5-11 Shielded-Twisted Pair Cable Interface +5 V +5 V TAXI TX L, Z0 R1 C + + C – RE TAXI RX R1 – R2 R2 RE R1R2 = Z0/2 R1+ R2 5R2 Midpoint of Pseudo = = 3.7 V ECL Signal Swing R1+ R2 186 ≤ RE ≤ 7.2 (Z0) C = Largest RF Capacitor Available 70 TAXIchip Integrated Circuits Technical Manual 12330E-18 AMD Sample Values Using IBM Type 1 STP 150 Ω shielded twisted pair cable, a successful TAXI link was established using the following component values: R1 = 101 Ω R2 = 291 Ω R3 = 300 Ω C = 0.1 µF 6.0 BOARD LAYOUT CONSIDERATIONS While the TAXIchip devices are digital in application, they are essentially analog parts, containing high frequency analog Phase Locked Loops. Reliable operation in a high frequency analog and digital environment requires that some simple board layout rules be followed. For example, most TAXI applications which are laid out on a wire wrap board will not work reliably. Because they have at most one power and ground plane, most wirewrap cards have insufficient separation between small signal current and digital switching current. Digital switching noise can couple into the analog PLL, causing phase errors and loss of synchronization. The preferred realization of a TAXI application is on a printed circuit board, where the user can control the layout of power and ground planes. 6.1 Printed Circuit Board Layout 6.1.1 Rules for Layout The following rules should be followed to ensure minimal noise coupling: 1. Use a PC board with separate GND and VCC planes. 2. Use two capacitors which differ by at least a factor of ten in value to decouple the devices. The reactance of large capacitors has a significant inductive component at high frequencies. Because of this inductive component, a single large capacitor is not very effective against high frequency noise. Two capacitors, one typically of 1 µF and one of 0.1 µF are more efficient at decoupling than a single large capacitor of 1.1 µF. The recommended layout is as shown in Figure 6-1. TAXIchip Integrated Circuits Technical Manual 71 AMD Figure 6-1 Transmitter and Receiver Decoupling Layouts VCC Plane A Transmitter VCC Plane B C2 Am7968 VCC1 (TTL) D Receiver C2 Am7969 6 VCC2 (ECL) GND1 5 VCC3 (CML) GND2 (CML) 7 C1 C3 C3 22 C1 21 C1 Leads must be very short (less than 1/4″) VCC1 (TTL) GND1 VCC2 (CML) GND2 C3 7 C1 C3 20 8 21 C1 = 0.1 µF (ceramic) C2 = 1 µF Tantalum C3 = 0.01 µF (ceramic) C1 C3 12330E-19 To further decouple the TAXIchip set, it is highly recommended that ferrite beads be inserted at locations A, B and D. Figure 6-3 Jogs and Glitches in the Clock Line Normal Overshoot < 0.5 V CLK or X1 Jog or Glitch 12330E-20 Normal Undershoot < 0.5 V 3. Keep all bypass capacitors as close to the power pins of the device as possible. Lead lengths should be minimized. 4. Use high quality RF grade capacitors such as type COG or X7R. Use of Z5U capacitors is not recommended. 5. Ensure that the power supply does not have more that 100 mV of peak-to-peak noise at any of the TAXI Vcc pins. Make this check while the TAXls are sending random data. 6. While CLK can drive four X1 inputs or several TTL loads, the highest performance can be achieved by reducing the load on the CLK pin. Care should be taken to ensure that no jogs or glitches occur in the CLK signal as shown in Figure 6-3. If present, these glitches will be passed onto the PLL and cause an occasional error. Serial Lines 7. Run serial outputs parallel to each other, or one on top of the other at all times and route them away from the Transmitter. Do the same for serial inputs on the Receiver. Running these serial traces adjacently will minimize noise caused by these extremely fast signals on other traces. Use of strip lines for serial signals is recommended. 72 TAXIchip Integrated Circuits Technical Manual AMD 8. When terminating serial lines to or from the TAXls ensure that the Vcc rail or ground tap is not at a noisy location. Resistors can couple noise from a power supply rail into the Serial lines. Vcc to Ground decoupling adjacent to the resistors is recommended when using pullup/pulldown terminating resistor setups as shown in Figure 6-4. When using only a pulldown, do not use decoupling as this could add more Vcc noise into the serial signals. Figure 6-4 Decoupling Terminations Decoupling Capacitor +5 V +5 V No Decoupling Capacitor Required TAXI TX R1 TAXI RX R1 + + – – RE GND R2 R2 RE 12330E-21 6.2 Layout using Fiber Optic Data Links Because of their small signals levels, fiber optic data links require some care in layout. Fiber optic data Link receivers consist of a photo sensitive diode and an amplifier. The photo-diode converts light pulses into currents of around a few hundred nano-amps. This signal current is then amplified and translated into an ECL signal. TAXI Receivers and most digital chips switch hundreds of milliamps. If switching noise from the digital section of the board gets coupled into the optical data link, the signal from the light pulse data can be corrupted. To prevent the coupling of the optical data link output with other digital signals, the user must ensure that small signal and digital switching currents do not flow in the same path. This is done by separating both the optical VCC plane and the optical ground plane from the V CC and Ground planes used by other digital circuitry. See Figure 6-5. TAXIchip Integrated Circuits Technical Manual 73 AMD Figure 6-5 Fiber Optic Data Link Decoupling As Appropriate 0.1 µF 4.7 µF Ferrite Bead (Part# 2743002111 by Fair-Rite) TAXI VCC Plane FODL VCC Plane As Appropriate FODL GND Plane .1 µF TAXI GND Plane TAXI GND Plane 4.7 µF Logic VCC Plane Power Supply Ground Logic GND Plane 4.7 µF 0.1 µF As Appropriate 12330E-22 Note: This connection includes a ferrite bead in the V CC circuit of the fiber optic components. 7.0 CASCADE MODE OPERATION The TAXIchip set can be cascaded to send multiple byte words over a single serial channel. Cascade operation is the loading of n bytes of data into a TAXI Transmitter, and the serial transmission of that data through the Transmitter to the media. Data and Command bytes are multiplexed into the Local Mode transmitter. Detailed block diagram and explanation of the data multiplexing method are described in section 7.1. Also see Appendix C, TAXI TIP #14. For Am7969-125 TAXI Receivers, the connection is parallel for data and daisy-chained for control. That is, the SERIN pins of all TAXI receivers are connected together and to the media. The daisy chain of IGM to CNB control signals determines which Receiver latches which incoming byte. The Receiver whose CNB input is connected to +5 V is the primary Receiver, supplying the initial IGM, as well as a reference frequency for the X1 inputs of the down stream TAXI receivers. Cascade mode does not increase data rate or throughput. The maximum data rate is 100 Mbits per second, cascaded(2) or not. The advantage of cascading lies in the fact that the width of the data word is transparently maintained. If the application requires the transfer of 32 bits of data, Cascade mode allows TAXI transmitters to latch all the data, and send it over a single serial channel, and receive the data in proper order in four TAXI receivers at the other end of the link. Another advantage of cascade mode is that if a byte gets corrupted, the system can be reset by just sending a Sync, ensuring that the first TAXI Receiver gets the first byte, the second Receiver gets the second byte, and so on. Performing this reset operation with latches would require additional logic to decode a Sync command which in turn would reset all the latches. For Am7969-175 TAXI Receivers, see Appendix C TAXI TIP #13 for single receiver cascade operation. (1) 74 Actually, in Non Auto-Repeat Cascade Mode, the throughput is less than 100 Mbits/s due to the need to send Syncs. TAXIchip Integrated Circuits Technical Manual AMD Figure 7-1 Cascaded TAXI System Mixed Data Sources (Note 2) 8 4 DI0–DI7 SEROUT+ SEROUT– CI0–CI7 TLS STRB ACK ACK TAXI RX #1 TAXI TX #1 X1 X2 DMS CLK * 12.5 MHz From an External TTL Frequency Source 12.5 MHz VCC SERIN+ SERIN– X1 X2 CNB DMS CLOCK IGM VLTN TAXI RX #1 (Note 1) DSTRB DO0–DO7 CO0–CO3 CSTRB 8 Data Destination SERIN+ SERIN– X1 X2 CNB Data Path Control Logic CLOCK To Next Stage IGM VLTN TAXI RX #2 DSTRB DO0–DO7 CO0–CO3 CSTRB 4 Command Destination DMS 8 Data Destination 4 Command Destination Data Path Control Logic 12330E-1 TAXIchip Integrated Circuits Technical Manual 75 AMD 7.1 Transmit Cascaded Data with a Single TAXI Transmitter For systems that require data transfer wider than a single byte, a single TAXI Transmitter can be used to cascade the multiple bytes. This operation allows the data to be multiplexed onto a single serial link, and then automatically demultiplexed and restored to the original word width. The TAXI Receiver performs this demux operation automatically when connected in the cascade configuration illustrated in the TAXlchip data sheet and section 7.2. The circuit shown in Figure 7-2 illustrates the basic technique that may be used to control multiplexing of word-wide data into a single TAXI Transmitter. This circuit assumes that the data to be transmitted is stored in appropriate registers that are all loaded simultaneously. While many systems will already include these storage elements, in the diagram these registers are shown as 74ALS374 octal D flipflops. They could be any register with the appropriate number of bits for the data, and a three-state controllable output. The registers are connected in a TRISTATE MUX configuration wherein each output can be selected individually. To clarify the illustration of the technique, the Command lines are not used, and have been tied low. In systems that send Commands as part of the data stream, these lines would be buffered in the same way as the data, except that the unused bits (or bytes) need to be held low when Data is to be sent. The controller for the automatic multiplexer consists of a shift register that can be loaded with a 0 that shifts through and selects each data register in sequence, and strobes the TAXI Transmitter. In the attached figure, this shift register is a 74LS174, but any collection of flip-flops would serve as well. The shifter is loaded with a 0 when STROBE, the signal that loads data into the registers, is a 1. The NAND gate (U1) at the input of the first flip-flop assures that only a single 0 is possible while the registers are being selected. STRB for the Transmitter is derived from the CLK output of Transmitter, and is gated by the same signals that select the data. It is important that no glitches appear on the TAXI STRB input, since that will cause false data to be sent, and will disrupt the information transfer. To assure that any race-caused glitches appearing at the output of the four input NAND gate (U2) are suppressed, the counter must be clocked on the falling edge of the CLK. This assures that, during the time the outputs are changing, the low on the CLK input of the two input NAND gate (U3) will suppress anything happening on the other input. When CLK rises, it will be the only signal active, and there should be no false strobes. This configuration also assures the longest possible setup time for the output of the data registers, since the STRB happens immediately before the outputs change, and a full byte time before they change again. The other gates (U4, U5, U6) are only buffer and inverters used to assure proper signal sense, and fanout. They may not be needed in all systems. Only four stages of shift register are required to select the four data registers, and the fifth stage shown in the figure is used to provide the SYNC character required for some cascade systems. The output of the fifth stage (ACK1 stands for one SYNC) is used to ACK systems that require a SYNC between data words. The output of the fourth stage (ACK0 stands for no SYNC) can be used for ACK in systems that expect to send contiguous data, and no SYNCs between words (auto-repeat cascade). Either of these outputs can be connected back to the DATA STRB input if the system is to run automatically, as in data sampling systems. 76 TAXIchip Integrated Circuits Technical Manual AMD Figure 7-2 Cascade with One TAXI Transmitter U7 74LS174 ACK0 LOAD1- U1 STROBE D Q LOAD2- D DFF Q D DFF CK LOAD3- Q D DFF CK LOAD4- Q DFF CK CK D ACK1 Q DFF CK CLK2 CLK1 U6 U5 U2 U3 LOADEN DATA U4 CLK Buffer; May Not Be Required for Low Fanout System 32 8 8 8 CLK 8 CLK OE- D Q OE- D Q OE- D Q OE- D Q BUFFERS BUFFERS BUFFERS BUFFERS CK CK CK CK 74ALS374 74ALS374 74ALS374 74ALS374 8 BYTE1 8 BYTE2 8 BYTE3 STRBIN 8 BYTE4 STRB SEROUT ACK SEROUT TAXI 8 DATA 4 Four-Byte Cascade Mode Logic 2 COMMAND 12330E-24 7.2 Receivers In Cascade Mode: Connections (Am7969-125 Only) Unlike transmitters, all cascaded receivers are directly connected to the media, via the two serial input data lines. All Receivers see the same serial data at the same time. The Primary Receiver always receives the first byte of serial data after a Sync. The signals used by the upstream Receiver to tell the downstream Receiver that it has captured a byte are IGM (I Got Mine) and CNB (Catch Next Byte). After receiving its byte, the upstream receiver raises its IGM signal, telling the next Receiver in line that it is to catch the next byte on the serial line. In this way each succeeding Receiver down the line catches each succeeding byte. The second receiver waits for the Primary Receiver to capture data before capturing its data (the second byte). Similarly, if there were a third Receiver it would wait until the second Receiver had captured the second byte before capturing the third byte. The connections of the cascaded (downstream) TAXI Receivers are as follows (see Figure 7-3): The CNB input of the cascaded Receiver is tied to the IGM of it’s upstream neighbor. The CNB input of the first upstream or primary Receiver is tied high. The IGM output of the last downstream Receiver is left unconnected normally. (This pin is used differently in Auto-repeat Configuration, discussed in section 7.3). TAXIchip Integrated Circuits Technical Manual 77 AMD X1 is connected to a common Crystal Oscillator or a TTL Clock Source. It is not recommended that X1 be connected to another Receiver’s CLK output. X2 is grounded. The DMS pins of all TAXls must be tied in the same state as the DMS pins on the Transmitters. The CSTRB/DSTRB pins on each of the Receivers are all active simultaneously. A timing description for CSTRB and DSTRB is included in Appendix C, TAXI TIP #89-10 TAXI receiver CSTRB and DSTRB pulse width. The VLTN pin has timing that is identical to the timing of the Data Out and the Command Out lines. Its connections are specific to each user’s applications. If CNB is HIGH, the Receiver will catch the next valid byte of data and hold it. It will not attempt to catch any more data until it sees a Sync command from the Transmitter or until its CNB goes LOW and then HIGH again. Figure 7-3 Receivers in Cascade Mode 12.5 MHz Crystal OSC SERIN– SERIN+ SERIN– SERIN– SERIN+ SERIN+ CLK X2 RX1 Am7969 PRIMARY RX VCC X1 X2 DMS IGM CNB CSTRB CMD DATA DSTRB VLTN D23-D16 RX2 Am7969 DMS IGM CNB X2 X1 RX3 Am7969 X1 DMS IGM CNB CSTRB CMD DATA DSTRB VLTN CSTRB CMD DATA DSTRB VLTN D15-D8 D7-D0 N/C 12330E-25 *Transmission line terminations not shown. The following section describes the functionality of individual pins: The DSTRB Pin Any one of the DSTRBs may be used as the user’s DSTRB to his system. When an entire word has been received (signified internally by a Sync from the Transmitter) the data in the Receivers are latched out to the output ports and all the DSTRBs are raised (simultaneously) one cycle later. Likewise, if Commands are sent as part of the cascade word, the CSTRB/DSTRB connections must be made appropriately. Timing description for receivers in cascade mode is included in Figure 7-4. 78 TAXIchip Integrated Circuits Technical Manual AMD Figure 7-4 Receiver Timing—8-Bit Cascade Mode Internal Clock* 1 1 0 0 0 1 0 0 0 1 1 1 0 0 0 1 0 0 0 1 SERIN Serial Data DATA N NRZ Data* DATA N SYNC SYNC 1 1 0 0 0 1 0 0 0 1 DATA 1 DATA 2 DATA 1 DATA 2 SYNC 1 1 0 0 0 1 0 0 0 1 1 1 0 0 0 1 0 0 0 1 SYNC SYNC 1 1 0 0 0 1 0 0 0 1 SYNC CLK OUT 1 2 3 4 5 6 NO CHANGE NO CHANGE NO CHANGE NO CHANGE COMMAND 0 NO CHANGE NO CHANGE NO CHANGE NO CHANGE DATA N–1 NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE NO CHANGE DATA N NO CHANGE NO CHANGE CNB TAXI #1 = 1 IGM TAXI #1 = CNB TAXI #2 TAXI #1 Command OUT CSTRB OUT DATA OUT DSTRB OUT Command OUT TAXI #2 CSTRB OUT DATA OUT DSTRB OUT 12330E-26 * Internal Signals If CNB is HIGH, the Receiver will catch the next valid byte of data and hold it. It will not attempt to catch any more data until it sees a Sync command from the Transmitter or until its CNB goes LOW and then HIGH again. If CNB is held LOW, the Receiver will not attempt to capture any data. When the Primary Receiver RX1 catches a valid data byte it will raise its IGM (I Got Mine) so the next Receiver RX2 can catch the next byte and so on down the line. After all the receivers in the system have received their bytes a Sync must be sent or the next byte of data will be lost(3) . Referring to Figure 7-5 for a system of Cascaded Receivers. (3) In the Auto-Repeat Configuration, a Sync is not required. TAXIchip Integrated Circuits Technical Manual 79 AMD Figure 7-5 CNB and IGM Propagating Down Cascaded Receivers Time Serial Data CNB1 = VCC Sync Data 1 a Data 2 b Data 3 c Sync d t46 IGM1 CNB2 IGM2 CNB3 IGM3 = N/C 12330E-27 Note: Half of the byte is sufficient for the Receiver to decide whether the byte is a Sync or Data. When CNB on the first Receiver is raised (Figure 7-3 it is tied to Vcc), its IGM does not follow until the first half of a non-Sync byte is detected in its SERIN. Note that if a Sync is detected, IGM does not go HIGH, since it is a Sync that makes IGM fall. The IGM on RX1 rises when it sees a non-Sync byte, then since it is tied to the CNB of RX2. RX2 will now be ready to accept the next byte of data. RX2 will now wait for the next non-Sync byte to come down the SERIN lines. During this time all the other downstream receivers will ignore the data on the SERIN lines because their CNBs are still LOW. In the same way the upstream (Primary) Receiver will ignore the SERIN lines because it has already caught one byte and thus it will continue to ignore the data until it sees another Sync. The IGM on RX2 rises when it sees the second non-Sync byte. In this fashion, each Receiver will sequentially get ready to receive data as the CNBs propagate down the IGMs. When the first Receiver sees a Sync, it will lower its IGM which is connected to RX2’s CNB which will lower its IGM and RX3’s CNB and so on. In this way the LOW IGM will also propagate down all the Cascaded Downstream Receivers. CNB falling to IGM falling is t46 ns. In normal Cascade mode, the CNB on RXl is tied HIGH and thus, a Sync has to be sent after all the receivers are full to ensure that RX1 is reset to accept the next byte of data. 80 TAXIchip Integrated Circuits Technical Manual AMD The Data Out Lines When a Receiver sees the Sync symbol it sends the data byte it just received from its Input Latch to its Decoder Latch, and then the receiver lowers its IGM. One more clock cycle is required for the data to go to the Output Latch. At this point DSTRB is raised. In this way all data bytes are output simultaneously from all receivers, two clock cycles after the first Sync (or two clock cycles after a LOW CNB). The DSTRBs of all the receivers rise simultaneously as well. The VLTN (Violation) Pin In Cascade mode the VLTN pin acts exactly like a Data Out line. The timings are exactly the same. Violations do not change the output of the IGM pin. i.e., a Receiver that gets a VLTN will still raise it’s IGM signal as if it received a valid data byte. 7.3 Auto-Repeat Configuration 7.3.1 Receiver Connections in Auto-Repeat Configuration In Auto-repeat Configuration the IGM of the last Receiver on the line is inverted and tied to the CNB of the Primary Receiver. This connection eliminates the need to send a Sync between each Data Word. In a 3-Receiver cascade system, IGM3 is inverted and tied to CNB1. When the IGM of the last Receiver goes high, CNB1 goes LOW. CNB1 going LOW ripples through the chain pulling each IGM LOW (t46 ns) until finally the last IGM goes LOW again, pulling CNB1 HIGH resetting RX1 to receive new data. In Figures 7-6 and 7-7, as each Receiver decodes its data byte, it raises its IGM and thus the next Receiver’s CNB. Figure 7-6 TAXI Receiver—Cascaded in Auto-Repeat SERIN+ SERIN– CNB CSTRB IGM DSTRB CNB CSTRB IGM DSTRB CNB CSTRB IGM DSTRB CNB CSTRB IGM DSTRB 12330E-28 TAXIchip Integrated Circuits Technical Manual 81 AMD Figure 7-7 Receiver Timing in Auto-Repeat Configuration Serial Data Sync Data 1 Data 2 Data 3 CNB1 IGM1 CNB2 IGM2 CNB3 IGM3 = CNB1 12330E-29 Note: Only when a Receiver has a CNB = 1, can it accept new data. It then raises its IGM when it sees a non-Sync byte. It won’t accept another data byte until it’s CNB has gone LOW and HIGH again. When IGM1 goes high, CNB2 goes high. This allows RX2 to decode the next byte and raise it’s IGM. IGM2 is connected to CNB3 and RX3 is now allowed to decode the next byte and raise its IGM. In Figure 7-8 since IGM3 = CNB1, CNB1 goes LOW. When CNB1 goes LOW, RX1 is reset and it pulls it’s IGM LOW (t46 ns). Since IGM1 is connected to CNB2, RX2 is reset and pulls its IGM LOW t 46 ns later. CNB3 = IGM2 goes LOW, which causes IGM3 to follow it LOW t 46 ns later. IGM3 going LOW makes CNB1 go HIGH again and RX1 is now set to receive the next byte of data on the SERIN. See Figure 7-9. Thus, the cycle starts over again. 82 TAXIchip Integrated Circuits Technical Manual AMD Figure 7-8 Receiver Timing in Auto-Repeat Configuration Serial Data Sync Data 1 Data 2 Data 3 CNB1 t46 IGM1 CNB2 IGM2 CNB3 IGM3 = CNB1 12330E-30 Note: When IGM3 goes HIGH CNB1 goes LOW. Thus, IGM1 = CNB2 goes LOW t46 ns later, and IGM t46 ns after that. This will ripple down to IGM3. TAXIchip Integrated Circuits Technical Manual 83 AMD Figure 7-9 Receiver Timing in Auto-Repeat Configuration Serial Data Sync Data 1 Data 2 Data 3 Data 4 Data 5 Data 6 CNB1 IGM1 CNB2 IGM2 CNB3 IGM3 = CNB1 12330E-31 Note: IGM3 = CNB1 so RX1 is now ready to receive new data. The cycle can now be repeated. 7.3.2 Timing Limitations of the Auto-Repeat Configuration Note, however, that the t46 delay adds up as it ripples through the daisy chain. If the total delay from the first to the last Receiver in the cascade is greater than 1 byte time, parallel data will output 1 byte time later on some Receivers than on others. The following example is for t46 = 20 ns and a 12.5 MHz byte rate, the time between the start of one byte to the start of the next is 80 nanoseconds. When IGM on the last Receiver goes HIGH forcing the CNB1 on the first one to go LOW, it will take 20 x R ns (where R is the number of Receivers in cascade) before the last IGM goes LOW again, (allowing CNB on the first Receiver to go HIGH). In order for the first Receiver to capture the next byte its CNB cannot remain LOW for more than X ns (where X must be less than 1 byte period). X = (20 x R1) + (inverter delay) + (CNB to CLK set-up) (R1 is the number of receivers that can be connected in cascade in this format) The CNB to CLK set-up time is specified as t47 = [(byte time/n) –32 ns] In 8 Bit mode at 12.5 Mbyte/s, CNB to clock setup = - [(80/10) –32] = 24 ns Figure 7-10 demonstrates an alternative scheme which will allow a virtually unlimited number of receivers to be cascaded. The fan-out of the inverter dictates the number of AND gates that can be driven. Multiple inverters can be connected to the last IGM output if needed. Using this scheme guarantees that all of the receivers in cascade will 84 TAXIchip Integrated Circuits Technical Manual AMD output data at the same time This also guarantees that the CNB on the first Receiver goes active (HIGH) within 2 gate delays + 20 ns after it goes LOW. This leaves enough time for the first Receiver to capture the (R+1)th byte of data. Figure 7-10 TAXI Receiver—Cascaded In Auto-Repeat Configuration. Configuration 2 CNB IGM CNB IGM CNB IGM CNB IGM CSTRB DSTRB CSTRB DSTRB CSTRB DSTRB CSTRB DSTRB SERIN + SERIN - 12330E-32 Figure 7-11 TAXI Receiver—Cascaded in Auto-Repeat Configuration. Configuration 3 SERIN+ SERIN– CNB CSTRB IGM DSTRB CNB IGM CSTRB DSTRB CNB CSTRB IGM DSTRB CNB IGM CSTRB DSTRB 12330E-33 In practice, all the AND gates are not required. Using the above equation for X we can calculate a value of R1 for which X is less than 1 byte period at the appropriate frequency of operation. Then if the number of receivers to be cascaded is greater than R1, an AND gate is needed for every (R1+1)th Receiver in cascade. The other receivers can be directly connected as shown in Figure 7-11. Syncs in Auto-Repeat Configuration and Recovering from Errors A Sync in Auto-Repeat Configuration acts much like a Sync in Normal Cascade mode. It resets all the Receivers and their IGMs so the upstream (Primary) Receiver receives the next non Sync byte of data. This remains as the method of recovering from byte framing errors. 7.4 Unbalanced Configuration (Am7968/Am7969-125 Only) In reality there is no difference in connection between balanced and Unbalanced Configurations. The name only indicates that the number of Transmit bytes and the number of Receive bytes are unequal. The TAXI Receivers do not care how many data bytes the Transmitter is sending to them. One data byte can be transmitted to several Receivers. The only limitation here is TAXIchip Integrated Circuits Technical Manual 85 AMD the drive capability of the Transmitter and the termination circuit for multidrop transmission lines. Similarly, several Transmit bytes can be multiplexed to one Receiver. There are no drive considerations in this case. Figure 7-12 shows an example of an unbalanced mode of operation in which one Transmitter is connected to three Receivers. Figure 7-12 Unbalanced Configuration Example: One Transmitter to Three Receivers TTL Data IN 8, 9, 10 + SEROUT – X1 Am7968 X2 OSC Clock X1 VCC SERIN CNB IGM 8, 9, Am7969 10 X1 SERIN CNB IGM 8, 9, Am7969 10 TTL Data OUT X1 SERIN CNB 8, 9, Am7969 10 12330E-34 Note that in the Unbalanced Configuration, attention has to be given to where a Sync will be needed. Either the Auto-Repeat Receiver Configuration should be used or a Sync must be provided every (R + 1) bytes, where R is the number of Receivers cascaded together. More information on proper use and requirement of SYNC, refer to Appendix C, TAXI TIP #8903. 8.0 TEST MODE The Phase Locked Loops (PLLs) in the TAXlchips are designed to run within a frequency range that has been set for maximum efficiency and accuracy. The lower limit of this frequency range is 40 MHz. In Test Mode, the PLLs of the Transmitter and the Receiver are disconnected and the internal clock is applied from an external source. This allows the TAXls to function at a much slower speed. This mode was designed to simplify the testing of TAXls in an automatic testing production environment. A by-product of Test Mode is that it allows the user to run the TAXls in systems that are slower than 4 MHz (the minimum byte rate). In this mode there is no minimum frequency. A system that needs to transfer data at LOW byte data rates can normally be implemented without modifying the standard setup, and Test Mode need not be used. When there is no data to be sent, the TAXlchips will keep the line active by sending Syncs. 86 TAXIchip Integrated Circuits Technical Manual AMD The serial link will operate in the 40 to 175 MHz range as determined by the byte rate clock, but the byte data rate will be determined by how often the user strobes the TAXI Transmitter. The transmission speed is transparent to the user. Some applications may have a serial link bandwidth limitation. Typically, this means that the media connecting the Transmitter to the Receiver can only handle serial data rates that are lower than 40 MHz. The user can run the TAXlchips in Test Mode in order to overcome the 40 MHz lower frequency limitation. For convenience in the following discussions, encoded data width n has been set to 10, corresponding to an 8-bit input byte, (i.e. DMS = LOW). Since the multiplying PLL is turned off in Test Mode, an external clock source must be supplied to the TAXls. In normal (non-test) mode, the Transmitter PLL multiplies the byte clock by 10. The new 10X clock is called the bit clock or bitclk, and is used to transmit the serial data. The Receiver PLL generates the same type of bitclk to decode the incoming data and to track and follow any fluctuations in the transmission frequency of the incoming data. In test mode the Transmitter PLL is disconnected and the internal clock multiplier is switched out. The internal logic is now clocked directly by the signal applied to the CLK pin. The input to the CLK pin now becomes the bitclk and must be supplied by the user. On the Receiver side, the internal data tracking PLL is disconnected in Test Mode. An external clock recovery circuit must be used to allow the Receiver to track the incoming serial data stream. This recovered bitclk is supplied to X1. Either a digital PLL or an analog PLL (for faster rates) can be used for clock recovery as shown in Figure 8-2. The Transmitter and Receiver Test Mode connections and functionality are given in the following section. 8.1 Transmitter Connections Refer to Figure 8-1. The TLS pin is left floating. This is the pin that puts the Transmitter in Test Mode. The RESET pin is left floating. RESET pin function is described in Appendix C, TAXI TIP #89-02. The X2 pin is grounded. SERIN is left floating (D/C = Do Not Connect). The DMS pin is set in the appropriate state for 8-, 9- or 10-bit mode as desired by the user. The CLK is now an input for bitclk (the bit rate clock). This means that if the serial transmission rate is to be 1.5 Kbits/s, CLK must be 1.5 kHz. The ACK pin is raised only when a Sync byte is detected in the Transmitter’s shifter latch (note that if STRB is lowered before ACK is seen, ACK will be suppressed. See the STRB/ACK description in Section 7.1). The X1 input is the reset pin for the internal state machines and can be left unconnected in operational systems. For testing purposes, the following steps are to be taken upon power up or initialization. 1. X1 should be kept HIGH and the Transmitter bitclked about 15 times 2. X1 should be lowered and the Transmitter bitclked about 200 times. TAXIchip Integrated Circuits Technical Manual 87 AMD This serves to flush all extraneous data from the buffers and reset all internal state machines. Once this is completed the Transmitter may be Strobed. X1 should be left in the LOW state upon completion of the initialization. The STRB input must now be strobed only once every n = 10 bitclk pulses or more. This will allow time for an 8 bit wide byte to be encoded to 10 bits and shifted out one bit every clock pulse. The parallel data input pins are provided with new data every 10 bitclk pulses. Setup and hold times remain the same as in non-Test Mode with respect to STRB. (In the non-Test modes, the clock rate is the byte rate and a new data word and a strobe is provided every clock pulse. In test mode, the clock rate is the bit rate so the new data word and strobe are provided every n clock pulses). In Test Mode the Receiver expects only single ended data. Thus only one of the SEROUT lines from the Transmitter is used. However, both lines must have pulldown resistors to electrically balance the outputs. Figure 8-1 Transmitter Test Mode Connections Divide By n or Byte Rate Clock N/C ACK TLS X1 STROBE Data IN 8, 9, 10 Am7968 X2 RESET Bit Rate Clock Generator CLK Command IN 4, 3, 2 CLS SEROUT+ N/C = Test Mode DMS SEROUT– Can Be Set for 8, 9, or 10-Bit Mode 300 Ω 300 Ω To Receiver Media Interface 12330E-35 88 TAXIchip Integrated Circuits Technical Manual AMD 8.2 Receiver Connections Refer to Figure 8-2. Grounding SERIN– puts the Receiver in Test Mode. SERIN+ is a single ended 100K ECL NRZ input. The X1 pin now becomes the bit rate clock input (bitclk), just like the CLK pin on the Transmitter. The CLK pin remains a byte rate CLK out. 8.3 Timing Relationships in Test Mode The timing parameters in Test Mode are similar to the parameters in standard mode. Propagation delay values remain the same, however bit time relationships are now calculated with respect to the new bit times. For example, using a bitclk = 1.0 kHz, which is a 1 ms period, the byte time t35 = 10 bits x 1 ms = 10 ms. In the same way t 37, which is the CLK falling to STRB rising delay is now [2 (t35/n) + 15 ns] = 2.015 ms. Note that Setup and Hold times for SERIN to X1 are not specified and must be determined for each application. Figure 8-2 Receiver Test Mode Connections Normal Function DSTRB CNB Single Ended Input From Transmitter SERIN+ DATA STROBE SERIN– DATA OUT 8, 9, 10 X1 Am7969 X2 RESET CMD STROBE Clock Recovery Circuit Digital or Analog PLL CSTRB COMMAND OUT 4, 3, 2 CLK VLTN IGM Normal Function DMS Byte Rate CLK Out DMS Can Be Set For 8, 9, or 10-Bit Mode 12330E-36 TAXIchip Integrated Circuits Technical Manual 89 APPENDIX A Fiber Optic Data Link Manufacturer List Presented below is a partial listing of fiber optic data link suppliers that manufacture or market optical components in a data rate range compatible with the TAXIchip set. Several of these components have been demonstrated in a bench level evaluation in conjunction with the TAXlchip set. AMP 1 (800) 552-6752 (416) 475-6222 (Canada) AT&T Microelectronics (800) 372-2447 BT&D Technologies Delaware Corporate Center 11 Suite 200 2 Righter Parkway Wilmington, DE 19803 (800) 545-4306 Hewlett Packard Customer Information Center (800) 752-0900 Sumitomo Electric 777 Old Saw Mill River Rd. Suite 230 Tarrytown, NY 10591-6725 90 TAXIchip Integrated Circuit Technical Manual APPENDIX B Error Detection Efficiency When a received data pattern does not represent a valid coding symbol, the TAXI Receiver asserts the VLTN pin to indicate that the current data contains an error. The Receiver cannot detect the occurrence of a bit error that transforms one valid symbol into another valid but incorrect symbol. This means that the transition error can change a valid data symbol into a different valid data symbol, or in certain cases a valid Command symbol and not be flagged by the Violation pin. A single noise event on the serial link can cause at a minimum a double bit error. Single bit errors are assumed to be impossible (or at least rare) because NRZI encoding would require that the voltage level on the link be inverted after the event. There is no known error mechanism external to the TAXIchip set which could cause this condition. Having confirmed that all errors are at least 2 bits wide, let us examine the location at which these errors can exist. Consider the 4B/5B encoded data pattern for the TAXIchip set in the 8-bit mode. The output corresponds to two five bit nibbles for each eight bit data byte. Shown below are four nibbles, or two bytes of encoded data output, with six possible locations for double bit errors within nibble 1 of Byte 2. Figure B-1 Byte 2 Byte 1 Nibble 2 MSB b9 Nibble 1 LSB MSB b8 b7 b6 b5 b4 Nibble 2 LSB MSB b3 b2 b1 b0 b9 Nibble 1 LSB MSB b8 b7 b6 b5 b4 LSB b3 b2 b1 b0 A B C D E F 12330E-37 Notes: Error location A corresponds to a double bit error occurring in the Least Significant Bit of nibble 2 and the Most Significant Bit of nibble 1. Error locations B, C, D and E occur within the nibble between adjacent bits, and, Error location F occurs between the LSB of nibble 1 (Byte 2) and the MSB of nibble 2 (Byte 1). TAXIchip Integrated Circuit Technical Manual 91 AMD For example, consider transmitting Hex B [1011], encoded as 10111. Error E occurs changes bits b0 & b1, resulting in encoded pattern 10100, which is Hex 2 [0010] 2 bits changed, and the run length the error = 4 bits, 1011 0010 becomes 2 bits changed, and the run length the error = 4 bits, A double bit error can change valid data into a Violation, a valid Command byte, a 1-bit, 2-bit, 3-bit,or 4-bit data error. A summary of the occurrence of these errors for the six error locations for 4B/5B encoding is summarized below in Table B1. Table B-1 Table B-2 Error Type A B C D E F V=5 C=5 1B=4 2B=2 3B=0 4B=0 V=5 C=3 1B=0 2B=8 3B=0 4B=0 V=5 C=5 1B=2 2B=4 3B=0 4B=0 V=3 C=3 1B=4 2B=6 3B=0 4B=0 V=3 C=5 1B=0 2B=6 3B=0 4B=2 V=1 C=1 1B=14 2B=0 3B=0 4B=0 Similar reasoning for the 5B/6B encoding scheme results in seven possible error locations, and the summary of the occurrence of these errors is listed below: A B C D E F G V=13 C=3 1B=10 2B=6 3B=0 4B=0 V=16 C=2 1B=0 2B=14 3B=0 4B=0 V=12 C=2 1B=0 2B=12 3B=4 4B=2 V=6 C=4 1B=0 2B=14 3B=6 4B=2 V=9 C=3 1B=8 2B=12 3B=0 4B=0 V=10 C=4 1B=2 2B=12 3B=0 4B=4 V=5 C=3 1B=22 2B=2 3B=0 4B=0 Utilizing this information one can determine the efficiency of the violation logic in the TAXI Receiver. Figure B2 summarizes the violation effectiveness, as well as depicting the number of bits in error in the undetected corrupted data. This information can be extremely useful in determining what, if any, additional error detection schemes should be implemented. Figure B3 graphically represents the run length of the corrupted data for the undetected errors. As shown in this figure, there are a small percentage of unlimited run length errors. This is due to the few data patterns, which, when corrupted will cause a false Sync pattern to be generated. This pattern will cause a running error which will continue until the next valid Sync realigns the byte edge to its proper position. While these false Syncs occur very rarely, these are the most dangerous errors in a TAXI system, this very well may dictate the maximum user packet size. 92 TAXIchip Integrated Circuit Technical Manual AMD Figure B-2 60 50 40 Percent of Error 30 Events 20 10 0 Violation 1-Bit Error 2-Bit Error 3-Bit Error 4-Bit Error 8 Bit 9 Bit 12330E-38 10 Bit Figure B-3 0.104 0.027% 40 Percent of 30 Undetected Error Events 20 10 0.57 50 0 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit Unlimited Run Length of Error in Corrupted Data 8 Bit 9 Bit 10 Bit TAXIchip Integrated Circuit Technical Manual 12330E-39 93 APPENDIX C TAXI Technical Information Publications The TAXI applications team has documented questions and answers that are general purpose in nature and applicable to a wide range of applications. This documentation has taken the form of TAXI Technical Information Publications (TlPs), and have been incorporated in this revision of the technical manual. The contents of this appendix are as follows: 94 TAXI TIP # 1: Subject: Receiver Response to Loss of Input Signal TAXI TIP # 2: Subject: TAXlchip RESET Pin Function TAXI TIP # 3: Subject: Proper Use for TAXI Sync TAXI TIP # 4: Subject: TAXI PLL Lock-Up During Power-On! TAXI TIP # 5: Subject: TAXIchip set Crystal Specification TAXI TIP # 6: Subject: TAXI for FDDI Applications TAXI TIP # 7: Subject: Synchronous vs. Asynchronous Strobe TAXI TIP # 8: Subject: TAXI Receiver Lock Time TAXI TIP # 9: Subject: TAXI Bridge: Bidirectional TAXI Communication TAXI TIP # 10: Subject: TAXI Receiver CSTRB and DSTRB Pulse Width TAXI TIP # 11: Subject: Using Receiver CLK Output to Run a TAXlchip Transmitter TAXI TIP # 12: Subject: TAXlchip Pins Internal Circuit TAXI TIP # 13 Subject: Demuxing a TAXIchip Receiver to Output Multi-Byte Words TAXI TIP # 14 Subject: 32-Bit Multiplexed Cascade with the TAXIchip Transmitter TAXI TIP # 15 Subject: General Device Information for 125/175 MHz TAXIchips TAXI E.B. Nov ‘89: Subject: TAXlchip Error Rate Example TAXIchip Integrated Circuits Technical Manual TAXI TIPs TAXI Technical Information Publication #89-01 Subject: Receiver Response to Loss of Input Signal Question: It is desired that the TAXI Receiver outputs be predictable and stable during conditions when the TAXI Transmitter may cease transmitting (power-off) or is disconnected. How can a system designer predict the TAXI Receiver outputs or use the TAXI Receiver in a system where the TAXI Receiver must appear Inactive under these conditions? This applies to both Coaxial and Fiber-Optic Systems. Answer: The key to this problem is interpreting the loss of incoming Tx data as a Quiet-LineState and either flagging the system accordingly or gating the TAXI Receiver outputs with an inactive flag. In a Coaxial coupled system the loss of incoming signal drive will cause the TAXI Receiver inputs to rest at the input termination bias voltages. The differential serial inputs will normally be at equal potential. To properly interpret a loss of signal as a constant quiet state the input termination bias voltages must be altered slightly from each other. To allow reliable interpretation of the offset as a constant logic state, the offset voltage should typically be set to about 50 mV. The TAXI Receiver will interpret the Quiet-Line-State differently depending upon the operation mode (8-bit, 9-bit, or 10-bit). In 8-bit mode the Receiver will generate continuous CSTRB’s with the Command outputs at F Hex, or all HIGH. In the 9-bit and 10-bit modes there is no defined interpretation of an incoming quiet data stream. This will cause the TAXI Receiver to generate continuous CSTRB’s and the Violation output will be continuously HIGH. A one-shot may be used to determine Violation=HIGH duration and then generate an inactive flag, or the system may interpret the Violation output directly as an inactive or invalid condition flag and halt data-dependent system operations during any byte with Violation=HIGH. In a Fiber-Optic coupled system two methods may be used, depending on the Optical Receiver construction. If the Optical Receiver has a Carrier-Detect output this signal may be used to flag an inactive state. If there is no Carrier-Detect, one may be generated using an ECL one shot arrangement which will detect loss of edges after a predetermined period of say, for example, 80 bit times. The actual time may vary depending on the desired response to loss of data. In either condition, if the Receiver recovered Byte Clock (CLK) is used as a system clock, then the system must be able to tolerate a shift in the CLK frequency of typically about +/-3% to allow for Rx-PLL offset and drift during this period. (If the Optical Receiver begins oscillation when the fiber is dark, the TAXI Receiver PLL may attempt to track the oscillation resulting in an indeterminate Rx recovered clock frequency. Optical Receiver dark response thus becomes a possible system concern.) TAXIchip Integrated Circuits Technical Manual 95 AMD TAXI Technical Information Publication #89-02 Subject: TAXlchip RESET Pin Function Question: How long must the RESET pin be held low in order to insure that the TAXIchip has reset? Answer: The RESET pin is level sensitive and after a LOW input level is asserted it instantaneously forces the Phase Lock Loop (PLL) to its lowest possible frequency (approximately 5 to 10 MHz). A 1 ms LOW pulse should allow sufficient time for the PLL to reach a stable state. Preliminary tests conducted in the lab reported that for the full TAXI frequency and temperature range, the time required to recover from a reset was less than 100 µs. Resetting is intended to allow graceful recovery from the rare occurrence of a PLL lock-up due to noise bursts on the serial data lines, as may occur when light is removed from certain optical links. In a fiber-optic coupled system, loss of optical signal may cause the optical receiver to oscillate, causing the TAXI Receiver to track the oscillation to an indeterminate frequency. Care must be taken to avoid the oscillation, or a reset can be used to recover from it. After reset, the PLL begins tracking incoming data, and the byte boundary remains undefined until the transmitted data includes a Sync (JK). The Sync is a unique bit pattern which forces the TAXI Receiver to align itself to the correct byte boundary. In a coaxial system when a loss of incoming signal drive occurs, there will be no data for the TAXI Receiver to track. This quiet state will be interpreted as a continuous data pattern. The Receiver decodes this Quiet-Line-State differently depending upon the operational mode selected: 8-bit, 9-bit, or 10-bit. In 8-bit mode the TAXI Receiver will generate continuous CSTRBs with command outputs all high ( F Hex). In 9-bit or 10-bit modes there is no defined interpretation of an incoming quiet data stream thus generating continuous CSTRBs and forcing the violation output (VLIN) to be continuously high. Further information on the effects of incoming signal drive loss is available in TAXI TIP #89-01, Receiver Response to Loss of Input Signal. 96 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-03 Subject: Proper Use for TAXI Sync Question: What is the proper use for Sync? How often is a Sync needed? Answer: When a Transmitter has no data to send, it sends Sync. This symbol allows the Receiver PLL to maintain phase and frequency lock with the transmitter, exactly as would a normal DATA stream. It has the additional special property of being a unique bit pattern that can be used to discover the byte boundaries in an otherwise continuous bit stream. The Receiver PLL takes some time to achieve phase and frequency lock (as described in section 3.3). After lock is achieved the TAXI Receiver must align the incoming data to the proper byte boundaries. The Receiver logic compares the incoming bit stream (bit by bit and without regard for byte boundaries) with the pattern for Sync, and when it is found, forces an internal bit counter to 0. The internal counter then continues to count bits and run the byte rate logic without further reference until another Sync is found. From this description of the Sync function, it is obvious that only ONE Sync symbol is ever really required to define the byte boundary for the TAXI Receiver if the internal counter continues to count correctly. It is unlikely that the internal logic function will make a mistake, and therefore the counter will continue to count off the proper number of bits per byte forever. However, there is some chance that noise can corrupt DATA into a pattern that looks exactly like the Sync symbol. (The chance is about 0.13% of all possible error types.) When this happens, the byte boundary is forced to an incorrect position, and all data following is decoded incorrectly. TAXI Receiver violation detection logic may or may not flag the errors, but the Receiver cannot distinguish properly framed data from incorrectly framed data. The only thing that can correct this running error is another Sync. The minimum number of Syncs required in a user data stream is dictated by the system sensitivity to running errors, and the system’s built in error detection mechanism. However, it is a good practice to send a Sync every 1000 bytes. Systems that send packetized data, should allow a Sync between each packet. This will assure that if an error occurs, it will be terminated at the end of the packet and will not corrupt the succeeding packets. Systems that send data at a rate slower than the TAXI byte rate will have Sync automatically inserted as pad characters, so the user may not need to specifically insert them. Systems that send byte or short phrase data (commands or control words, for example) might send a Sync before each byte or phrase to assure that the message is not missed because of an earlier framing error. From this discussion it should be clear that there is no RIGHT NUMBER of Syncs to send with TAXI data. The correct number is dependent on the type of data the user is sending, and the system sensitivity to running errors. TAXIchip Integrated Circuits Technical Manual 97 AMD TAXI Technical Information Publication #89-04 Subject: TAXI PLL Lock-Up During Power-On! Question: Is there a recommended power-on sequence for the TAXIchips to prevent PLL lock-up? Answer: Early versions of the -70 TAXIchips did have some sensitivities associated with hotplug-in lock-up, fast VCC rise time, and/or power supply sequencing during power-on causing occasional PLL lock-up. These potential problems were addressed in the -125 TAXIchips with an improved circuit design. The -125 TAXIchips do not exhibit any known power-on problems, but a PLL Reset function is available on a package pin and may be used to restart the PLL if problems occur. Use of the external PLL Reset pin should not be necessary with the -125 TAXIchips, but there may be specific situations where its use may be helpful with the TAXI Receiver. There are possible situations where large amounts of noise may occur on the Receiver serial data inputs. Under these conditions the Rx-PLL may attempt to track the noise to an indeterminate frequency. This deviation in frequency may adversely affect data recovery when a good data stream reappears. System requirements may also place a restriction on the allowed clock frequency deviation. Use of the PLL Reset function on the Receiver may assist in the containment of some of these effects. All VCCs may be powered-on simultaneously with a common supply. It is only recommended that the TAXI GND pins be connected to a common Ground and the V CC pins be separately filtered and decoupled to that Ground. Variations in power-on times due to separate VCC filtering and decoupling are not a problem. Use of a common VCC supply is sufficient as long as noise filtering of the supply at the TAXI V CC pins is adequate, therefore use of separate power supplies for the VCCs is usually not necessary. Refer to Section 6.1, for more information concerning power supply layout and decoupling. Further information is also available in TAXI TIP #89-02, TAXI Receiver RESET Pin Function. 98 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-05 Subject: TAXIchip Set Crystal Specification Question: What are the design considerations for crystals used with TAXIchip set? Answer: The TAXIchip’s parallel mode oscillator uses a 4.0 MHz – 17.5 MHz crystal with a frequency tolerance of 0.1%. Any crystal will oscillate in either series or parallel mode depending upon the type of oscillator used. By specifying parallel mode and the load, the manufacturer will calibrate the crystal in parallel mode at the desired frequency. This could be important in applications where frequency tolerance is critical due to the fact that the resonant frequency in parallel mode is typically 0.02% above the series mode frequency. As discussed in section 3.3, the time required to synchronize the data recovery circuit in the Receiver is proportional to the delta between the Transmitter frequency and the Receiver PLL resting frequency. The Receiver resting frequency is typically less than ±1% away from its own crystal frequency, due to mismatch between internal circuits. The crystal specification of 0.1% is meant to be small enough to cause a negligible effect on lock time while not increasing the crystal cost (0.025% crystals are quite common). Sometimes tighter frequency and tolerance specifications may be necessary to meet the user’s system requirements (i.e. FIFO depth, etc.). More information on crystal specifications for the TAXIchip set may be found in Section 4.1.1. A partial list of vendors follows: Distributor Typical 12.5 MHz Part Number Phone Number I.E.A. Calmax Corp. Monitor Products Anderson Electronics Target Electronics HC18U 12.500 UM-12.5 MM 49XlE12A-12.5 011-668-03260 CC025A-12.5 (408) 435-1000 (714) 957-1299 (619) 433-4510 (814) 695-4428 (408) 733-0384 TAXIchip Integrated Circuits Technical Manual 99 AMD TAXI Technical Information Publication #89-06 Subject: TAXl for FDDI Applications? Question: Can the TAXIchip set be used for FDDI physical layer applications? Answer: The TAXIchip set is code compatible with the FDDI physical layer but there are restrictions in the design which would cause difficulty in using the TAXIchip set for the physical layer of an FDDI node. The TAXIchip set by itself cannot be used to build a fully compliant FDDI node, although it provides several of the functions required. The TAXI Transmitter is compatible with FDDI at the physical layer electrical interface and can send all codes specified by FDDI. An exception to the encoding is that QuietLine-State (QLS) is defined as fiber-dark for FDDI, requiring a static SEROUT=LOW, and the Transmitter defines the equivalent of QLS, as Command F, as no-transitions, with no control of the static logical state. The TAXI Receiver is also compatible with FDDI at the physical layer electrical interface and can recognize the codes specified by FDDI, with restrictions. The restrictions concern Master-Line-State (MLS), Halt-Line-State (HLS), and the carrier detect function. MLS and HLS are terms describing a data stream composed of a consecutive string of HQ and HH symbols respectively, representing a line-state condition. The Receiver will decode these symbols, but it does not count them to signal line-states as required by FDDI. MLS and HLS are relatively long run-length signals with 10 and 5 bit-times between transitions respectively, as compared to a maximum limit of 3 bit-times for data. The Receiver PLL was designed for wide operating frequency range, with tradeoffs in the ability and time required to capture long run-length data sequences. The FDDI specification allows 100 µs for the Receiver to lock upon and detect MLS following a long period of QLS. A typical TAXI Receiver will meet these criteria but the production parts are neither tested nor guaranteed for this condition. There are no problems associated with tracking the MLS signal once the PLL has acquired lock. HQ and HH, within the TAXI Receiver, require proper byte framing for detection. MLS and HLS as specified by FDDI are not framed, therefore the transition may be located at any of the ten bit locations. The result, as decoded within the TAXI Receiver, will be as follows: MLS: HLS: 00100 00000 00000 00100 all other 00100 00100 all other = = = = = HQ QH HH CMD-A CMD-D Violation CMD-8 Violation 10% probability 10% probability 80% probability 20% probability 80% probability The FDDI line state definition does not preclude the insertion of an occasional sync into the MLS or HLS data stream for proper framing, solving the recognition problem. If full FDDI compliance is required, MLS and HLS must be detected external to the TAXIchip set. The carrier detect function, as specified by FDDI, requires the flagging of a QLS to the MAC layer as long as the fiber is dark. The TAXI SERIN inputs must be static for this condition to be met by the TAXI Receiver. This problem must be addressed directly by the Optical receiver or gating of its outputs. Functions of the FDDI MAC layer interface are not directly addressed in the TAXI designs. 100 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-07 Subject: Synchronous vs. Asynchronous Strobe Question: When should synchronous vs. asynchronous strobing be employed? Answer: Inputs to the TAXI Transmitter can be strobed asynchronously, but with some limitations. In local mode, the STROBE edge can rise at any time, without regard for placement within any particular byte. The data associated with the STROBE (STRB) will be latched into the Transmitter, and will be transmitted at the earliest opportunity. If some system limitation insures that a second STRB cannot ever be within the same byte time (80.0 ns at 125 MHz), then there is no need to observe the ACK output of the TAXI Transmitter. If no such guarantee exists, then ACK must be used to insure that no more than two STRBS lie within a single byte. Again there is no restriction on STROBE placement within a byte, since ACK will always insure that the capacity of the TAXI input buffer is not exceeded. The TAXI input buffering can handle two STRBS within a single byte, but this additional buffer must be flushed by the absence of a STRB in a given byte before another two-strobe byte is encountered. In an early revision of the 70 MHz Transmitter, there was a particular placement of STROBE with respect to the falling edge of CLK, that could cause loss of data. This lead to several revisions of technical literature mentioning the Prohibited Zone, and Uncertainty Zone. This restriction in STROBE placement has been removed in the 125 MHz version of the Transmitter. T6 in the data sheet, now refers only to the exact placement of the internal byte boundary. Knowledge of this time is only important for synchronous systems to predict in which byte the data will appear. The only restriction on Local mode asynchronous STRB input would be in systems which require contiguous data output from the TAXI Receiver. It is possible that when strobing asynchronously, there will be an occasional byte with no strobe, and another nearby byte with two strobes. The Transmitter has sufficient buffering to handle this condition, but will pad the missing byte with a Sync character. For systems that have this restriction, STRB should be made synchronous with the CLK of Transmitter. TAXIchip Integrated Circuits Technical Manual 101 AMD TAXI Technical Information Publication #89-08 Subject: TAXI Receiver Lock Time Question: In a fully operational system in which both the Transmitter and Receiver are powered on, how long will it take for the Receiver to lock to new data after a quiet line? Answer: When data transmission stops and the link becomes quiet, the TAXI Receiver PLL will drift to its natural resting frequency which by design, is less than 3% away from the reference frequency applied at the X1 pin. When data appears on the line, the Receiver PLL will achieve phase lock in a time which is proportional to the incoming data edge density and PLL loop bandwidth. Because this lock time is dependent on the data being transmitted, the time it takes for the receiver to lock will depend on the specific system application. In Section 3.3, three types of data are represented and their calculated lock times are shown. By dividing the lock time for a specific data pattern by the X1 clock period, the number of bytes to lock the PLL can be calculated. Because time to lock is dependent on many variables, it is represented as a typical time. If time to lock is critical to the specific application, we suggest you allow at least the times shown. Although there is no guaranteed specification for time to lock, a test is run (using a JK pattern) as part of AMD outgoing tests to ensure that all devices can achieve lock within a reasonable time. The test is performed by sending JKs for 640 µs, and then without interruption, a full rate functional test is run. For the test to pass, the PLL must lock to the JK pattern and then track the incoming data perfectly. 102 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-10 Subject: TAXI Receiver CSTRB and DSTRB Pulse Width Question: What is the maximum CSTRB and DSTRB pulse width? Answer: The internal logic of the TAXI Receiver determines the pulse width of CSTRB and DSTRB based on the timing of an internal clock (Bit Clock). Under normal conditions, the pulse width will be 4-bit times wide in the 8-bit mode, and 5-bit times wide in the 9- and 10-bit modes. An exception to this typical width is upon re-sync which can cause the pulse to be expanded by up to 5 bit times as the byte boundaries are re-aligned to the incoming data stream. The number of bit times used to represent data differs based on the operational mode; in 8-bit mode, data is encoded into 10 bits, in 9-bit mode 11-bits, and in 10-bit mode 2 bits. For example, a Receiver operating with a 12.5 MHz crystal and utilizing 8-bit mode will have a clock period of 80 ns (1/12.5 MHz = 80 ns). Internally the Receiver divides this period by 10, forming the internal bit boundaries used to represent the encoded data. This example yields a 8 ns (80 ns/10 = 8 ns) bit period, which translates to a internal clock rate of 125 MHz (1/8 ns = 125 MHz). Figure 11. shows a timing diagram of a TAXI Receiver internal clock and its relationship to CLK, Data, and Strobe outputs. The Receiver utilizes this divided clock to define its internal logic states. The CSTRB and DSTRB signals are generated by using these logic states and have a fixed relationship to the incoming encoded data. The figure shows that from the beginning of the byte (state 0), the CSTRB or DSTRB delay is two internal clock periods before going high, and the signal remains high for four internal clock periods then returns to a low logic level. Actual pulse width will vary from this ideal width due to signal rise and fall delay, propagation delay and effects of loads external to the Receiver. The data sheet parameters reflect these delays and normal manufacturing guard bands. TAXIchip Integrated Circuits Technical Manual 103 AMD Figure 11 (8-Bit Mode Example) TAXI Receiver Internal Clock Distribution 9 0 1 2 3 4 5 6 7 8 9 0 1 2 Internal Bit Clock Internal Clock (Byte Rate) External Clock (CLK) Internal CSTRB & DSTRB External CSTRB & DSTRB Internal Data External Data 12330E-40 104 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-11 Subject: Using Receiver CLK Output to Run a TAXI Transmitter Question: Is it possible to use the Receiver CLK output to drive the X1 input of a TAXI Transmitter? Answer: To assure accurate transmission of data, the Transmitter must have a stable, jitter free, byte rate reference to its multiplying PLL. This is typically derived from a crystal and can be connected to any crystal controlled and noise free TTL source. The Receiver synchronizes its internal clock with the incoming signal and recovers data and clock for use by the receiving host system. In the process of sending high speed data over typical serial links, the data may be affected by noise from various sources. The PLL in the Receiver removes this noise and delivers a synchronized clock to the Receiver logic and to the host system. However, some of the noise may feed through the PLL and appear on the CLK output. The CLK output can jitter as much as 2 ns when recovering data from a noisy link. This will not typically affect normal logic functions, and can be ignored. If the Receiver must realign its byte boundary, it will stretch CLK to the new alignment position and thus protect the host logic from shortened CLK cycles. These noise and phase jumps make the Receiver CLK output undesirable for use as a Transmitter frequency source. For systems that MUST use synchronized clocks (for example to avoid FIFO re-timing logic) it is possible to filter the Receiver CLK output and make an adequate reference for the Transmitter. There are two basic approaches to provide this filter. The first is to use a crystal filter (Figure 12). When placed between the Receiver CLK and Transmitter Xl, the crystal filter can be effective in attenuating system jitter to levels nearly comparable to crystal controlled reference clock levels. By the nature of a crystal filter, as the frequency of the crystal used in the filter and the data rate frequency vary, the phase of the output varies. This will make the filter seem to have a variable delay (+ or -) which must be accommodated by the users logic. The second method is to use a PLL tracking filter (Figure 13). The jitter attenuation through the PLL is less than that through the crystal filter because the PLL has a bandwidth several orders of magnitude larger. The PLL provides a solution whose merits lie between the simplicity of the crystal filter and the need for tight crystal tracking and matching. The PLL filter is relatively straight forward. Attention to proper grounding and board layout should be followed. The PLL filter is more tolerant of component and environmental variations than the crystal filter. TAXIchip Integrated Circuits Technical Manual 105 AMD Figure 12 Crystal Filter +5 V SEROUT + SEROUT - SERIN + SERIN - Am7968 Transmitter CLK X1 X2 Am7969 Receiver CLK X1 X2 1 µF 2 4 pF SEROUT + SEROUT - 300 300 300 3 + LT1016 - 1 Am7968 Transmitter CLK X1 X2 7 SERIN + SERIN Am7969 Receiver CLK X1 X2 4 5 6 300 GND Crystal Filter 12330E-41 Note: All crystals used are of same type. Figure 13 PLL Filter +5 V 50 GND SERIN + SERIN – VCC GND V Am7969 TAXI Receiver X1 X2 1 µF 15K U1 VCC VCM2 - MC4044 D1 CLK 15K 4.7K R GND GND 15K 4.7K 15K 50 V+ GND LMC660C V+ 50 pF MC4024 VCX2 OUT 2 CX2 GND SEROUT + SEROUT – Am7968 TAXI Transmitter X1 CLK X2 1 µF GND Notes: 1. Filter components were chosen for the following loop parameters: Noise Bandwidth = 10 kHz Damping Factor = 0.5 Natural Frequency = 3.18 kHz 2. Refer to Motorola MC4024, MC4044 and National LMC660C data sheets for specifications. 106 TAXIchip Integrated Circuits Technical Manual 12330E-42 AMD TAXI Technical Information Publication #89-12 Subject: TAXlchip Pins Internal Circuit Question: What do the TAXIchip I/O circuits look like? Answer: There are five different input circuits and two different output circuits in the TAXIchip set. Each I/O circuit has Electro Static Discharge (ESD) protection circuit attached to it. The five input types are: TTL Input, ECL Input, Three State Input (TSI), High Threshold Input (HTI), and Oscillator (OSC). The two output types are: TTL Output and ECL Output. Each I/O circuit and the ESD circuit are shown on the following page. The following table lists all Transmitter and Receiver pins and their I/O type. Transmitter Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 Receiver Pin Name ACK STRB SEROUT+ SEROUT– VCC2 VCC1 VCC3 RESET DMS CLS SERIN CI0 CI1 DI9/CI2 DI8/CI3 DI7 DI6 CLK X2 X1 GND2 GND1 DI0 DI1 DI2 DI3 DI4 DI5 I/O Type TTL OUT TTL IN ECL OUT ECL OUT 5V 5V 5V HTI TSI TSI ECL IN TTL IN TTL IN TTL IN TTL IN TTL IN TTL IN TTL OUT OSC OSC GND GND TTL IN TTL IN TTL IN TTL IN TTL IN TTL IN Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 Pin Name DO3 DO2 DO1 DO0 IGM RESET VCC1 VCC2 SERIN+ SERIN– DMS DSTRB CSTRB VLTN CO0 CO1 DO9/CO2 DO8/CO3 CLK GND1 GND2 X1 X2 CNB DO7 DO6 DO5 DO4 TAXIchip Integrated Circuits Technical Manual I/O Type TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT HTI 5V 5V ECL IN ECL IN TSI TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT GND GND OSC OSC TTL IN TTL OUT TTL OUT TTL OUT TTL OUT 107 AMD VCC 22K 11K TTL IN ESD 12330E-43 GND GND ESD 12330E-44 TTL IN VCC VCC C C 300 ECL IN 300 17K ESD DMS/CLS IN 9K 50K ESD GND GND 12330E-45 ECL IN 108 12330E-46 Three-State IN TAXIchip Integrated Circuits Technical Manual AMD VCC 3K 3K X1 ESD 125 5.3K 48K RESET GND REF. 125 X2 ESD 125 ESD GND 12330E-47 GND 12330E-48 Oscillator HIGH Threshold IN VCC VCC 50 300 300 ECL OUT ESD ECL OUT TTL OUT ESD ESD 12330E-49 GND 12330E-50 GND TTL OUT ECL OUT TAXIchip Integrated Circuits Technical Manual 109 AMD TAXI Technical Information Publication #89-13 Subject: Demuxing A TAXIchip Receiver Output to Multi-Byte Words Question: How can a single TAXI Receiver be used to receive multi-byte words? Answer: INTRODUCTION For systems that require data reception wider than a single byte, a single TAXI Receiver can be used to cascade the multiple bytes. This operation allows the data to be demultiplexed from a single serial link and used by an external system. In the following example, data is captured sequentially and output in the form of four 8-bit words. Commands, which can also be transmitted are not used in this example in order to clarify the basics of the technique. Some simple modifications to include commands will be presented at the end of this technical note. The circuit shown in Figure 14 illustrates the logic configuration that has been built and tested in the laboratory using nominal commercial parts. The circuit handles blocks of data typically ranging from four bytes to 64K bytes. The TAXI Receiver converts the serial information that is received by the SERIN+/– inputs to the data information that is output by the D0–D7 Data pins, C0–C3 Command pins, and the DSTRB, CSTRB, and VLTN pins. This data information output by the single receiver is used by the controller to capture the incoming data and output it four bytes at a time. FUNCTIONAL DESCRIPTION Controller Circuit: The controller consists of a shift register constructed of four D flip-flops and a 3-input NOR gate. The shifter is loaded with a 1 that progresses through the flip-flops sequentially clocking the first column of four registers which capture the incoming data. When the 1 is shifted through the fourth flip-flop, it raises the PCO signal for the CLKOUT D flip-flop. On the following rising edge of the /CLK signal the bytes of cascaded data are simultaneously clocked out through the second column of four registers that buffer the cascaded data to the outside system. Controller Clock: The clock for the controller circuit is generated by OR-ing DSTRB and CSTRB. This ensures that the DSTRB signal is captured for output to the external system. These signals also prepare the way for a simple upgrade to allow the use of commands (explained later). Sync Commands: When not receiving blocks of data, Sync Commands (bytes) are received which keeps the TAXI Receiver locked onto the correct byte rate and byte boundaries. This ensures proper capture of the data at the beginning of the next block. In addition, before a block of data is to be sent, a Sync Command must be received to reset the counter to the proper byte alignment and initialize the system. The Sync Commands are sent by default in the system because they are automatically inserted whenever a byte time passes without a STRB (no data to send) pulse at the transmitter. It is important to note that the Receiver generates a CSTRB and outputs zeros on the Command lines when a Sync Command is received. 110 TAXIchip Integrated Circuits Technical Manual OSC VCC GND CLR NC VCC CNB DMS VCC VCC1 SERIN- VCC2 X1 CO0 CO1 CO2 CO3 TAXI_CLK DSTRB CSTRB IGM CLM VLTM /RESET X2 SERIN+ /CLK Buffers Q CLR D CLR_CNTR CLK_CNTR CHMNDO PRB QB CLK TAXI RX Q CLR D SYNC QB Q QB CLR D CLK1 D Q QB QB CLR Q CLK3 CLR D CLK2 4-Byte Demux Cascade Receiver PRB AM7969 008 001 002 003 004 005 006 007 PRB CLK PRB CLK PRB TAXIchip Integrated Circuits Technical Manual CLK Controller Block CLK4 Q QB CLR PCD D PRB OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP Data Output Registers OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP Data Capture Registers D0 - BYTE 3 D7 VLTN DSTRB D0 - BYTE 2 D7 VLTN DSTRB D0 - BYTE 1 D7 VLTN DSTRB D0 - BYTE 8 D7 VLTN DSTRB 12330D-61 OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 Y5 d5 Y6 d6 Y7 d7 Y8 d8 Y9 d9 CP GND OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 Y5 d5 Y6 d6 Y7 d7 Y8 d8 Y9 d9 CP GND CLKOUT OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP Figure 14 CLK OE VCC d0 Y0 Y1 d1 d2 Y2 Y3 d3 d4 Y4 d5 Y5 Y6 d6 Y7 d7 d8 Y8 Y9 d9 GND CP AMD Logic Diagram of Cascaded Data with One TAXI Receiver 12330E-51 111 AMD The circuitry that handles the Sync Commands or Sync Bytes generates several signals. The CMND0, CLR_CNTR, Sync and PCO are the signals that are generated by Sync Command logic. The CLR_CNTR signal is generated from the CMND0 and the CSTRB signal which signify a Sync Command has been received. CLR_CNTR clears the controller and then is latched by the rising edge of the Receiver CLK to form the Sync signal. The Sync signal then generates an active PCO signal. The CLKOUT is then driven High on the following rising edge of CLK if CLK4 has not already driven the CLKOUT signal High. The Sync Command only clocks out the data when it is received before the fourth byte of data has been received. In all other cases, the data is clocked out by the logic involved with the fourth state of the controller. The Sync Commands that follow this Sync Command hold the CLKOUT signal High to effectively hold the controller circuitry in a constant state of reset with no change to the output data. Buffering: The buffering of signals should also be considered for this design. In this example, the data outputs from the TAXI Receiver drive the first column of four low power registers. This design does not exceed the driving capacity of the Receiver, but if different parts are used, load calculations should be redone. This system should work with any standard logic, although logic families should not be mixed unless timing considerations have been made. This particular example uses low power Schottky devices with relatively fast low power output registers. TIMING CONSIDERATIONS Some critical timing considerations must be met to ensure the proper operation of this design. In order to capture the DSTRB signal, the timing of DSTRB going active and the rising edge of the CLKx signals from the controller must agree with the setup and hold times of the first column of registers. To ensure capture of Sync Commands, the CLR_CNTR signal becoming active and the rising edge of the Receiver CLK must agree with the setup and hold times of the Sync flip flop. To prevent glitches on the CLKx signals and the potential capture of incorrect data, the timing between CLK_CNTR rising and CLR_CNTR becoming active must be considered, CLR_CNTR needs to become active at a time before CLK_CNTR can effect the output of CLKx. The timing diagram is shown in Figure 16. Figure 16 shows the timing of the system where one Sync Command is received between data blocks being received. The premature Sync Command is not shown, but can be derived by following the given timing diagram and known responses of the logic given in Figure 15. UPGRADE NOTES Command Line Handling: To add the capability to receive Commands in this design, only a few additions are necessary. Since this design uses 8-bit data mode, 4-bit commands can be used. It will be necessary to add command storage registers four bits wide as well as command output registers four bits wide to output these Command lines correctly. The CLKx signals as well as the CLKOUT signals for the existing registers need to be connected to these new registers. The CLKx signals may need to be buffered to meet fanout limitations of the controller circuitry. Control Signals: The signals that need to be output by the new features do not add to the logic. The circuitry to capture the CSTRB signal is already designed into the system. The DSTRB signal can be used as a CSTRB indicator, active Low, as well as a DSTRB indicator, 112 TAXIchip Integrated Circuits Technical Manual AMD active High, without any additional logic. The VLTN signal is used for both Command and Data violations. Buffering of the DSTRB and VLTN signals may be necessary as illustrated in Figure 15 to meet the drive requirements of the first column of registers. Data/Command Output Note: In this system, when a nonSync Command byte is received the data line values corresponding to that byte will change to the values last output from the TAXI Receiver data lines. Conversely, when a data byte is received the command line values for that byte will change to the values last output from the TAXI Receiver command lines. This is a characteristic of the example given and depends on how the command and data information is latched. Altering the Number of Output Bytes: The above described design is an example of a four byte cascaded serial data receiving system. The same design techniques can be used to expand or reduce the number of bytes output at a time by the system. The considerations that should be taken into account for an altered system deal with board space and part cost in accordance with the requirements of the situation at hand. For board space note see the PAL Usage section below. PAL Usage: In this system, the use of a PAL could greatly reduce the amount of board space used. The PAL could incorporate all of the flip-flops and buffering logic as well as the first column of registers that capture the system information. The reason a PAL was not used in the system described above was to help ensure the understanding of the design concept. For this application it is recommended that the timing considerations mentioned before should be investigated to ensure proper operation of the system. TAXIchip Integrated Circuits Technical Manual 113 AMD Figure 15 Timing Diagram of 4-Demux Cascaded Receiver TAXI CLK /CLK 4 1 2 Byte 4 Byte 1 Byte 2 3 4 Sync 1 2 3 DSTRB CSTRB RCVR DATA Byte 3 Byte 4 Byte 1 Byte 2 Byte 3 CLKCNTR CLK1 CLK2 CLK3 CLK4 CLKCNTR PCO Sync CLKOUT DATA OUT Valid Data (for all four bytes) 12330E-52 114 TAXIchip Integrated Circuits Technical Manual AMD TAXI Technical Information Publication #89-14 Subject: 32-Bit Multiplexed Cascade with the TAXIchip Transmitter Question: How can a single TAXIchip Transmitter be used to send n-byte data words? Answer: I. INTRODUCTION Many systems have DATA/CMD paths wider than the twelve lines available per TAXI Transmitter. AMD TAXI applications has designed a circuit which economically multiplexes data words longer than eight bits using one TAXI Transmitter. The following discussion is specifically for an Am7968 Transmitter with a 32-bit data word, but is also applicable to systems with shorter or longer data words (with or without commands). II. ADVANTAGES There are several advantages to using the multiplexed data scheme utilizing one TAXI Transmitter as opposed to a system using several Transmitters: 1) To implement the mux circuit for 32 bits requires one Am7968 TAXI Transmitter and three relatively small integrated circuits. A 32-bit wide data path without multiplexing requires four Am7968 TAXI Transmitters. 2) Four Am7968 TAXI Transmitters require more board real estate than three SSI parts and one TAXI Transmitter. 3) Four Am7968 TAXI Transmitters will dissipate about 3.5 W, while one Am7968 and three SSI chips dissipate only 1.25 W. The power saving is even more dramatic if optical data links are being used. A design using four TAXI Transmitters and four Am79h1000T optical data links would dissipate over 5 W of power. The same 32-bit wide system using the multiplexing circuit would dissipate only 2.6 W! III. IMPLEMENTATION Implementation of the 32-bit multiplexed transmitter circuit is straightforward. (See Figure 11). In addition to the Am7968 TAXI Transmitter, the following parts are required: (1) 74LS00 (1) 74LS20 (1) 74LS174 A group of buffers with tri-state outputs (four Am29C821s in this example), would likely be required in any type of point to point communication application and might already be available in the host system. Additionally, a number of termination resistors are required. The number and values are dependent upon the type of coupling and the media used. IV. OPERATION Referring to Figure 15, the data to be transmitted is assumed to be simultaneously loaded into the buffers when a strobe pulse is input to the system. The controller for the mux is the 74LS174, which is wired as a shift register. As a 0 (which occurs on strobe) is shifted through the register, each buffer is enabled in turn. The NAND gate (U1) at the input of D1, ensures that only a single 0 is possible while the registers are being selected. The TAXI CLK signal, which is used to clock the 74LS174, is inverted to provide set-up time to ensure that no false strobes reach the TAXI Transmitter. The other four-input NAND gate (U2) enables the two-input NAND gate (U3), so that the Transmitter will be strobed while there is data available in the buffers. TAXIchip Integrated Circuits Technical Manual 115 AMD Jumpers are provided on the outputs of Q4 and Q5 to be inverted (U7) and fed back to the first NAND gate (U1). If Q4 is shorted back to the strobe input, the system will run in auto-repeat ACK 0 mode. This means that there will be a strobe on every clock cycle. In this mode a sync will never be sent. If the output of Q5 is shorted back to the strobe input, the system will run in auto-repeat ACK 1 mode. This means that a sync will be automatically inserted in between each group of four data bytes. On the receiver end of the link, the option is left up to the designer to either use four Am7969 TAXI Receivers or to demultiplex the data and use only one Receiver. Figure 16 has been included to give a detailed schematic of the circuit with an Am7969 TAXI Receiver on-board to complete the data path. Figures 17, 18, and 19 show typical outputs for auto-run ACK0, auto-run ACK1 and Normal run modes. V. CONCLUSION To increase the length of a data word beyond eight bits, multiplex the data into an Am7968 TAXI Transmitter. This method uses less power, less board space, and lowers the parts cost of the system. 116 TAXIchip Integrated Circuits Technical Manual D24 D25 D26 D27 D28 D29 D30 D31 D16 D17 D18 D19 D20 D21 D22 D23 TAXIchip Integrated Circuits Technical Manual GND 1 2 3 4 5 6 7 8 9 10 11 12 GND 1 2 3 4 5 6 7 8 9 10 11 12 GND 1 2 3 4 5 6 7 8 9 10 11 12 GND 1 2 3 4 5 6 7 8 9 10 11 12 AM29C821 U3 24 OC/VCC 23 D0 Y0 22 D1 Y1 21 Y2 20 D2 D3 Y3 19 D4 Y4 18 D5 Y5 17 Y6 16 D6 Y7 15 D7 Y8 14 D8 Y9 D9 13 GND CP AM29C821 U4 24 OC/VCC 23 D0 Y0 22 D1 Y1 21 Y2 20 D2 D3 Y3 19 D4 Y4 18 D5 Y5 17 Y6 16 D6 Y7 15 D7 Y8 14 D8 Y9 D9 13 GND CP AM29C821 U5 24 OC/VCC 23 D0 Y0 22 D1 Y1 21 D2 Y2 20 D3 Y3 19 D4 Y4 18 D5 Y5 17 Y6 16 D6 D7 Y7 15 Y8 14 D8 Y9 D9 13 GND CP AM29C821 U6 24 OC/VCC 23 D0 Y0 22 D1 Y1 21 D2 Y2 20 D3 Y3 19 D4 Y4 18 D5 Y5 17 Y6 16 D6 D7 Y7 15 Y8 14 D8 Y9 D9 13 GND CP 4 4 4 4 4 4 4 4 JMP2 U11 GND U10 AM7966 1 1A VCC 2 4B 3 1B 4A 4 1Y 5 2Y 4Y 6 2A 3B 7 3A 2B GND 3Y GND 74LS0O ACK STRB SEROUT+ SEROUTVCC2 VCC1 VCC3 RESET/ DMS CLS SERIN C10 C11 D19/C12 14 13 12 11 10 9 8 10 2B 9 2A 8 2Y 14 VCC 13 2D 2C 12 74LS2O U2 28 D15 27 D14 26 D13 25 D12 24 D11 23 22 D10 GND1 21 GND2 20 X1 19 X2 18 CLK 17 D18 16 15 D17 D18/C13 GND 4 5 1C 6 1D 1Y 7 GND U9 1 1A 2 1B 1 2 3 4 5 6 7 8 9 10 11 12 13 14 U1 D1 D2 D3 D4 D5 D6 S2 D1 D2 D3 D4 D5 D6 138 74LS174 9 CLK 1 CLR 3 4 5 11 13 14 V C C 4 PWR ACK0 ACK1 3 GND 2 C UB L DSC G K N D GND 138 12330D-63 SERIN+ SERIN- To Coax or Fiber Media JMP3 U12 S2 PWR 10 12 15 2 5 Figure 16 D8 D9 D10 D11 D12 D13 D14 D15 D0 D1 D2 D3 D4 D5 D6 D7 STRB AMD 32-Bit Multiplexed Transmitter Circuit 12330E-53 117 AMD Figure 17 AUTORUN ACK 0 (No Sync Between Data Bytes) D7 D6 D5 D4 D3 D2 D1 D0 STRB TXCLK CSTRB DSTRB 12330E-54 Figure 18 AUTORUN ACK 1 (One Sync Between Every Four Data Bytes) D7 D6 D5 D4 D3 D2 D1 D0 STRB TXCLK CSTRB DSTRB 12330E-55 118 TAXIchip Integrated Circuits Technical Manual AMD Figure 19 Normal Run Mode (Transmission of Syncs Depends on Host) D7 D6 D5 D4 D3 D2 D1 D0 STRB TXCLK CSTRB DSTRB 12330E-56 TAXIchip Integrated Circuits Technical Manual 119 AMD TAXI Technical Information Publication #89-15 Subject: General Device Information for 125/175 MHz TAXIchips This T.I.P. provides general information about the design and manufacturing of the 125 MHz and 175 MHz TAXIchips. The information is separated into three categories: Design, Wafer Fab, and Assembly/Packaging. Design: Product P/N: Die Number: Chip Dimensions: # NPN Transistors: # PNP Transistors: # Resistors: # Diodes: Equiv. Gate Count: I/O Schematics: Transmitter (TX) Receiver (RX) Am7968-125 Am7968-175 4768 Am7969-125 Am7969-175 4769 170 x 167 mils2 3386 14 2504 87 595 196 x 187 mils2 4384 24 3556 76 720 See TAXI TIP #89-12 Supply Currents: Transmitter: Receiver: Typical Values (mA), VCC = 5.5 V Process=Nominal, CD 028 package, Temp. forced with moving air flow (approx. thetaJMA= 20°C/W) –55°C 0°C 25°C 70°C 125°C 230 215 203 187 178 272 250 237 212 182 Wafer Fab: 120 Location: Fab 2A, San Antonio, TX (formerly Fab 11) Process ID: Bipolar IMOX–S2: 402L–1156 Metal One: TiW (barrier metal): 1800 A nom. thickness AlCu: 1.0% Cu, 8000 A nom. thickness Pitch = 4 µ Metal Two: AlCu: 1.0% Cu, 15500 A nom. thickness Pitch = 8 µ Passivation: Silox/Nitride dual layer. 7500 A nominal thickness Nitride: 6800 A nominal thickness TAXIchip Integrated Circuits Technical Manual AMD Assembly/Packaging: CerDIP (CD 028) LCC (CLT028) PLCC (PL 028) Assembly Location: Manila Bangkok Ld. Frame Material: Bond Wire: CD: Alloy 42 1.25 mil Al/Si (1% Si) Ultrasonic Ag Glass N/A Copper 1.25 mil Au Ball Bonding Ag Filled Epoxy Sumitomo 6300H CD 028 Comm.: Tin Plate CD 028 Mil.: CLT028 Mil.: Solder Dip Solder Dip PL 028: Solder Plate Bonding Method: Die Attach: Molding Compound: Lead Finish Thermal Impedance: CD 0281 CLT0282 PL 0282 θJA TX : RX: 41°C/W 43°C/W n/a n/a 53°C/W 52°C/W θJC TX, RX: 4°C/W 10°C/W 12°C/W 1 2 socketed surface mounted TAXIchip Integrated Circuits Technical Manual 121 AMD TAXI Technical Information Publication #89-Nov ’89 Subject: TAXIchip Error Rate Example INTRODUCTION A method was devised to establish a baseline TAXIchip set error rate. A series of tests were conducted at a transmission rate of 125 MHz at room temperature, and various power supply voltages. The data collected will be used to determine fiber optic and wire interconnect BER (Bit Error Rate) tests to be completed at a later date. METHOD The test method used the TAXI Transmitters and Receivers to transfer data continuously for at least one thousand hours per pair with different VCC conditions. To implement this test, five TAXI K2 boards were used. Each board includes a TAXI Transmitter with a ROM data source, and a Receiver with a ROM data checker to test data integrity on every byte. They were set up according to the diagrams in Figure 20, and interconnected with AC coupled short coax lines. In Setup 1, a single power supply with 5 V VCC was attached to TAXI K2 board #1. Board #1 ran independently with the SEROUT+/– connected to its SERIN+/– with 50 Ω coaxial cables. Setup 2 had oscillating voltages (4 V to 6 V) connected to the V CC of TAXI K2 boards #2 and #3. The SEROUT+/– of board #2 were connected to the SERIN+/– of board #3, and the SEROUT+/– of board #3 connected to the SERIN+/– of board #2, with 50 Ω coaxial cables, forming two test setups with continually varying power supply voltages. Setup 3 also uses two power supplies with one set at 4 V and the other at 6 V. These two power supplies were connected to TAXI K2 boards #4 and #5. The SEROUT+/- and SERIN+/- were connected in the same configuration as boards #2 and #3 in setup 2 with 50 Ω coaxial cables. The power supply voltages used (4 and 6 V) are outside the data sheet specification for the TAXIchip set. This test was intended to stress the parts and to simulate extreme temperature and operating conditions. These five boards were checked regularly, and the error counts were recorded. To verify that these boards were still running correctly, they were made to fail intentionally and then reset. RESULT The tests were completed after each board ran more than 1,000 hours. The table below summarizes the results. Board# 1 2 3 4 5 Hours 1,606 1,623 1,082 1,607 1,082 Errors 0 8* 0 2* 0 Notes Errors occurred between 438–558 hours Errors occurred between 438–558 hours . * One error can cause multiple error counts. These were assumed to be one error event. 122 TAXIchip Integrated Circuits Technical Manual AMD Board #4 failed on another occasion after the errors indicated above, but this failure was due to a power supply failure. Failure time was subtracted from the total run time, and errors were not indicated in the total. Also, boards #2 and #4 ran over 1,000 hours each without any error after the only noted error occurrence. CONCLUSION The fives sets of TAXI Transmitters and Receivers have run a sum total of 7,000 hours (3.15 x 1014 bytes) with two error events. Figure 20 TAXI K2 Board Transmit/Receive Section VCC VCC A B ROM TAXI TX TAXI TX ROM and Comparator 12330E-57 Note: TAXI K2 board includes both TAXI TX and TAXI RX. Each half may be used independently or with other boards with matching ROM data patterns. For the test described above, FDDI DDJ ROM patterns were used. VCC Conditions SETUP 1 SETUP 2 SETUP 3 TAXI TX 5 4–6 Variable 4–6 Variable 4 6 TAXI RX 5 4–6 Variable 4–6 Variable 6 4 TAXIchip Integrated Circuits Technical Manual 123