LXT6155LE

LXT6155 155 Mbps SDH/SONET/ATM Transceiver Datasheet The LXT6155 is a high speed fully integrated transceiver designed for 155 Mbps SDH/SONET/ ATM transmission system applications. The LXT6155 provides a LVPECL interface for fiber optics modules, and a CMI interface for coax cable drive. These circuits are implemented using Level One’s proven low power 3.3V CMOS analog and digital circuits. The transmitter incorporates a parallel-to-serial converter, a frequency multiplier PLL, CMI line encoders, and line interfaces for both coax cable and optical fiber. The receiver incorporates an adaptive equalizer, a clock recovery PLL, Loss of Signal (LOS) detector, CMI and NRZ decoders, a serial-to-parallel converter, and an SDH/SONET frame byte detector/aligner. At the system interface, the LXT6155 offers both parallel 8-bit and serial differential interfaces. The LXT6155 also operates in either Hardware stand-alone mode or Software mode. Software mode is controlled by a serial microprocessor (µP) to program formats and operating/test modes. Product Features Applications OC3/STM1 SDH/SONET Cross Connects OC3/STM1 SDH/SONET Add/Drop Mux OC3/STM1 Transmission Systems OC3/STM1 Short Haul Serial Links OC3/STM1 ATM/WAN Transmission Systems OC3/STM1 ATM/WAN Access Systems Receive clock recovery PLL Adaptive CMI equalizer Analog circuitry for transformer drive Programmable LOS function CMI encoder and decoder Serial/Parallel and Parallel/Serial conversion Byte alignment for SDH/SONET frames Two modes of operation: — Microprocessor controlled; software mode — Stand-alone; hardware mode No external crystal required. A 19.44 MHz crystal is optional Low power consumption (less than 760 mW typical) Operates from a single 3.3 V supply 64 pin LQFP package Features Complies with: — Bellcore SONET GR-253 — ITU-T G.703/813/958 STM1 Two line interface formats: — Fiber LVPECL NRZ — Coax CMI Transmit synthesizer PLL Order Number: 249612-001 January 2001 Information in this document is provided in connection with Intel® products. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Intel's Terms and Conditions of Sale for such products, Intel assumes no liability whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. 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Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800-548-4725 or by visiting Intel's website at http://www.intel.com. Copyright © Intel Corporation, 2001 *Third-party brands and names are the property of their respective owners. D atasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Contents 1.0 2.0 Pin Assignments and Signal Descriptions ......................................................8 Functional Description........................................................................................... 13 2.1 Transmitter .......................................................................................................... 13 2.1.1 Transmitted Signal ................................................................................. 13 2.1.1.1 Fiber Based G.957/GR-253 Transmission Systems ................. 13 2.1.2 Coax Based G.703/GR-253 Transmission Systems .............................. 13 2.1.2.1 CMI Encoding ............................................................................ 14 2.1.3 Tx Clock Monitoring................................................................................ 14 Receiver .............................................................................................................. 14 2.2.1 Analog Front End and Timing Recovery ................................................ 14 2.2.1.1 CMI Mode .................................................................................. 14 2.2.1.2 NRZ Mode ................................................................................. 15 2.2.2 Receive Frame Detect and Byte Alignment ........................................... 15 2.2.2.1 Loss of Signal (LOS) ................................................................. 16 2.2.2.2 Coax Interface ........................................................................... 16 2.2.2.3 Fiber Interface ........................................................................... 16 Clocks.................................................................................................................. 18 2.3.1 Parallel Mode ......................................................................................... 18 2.3.1.1 Transmit Parallel Input Clock (TPICLK) .................................... 18 2.3.1.2 Receive Parallel Output Clock (RPOCLK) ................................ 18 2.3.2 Serial Mode ............................................................................................18 2.3.2.1 Transmit Serial Input Clock (TSICLKP/TSICLKN).....................18 2.3.2.2 Receive Serial Output Clock (RSOCLKP/RSOCLKN) ..............18 2.3.3 Crystal Reference Clock (XTALIN/XTALOUT) ....................................... 19 Jitter..................................................................................................................... 19 2.4.1 Jitter Tolerance....................................................................................... 19 2.4.2 Jitter Generation (Intrinsic Jitter) ............................................................ 19 2.4.3 Jitter Transfer ......................................................................................... 19 Operational Modes .............................................................................................. 19 2.5.1 Hardware Mode ...................................................................................... 20 2.5.1.1 PLL Clock Reference (CIS pin) ................................................. 20 2.5.1.2 Loopback Test (RLIS and LLIS pins) ........................................21 2.5.1.3 Line Interface Selection (MODE Pin) ........................................21 2.5.1.4 Parallel/Serial Mode Selection (SP pin) .................................... 21 2.5.1.5 Tx Amplitude Trim ..................................................................... 21 2.5.2 Software Mode ....................................................................................... 22 2.5.2.1 Serial Input Clock (SCLK) ......................................................... 22 2.5.2.2 Chip Select Input (CS)............................................................... 22 2.5.2.3 Serial Input Word (SDI) ............................................................. 22 2.5.2.4 Serial Output Word (SDO)......................................................... 22 Serial System Interface ....................................................................................... 23 Parallel System Interface .................................................................................... 23 Loopback Modes .................................................................................................24 2.8.1 Local Loopback ...................................................................................... 24 2.8.2 Remote Loopback .................................................................................. 25 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Datasheet 3 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 3.0 4.0 Register Definitions ................................................................................................ 26 Application Information ......................................................................................... 33 4.1 4.2 Fiber Optic Module Interface ............................................................................... 33 Coax Interface ..................................................................................................... 33 5.0 6.0 7.0 Test Specifications .................................................................................................. 37 Mechanical Specifications ................................................................................... 48 Notes ............................................................................................................................. 49 Figures 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 29 30 LXT6155 Pin Assignments ................................................................................. 8 LXT6155 System Interface.................................................................................. 14 Framing State...................................................................................................... 16 Criteria for LOS Output ....................................................................................... 16 Receive Frame Synchronization and Frame Pulse Position ............................... 17 Example of CMI Encoded Binary Signal ............................................................. 17 Hardware Mode................................................................................................... 20 Software Mode .................................................................................................... 23 Serial Data Output Word Structure (Read Cycle: R/W=High) ............................. 23 Serial Data Input Word Structure (Write Cycle: R/W = Low)............................... 23 Serial Interface .................................................................................................... 24 Parallel Interface ................................................................................................. 24 Local Loopback ................................................................................................... 25 Remote Loopback ............................................................................................... 25 Rx Digital 2, Register #13 (Address A=11001) .......................................... 31 3.3 V LVPECL to 3.3 V LVPECL Interface .......................................................... 34 75 W Coax Cable Interface ................................................................................. 35 Transmit Parallel Input Data Timing (See Table 28) ........................................... 38 Transmit Serial Input Data Timing (See Table 28) .............................................. 38 Receive Serial Output Data Timing (See Table 30) ............................................ 40 Receive Parallel Output Data Timing (See Table 30) ......................................... 40 Microprocessor Input Timing Diagram ................................................................ 42 Microprocessor Output Timing Diagram ............................................................. 42 CMI Encoded Zero per G.703 and STS-3 ........................................................... 43 CMI Encoded One per G.703 and STS-3 ........................................................... 43 Jitter Tolerance ................................................................................................... 44 Generation Measurement Filter Characteristics................................................. 45 Typical Coax Jitter Transfer ................................................................................ 46 Typical Fiber Jitter Transfer ............................................................................... 47 LXT6155LE Package Specification ..................................................................... 48 4 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Revision History Datasheet 5 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 6 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 1. LXT6155 Block Diagram Optional 19.4MHz crystal HWSEL XTALIN XTALOUT TXISH m Control (CS, SCLK, SDI, SDO), P Hardware (MODE0, SP, CIS, RIFE) RLIS, LLIS 4 2 TTIP1 TRING1 TTIP0 TRING0 CMI Encode 2 Control Logic Control Registers 8 TPOS, TNEG TPID Parallel/ Serial 2 TSICLKP, TSICLKN TPICLK Local Loopback Frequency Doubler x 8 Synthesizer PLL Remote Loopback RTIP RRING RXISH Adaptive Equalizer Clock Recovery PLL Equalizer Control CMI/NRZ Decode Divide 8 2 Serial/ Parallel 8 RPOCLK RSOCLKP, RSOCLKN RPOD 2 RPOS, RNEG Frame Detect & Byte Aligner Data Recovery Loss of Signal (LOS) ROFP/CMIERR LOS LOCK Datasheet 7 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 1.0 Pin Assignments and Signal Descriptions Figure 1. LXT6155 Pin Assignments ADDR0/RLIS ADDR1/LLIS TRING1 TRING0 RAGND RAGND 50 HWSEL RRING 64 63 62 61 60 59 58 57 56 55 54 53 52 51 49 RXISH TGND WELL TTIP1 TTIP0 TVCC RTIP SUB XTALIN XTALOUT TAGND TXISH TAVCC TDVCC TSICLKP TSICLKN TPOS TNEG TDGND CS/MODE SCLK/SP SDI/CIS SDO/RIFE TPID7 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 29 30 31 32 48 47 46 45 44 43 42 VBIAS ATST RAVCC LOS LOCK ROFP/CMIERR RDGND RDVCC RPOS RNEG PVCC RSOCLKN RSOCLKP GND RPOD0 RPOD1 LXT6155LE (top view) 41 40 39 38 37 36 35 34 33 TPID6 TPID5 TPID4 TPID3 TPID2 TPID1 TPID0 RPOD7 RPOD6 RPOD5 RPOD4 RPOD3 TPICLK 8 RPOCLK RPOD2 VCC Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 1. Pin # 1 2 LXT6155 Pin Descriptions Symbol XTALIN XTALOUT I/O1 AI/O Type2 Description Crystal Input/Output. These pins are connected to an external 19.44 MHz crystal. Alternately, a stable external clock signal may be connected to XTALIN with XTALOUT left open. XTALIN should be connected to TAGND and XTALOUT should be left open if the transmit input clock is used as a clock reference Transmit Analog Ground. Transmit PLL Loop Filter Pin. Connecting a capacitor to TAGND from this pin controls the Tx PLL transfer function. This pin requires a 68nF cap to TAGND. Transmit Analog Power Supply. Transmit Digital Power Supply. LVPECL Transmit Serial Input Clock, positive and negative. Differential Transmit clocks at 155.52 MHz. These pins are disabled when parallel mode is selected. Transmit Serial Input Data, positive and negative. Differential input data from an overhead terminator at 155.52 Mbps, clocked in by TSICLK. These pins are disabled when parallel mode is selected. Transmit Digital Ground. TTL Chip Select Input, software mode (HWSEL = High). Register transactions through the µP interface are initiated by the falling edge of this signal. Line Interface Mode, hardware mode (HWSEL = Low). Sets line interface mode to LVPECL (MODE = Low) or CMI (MODE = High). 3 4 TAGND TXISH S AI/O 5 6 7 8 9 10 11 12 TAVCC TDVCC TSICLKP TSICLKN TPOS TNEG TDGND CS/MODE S S DI DI LVPECL S DI 13 SCLK/SP DI TTL Serial Clock Input, software mode (HWSEL = High). Serial Microprocessor uses this pin to clock in/out data. SCLK can be from 0 to 4.096 MHz. Serial/Parallel Select, hardware mode (HWSEL = Low). When SP = Low, serial systems interface is used. When SP = High, 8 bit parallel system interface is used. 14 SDI/CIS DI TTL Serial Input Data, software mode (HWSEL = High). The serial data is applied to this pin when the LXT6155 operates in software mode. SDI is sampled on the rising edge of SCLK. Clock Input Select, hardware mode (HWSEL = Low). CIS sets the reference clock for centering the Rx PLL. If CIS = Low, then the LXT6155 uses the transmit input clock as the reference. If CIS = High, then the LXT6155 uses the crystal clock input (XTALIN) as the reference. 15 SDO/RIFE DI/O TTL Serial Output Data, software mode (HWSEL = High). The serial data from the on-chip register is output on this pin in software mode. Data output is valid on the rising edge of SCLK. This pin goes to a high impedance state when the serial port is being written to or when CS is High. Receive Input Frame Enabler, hardware mode (HWSEL = Low). The frame detection option is available only in parallel mode. If RIFE = Low, then the LXT6155 disables the frame detection, and byte alignment. If RIFE = High, then the LXT6155 enables the frame detection, and outputs RPOD bytes aligned to the SONET/SDH framer. This feature, if used, must be enabled prior to applying data to Rtip/Rring. 1. DI = Digital Input; DO = Digital Output; DI/O = Digital Input/Output; AI = Analog Input; AO = Analog Output; AI/O = Analog Input/Output; S=Supply. 2. TTL = Transistor-to-Transistor Logic (5V tolerant); LVPECL = Low-Voltage positive ECL. Datasheet 9 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 1. Pin # 16 17 18 19 LXT6155 Pin Descriptions (Continued) Symbol I/O1 DI Type2 TTL Description Transmit Parallel Input Data. Transmit data from an Overhead Terminator at parallel speed 19.44 MHz, clocked in by TPICLK. TPID7 is the most significant bit, and is the first bit to be sent. These pins should be grounded or not connected when the LXT6155 is used in serial mode. Transmit Trim Controls, in serial, hardware, coax mode only. These pins trim the amplitude of the line driver output from (nom -21%) to (nom +24%) in 3% steps. This feature is only enabled when pin #20 (TXTRIMENA) is High. TPID7/TXTRIM3 TPID6/TXTRIM2 TPID5/TXTRIM1 TPID4/TXTRIM0 20 TPID3/TXTRIMENA DI TTL Transmit Parallel Input Data. Transmit data from an Overhead Terminator at parallel speed 19.44 MHz, clocked in by TPICLK. TPID7 is the most significant bit, and is the first bit to be sent. These pins should be grounded or not connected when the LXT6155 is used in serial mode. Transmit Trim Enable, in serial, hardware, coax mode only. This pin enables the trimming of the line driver output by pins 16-19 when high. 21 22 23 24 TPID2 TPID1 TPID0 TPICLK DI TTL Transmit Parallel Input Data. Transmit data from an Overhead Terminator at parallel speed 19.44 MHz, clocked in by TPICLK. TPID7 is the most significant bit, and is the first bit to be sent. These pins should be grounded or not connected when the LXT6155 is used in serial mode. Transmit Parallel Input Clock. Parallel transmit clock at 19.44 MHz. This pin is disabled when serial mode is selected and should be grounded or not connected. Power Supply. DI TTL 25 26 VCC RPOCLK S DO TTL Receive Parallel Output Clock. Parallel receive clock as recovered from received data. The clock is nominally 19.44 MHz, synchronized with RPOD. 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 RPOD7 RPOD6 RPOD5 RPOD4 RPOD3 RPOD2 RPOD1 RPOD0 GND RSOCLKP RSOCLKN PVCC RNEG RPOS RDVCC RDGND DO TTL Receive Parallel Output Data. RPOD output aligned 8-bit bytes at RPOCLK clock rate. These pins are to be left open when serial mode is selected. RPOD7 is the most significant bit, and is the first to arrive. S DO LVPECL Ground. Receive Serial Output Clock. Serial receive clock as recovered from received data. The clock is nominally 155.52 MHz, synchronized with output serial data RPOS and RNEG. PECL Buffers Power Supply. LVPECL Receive Serial Output Data, positive and negative. These two pins provide recovered data synchronized to receive serial output clocks RSOCLKP and RSOCLKN. These pins are tristated and should be left open when parallel mode is selected. Receive Digital Power Supply. Receive Digital Ground. S DO S S 1. DI = Digital Input; DO = Digital Output; DI/O = Digital Input/Output; AI = Analog Input; AO = Analog Output; AI/O = Analog Input/Output; S=Supply. 2. TTL = Transistor-to-Transistor Logic (5V tolerant); LVPECL = Low-Voltage positive ECL. 10 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 1. Pin # 43 LXT6155 Pin Descriptions (Continued) Symbol ROFP/ CMIERR I/O1 DO Type2 TTL Description Receive Output Frame Pulse. In hardware mode (HWSEL = Low), this pin is asserted (High) on the last A2 byte in the (A1.....A1, A2.....A2) sequence in the RPOD traffic. A1=1111,0110 and A2=0010,1000 in binary. In software mode (HWSEL = High), this position is programmable. During coax operation, when frame detection is disabled (RIFE = 0 in HW/Reg #12, bit3 = 0), or in serial mode, this pin indicates CMI line code errors. These pulses are 50 ns wide (active high). One or more errors in 16 consecutive bits will causes a single pulse. Receive Output PLL Lock. A High indicates receive PLL has locked to incoming data. A Low indicates receive PLL is not locked. Loss of Signal. An alarm output signal (high) indicating incoming signal voltage is weak or incoming data does not contain enough transitions. In software mode (HWSEL = 1) this pin can be configured to combine LOS and LOCK alarms. Receive Analog Power Supply. Analog Test. For factory test purposes only; do not connect. Analog Analog Bias Input Voltage. This pin requires a 15K (1%) pull-down resistor to RAGND. Rx PLL External Cap. Connecting a capacitor to RAGND from this pin controls the Rx PLL transfer function. This pin requires a 330nF cap to RAGND. Receive Analog Ground. Analog Receive Input Data, positive (RTIP) and negative (RRING). Accepts incoming signals (LVPECL or CMI) from the line interface. Receive Analog Ground. TTL Address 0, software mode (HWSEL = High). This pin together with ADDR1 sets the chip select address. Up to 4 LXT6155 chips can be addressed by the µ P interface. Remote Loopback Input Select, hardware mode (HWSEL = Low). Together with LLIS sets LXT6155 in a loopback test mode. See Table 4 44 45 LOCK LOS DO DO TTL TTL 46 47 48 49 RAVCC ATST VBIAS RXISH S AI A0 50 51 52 53 54 RAGND RRING RTIP RAGND ADDR0/RLIS S AI S DI 55 ADDR1/LLIS DI TTL Address 1, software mode (HWSEL = High). This pin together with ADDR0 sets the chip select address. Up to 4 LXT6155 chips can be addressed by the µ P interface. Local Loopback Input Select, hardware mode (HWSEL = Low). Together with RLIS sets the LXT6155 in remote loopback mode. See Table 4 56 HWSEL DI TTL Hardware/Software Mode Select. When HWSEL = High, LXT6155 enters software (host) mode, and is ready to communicate with a serial microprocessor. When HWSEL = Low, LXT6155 operates in hardware standalone mode (without a serial µ P). Reserved. Must be connected to GND. Reserved. Must be connected to VCC. Transmit Analog Ground. Transmit Output Data, positive (TTIP0) and negative (TRING0). Differential CMI driver outputs for coax interface. 57 58 59 60 61 SUB WELL TGND TRING0 TTIP0 S S S AO 1. DI = Digital Input; DO = Digital Output; DI/O = Digital Input/Output; AI = Analog Input; AO = Analog Output; AI/O = Analog Input/Output; S=Supply. 2. TTL = Transistor-to-Transistor Logic (5V tolerant); LVPECL = Low-Voltage positive ECL. Datasheet 11 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 1. Pin # 62 63 64 LXT6155 Pin Descriptions (Continued) Symbol TRING1 TTIP1 TVCC S I/O1 DO Type2 Description Transmit Output Data, positive (TTIP1) and negative (TRING1). Differential LVPECL NRZ driver outputs for a fiber optic transceiver. Transmit Analog Power Supply. 1. DI = Digital Input; DO = Digital Output; DI/O = Digital Input/Output; AI = Analog Input; AO = Analog Output; AI/O = Analog Input/Output; S=Supply. 2. TTL = Transistor-to-Transistor Logic (5V tolerant); LVPECL = Low-Voltage positive ECL. 12 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 2.0 Functional Description The LXT6155 is a front-end transceiver designed for 155 Mbps OC3/STM1/ATM transmission applications. Table 2 lists the standards with which the LXT6155 is compliant. The LXT6155 interfaces to either a fiber transceiver or a coax cable on the line side, and on the system side, to an SDH/SONET Overhead Terminator or an ATM UNI. The LXT6155 can function in Hardware stand-alone mode, or in Software mode controlled through an industry standard Motorola compatible 4-wire serial microprocessor interface. The LXT6155 can be set to operate in either CMI mode for the 75Ω coax interface or NRZ mode for the optical transceiver interface. The operating mode can be set in either hardware mode by using the MODE pin, or software mode by using Primary Control Register, bit 0. 2.1 Transmitter In serial mode, the LXT6155 accepts both data (TPOS, TNEG) and clock signals (TSICLKP, TSICLKN). Serial clock signals are required for the LXT6155 to run internal logic, reshape the line transmit pulses and generate the low-jitter clocks for Tx data generation. In parallel mode, the LXT6155 accepts data TPID and clock TPICLK. TPICLK is internally multiplied by 8 to yield the 155.52 MHz clock for Tx data generation. Both serial and parallel clocks (TSICLKP/TSICLKN and TPICLK) must conform to the SONET/ SDH standard frequency accuracy requirements. Depending on whether the selected media interface is coax or fiber, the data is CMI or NRZ encoded respectively, and passed to the appropriate line drivers. The LXT6155 line drivers are high-speed buffers that meet the CMI templates and industry standard LVPECL signal requirements. The CMI output pins are TTIP0 and TRING0, and the NRZ LVPECL pins, TTIP1 and TRING1. 2.1.1 Transmitted Signal Transmitted signals conform to the standard templates listed in Table 2. 2.1.1.1 Fiber Based G.957/GR-253 Transmission Systems The LXT6155 provides 3.3V LVPECL compatible signals for interfacing to a fiber optic transceiver. Please refer to Application Information for interface schematics. 2.1.2 Coax Based G.703/GR-253 Transmission Systems The LXT6155 encodes and decodes CMI signals that are transmitted onto a 75 Ω coax cable compliant with STM1/STS-3 CMI templates. Please refer to the CMI templates shown in Figures 24 and 25. Datasheet 13 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Figure 2. LXT6155 System Interface Line Interface 2 Fiber Optic Modules or Coax Transformers LXT6155 1 System Interface SONET/SDH Overhead Terminator ATM UNI Tx Rx 4 µ Processor (optional) 1 2 2 2 Data/Clock (8-bit parallel or serial mode) Data/Clock (8-bit parallel or serial mode) Receive Output Frame Pulse (ROFP) Receive Ouput PLL Lock (LOCK) Loss of Signal (LOS) 2.1.2.1 CMI Encoding Coded Mark Inversion (CMI) is an encoding scheme adopted by SONET STS-3 and SDH STM1 standards. CMI encoding guarantees at least one transition per bit, thereby enhancing the clock recovery process. CMI encodes a “0” with a midpoint positive transition, and a “1” as Low or High, in opposite polarity to the previous encoded “1”. Refer to Figures 6, 24 and 25 for encoding and pulse template information. 2.1.3 Tx Clock Monitoring The LXT6155 provides transmit clock monitoring for both serial and parallel operating modes. When using the crystal clock as a reference, the LXT6155 monitors the TSICLKP/TSICLKN or the TPICLK input(s) for transitions. If no transition is seen within 200ns, the tx_clk_alarm flag will be set (reg #15) and the transmitter outputs ttip1/tring1 or ttip0/tring0 will stop sending data to the line. This condition will remain until the LXT6155 detects clock transitions at the transmitter input(s) TSICLKP/TSICLKN or TPICLK. Transmit clock monitoring can be disabled in software mode only. In remote loopback, transmit clock monitoring is disabled in SW and HW mode. In SW mode, when using transmit clocks as the receive PLL reference, the user must disable transmit clock monitoring by setting reg #1 bit low. 2.2 2.2.1 2.2.1.1 Receiver Analog Front End and Timing Recovery CMI Mode Received data on RTIP/RRING goes through an adaptive equalizer. An adaptive f equalizer and adaptive Automatic Gain Control (AGC) compensate the frequency-and-cable length dependent loss in data signal, and reshapes the signal to the optimal waveform. A Phase Locked Loop (PLL) 14 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 then performs clock recovery operation, comparing the reshaped data phase against the receive output clock phase. The receive PLL requires an external reference (e.g. transmit input clock or XTAL clock) to start up the clock recovery process. This clock can be derived from XTALIN, TPICLK or TSICLK (÷8). The recovered clock is used to retime the CMI signals, and to decode CMI to NRZ. Coding errors are detected and flagged via the CMIERR pin in HW mode with the frame detect disabled or in serial mode. In software mode (HWSEL = High) CMI coding errors are indicated via the µP interface interrupt register: Reg #15, mode 05. 2.2.1.2 NRZ Mode The on chip adaptive equalizer is bypassed. Data goes straight to the clock recovery phase locked loop. The PLL then performs clock recovery operation, comparing the data phase against the clock phase. This clock can be derived from XTALIN, TPICLK or TSICLK (÷8). The receive PLL requires an external reference (e.g. transmit input clock or XTAL clock) to start up the clock recovery process. The recovered clock is used to retime the data signals. When the recovered clock is within 488 ppm of the reference clock, the LOCK signal asserts. This alarm is also accessible on the µP interface as a status bit (Reg #15, mode 0) and as an interrupt (Reg #15, mode 05). Once the recovered clock has been obtained and the NRZ data has been recovered, the LXT6155 performs frame-detect-andbyte-alignment, and serial-to-parallel conversion. The LXT6155 optionally provides output data RPOD aligned to the SDH/SONET byte boundary. The user has the option to enable/disable the frame-alignment function in both hardware and software mode. The frame detect/byte alignment function generates the receive output frame pulse (ROFP). In HW mode (HWSEL = Low) ROFP asserts (high) on the third A2 byte. In SW mode (HWSEL = High) this position is programmable via register #13, bits . When byte alignment is disabled and the LXT6155 is in CMI mode, the ROFP pin indicates CMI coding errors including polarity errors for ones and inversion errors for zeroes. The clock recovery PLL’s center frequency comes from either the local crystal or a stable transmit input clock (TSICLKP/TSICLKN or TPICLK). If operated in loop-timed mode or remote loopback mode, an external reference clock must be used to center the internal PLL clock. In remote loopback, the receive reference remains either XTALIN or TSICLK or TPICLK, depending on the control selection. If an independent and stable transmit clock is available, the designer has the option of applying this clock to pin XTALIN to center the PLL, without the external crystal. The user can also replace the crystal by connecting the TPICLK (19.44MHz) signal to the XTALIN pin. However, a local crystal is recommended for “keep alive” purposes in case the clock becomes unavailable. 2.2.2 Receive Frame Detect and Byte Alignment Receive Frame Detection only operates in parallel mode, if Frame Detection is enabled. The LXT6155 provides aligned bytes RPOD following the distinct SONET OC3/STM1 frame marker word, 3 x A1, followed by 3 x A2, where A1=F6h and A2=28h. The Receive Output Frame Pulse (ROFP) asserts during the third A2 byte, and de-asserts after one complete RPOCLK clock period. If this feature is used, it can be enabled in register #12 bit in software mode1, or by setting the RIFE (pin 15) high in hardware mode prior to applying data to Rtip/Rring. Two consecutive frames with correct frame words (A 1...A 1 A2...A 2) are required to change from an outof-frame state (OOF) to an in-frame state. The OOF alarm is accessible in SW mode (HWSEL = High) as a status or interrupt signal (Reg #15). To declare an OOF condition, four consecutive 1. For further details see register #12 description for usage. Datasheet 15 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver frames with incorrect frame words are required. Byte alignment occurs when entering the in-frame state. In case of an OOF event, the byte alignment and frame pulse position are frozen. The ROFP output continues unchanged until re-entering the in-frame state. Figure 3. Framing State 4 consecutive frames with errored FAS In Frame 2 consecutive frames with correct FAS Out of Frame 2.2.2.1 Loss of Signal (LOS) Loss of Signal provides an alarm signal indicating incoming signal voltage is weak or incoming data does not contain enough transitions. This signal is available in HW mode on pin #45 and in SW mode as status and interrupt (Reg #15, modes 00 and 05). 2.2.2.2 Coax Interface Loss of Signal provides an alarm output that indicates weak line input signal. The LOS signal asserts when the incoming signals fall below a specified loss threshold, and de-asserts when the line signal rises nominally 2dB above the assert threshold. The threshold is adjustable in SW mode (HWSEL = High) via the µProcessor interface. 2.2.2.3 Fiber Interface If no transition is detected during any 3112 bit times (20 µsec), LOS asserts. LOS is cleared when two consecutive frame words with no LOS events between then are received. In SW mode (HWSEL = High) the assertion window is programmable from 128 bits to 4096 bits in four steps. The deassertion criteria can also be configured to 12.5% transition density. The 12.5% density is determined by receipt of at least 4 transitions during a 32 bit sliding window. Figure 4. Criteria for LOS Output Nominal Value LOS De-assert HYS = 3 dB LOS Assert Level below nominal 16 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 5. Receive Frame Synchronization and Frame Pulse Position RPOCLK RPOD A1 A1 A1 A2 A2 A2 J0 Z0 Z0 Start of SPE End of Previous Frame -7 -6 -5 -4 -3 -2 -1 0 +1 +2 +3 +4 +5 +6 +7 Contents of REG 13h Hex Fh Eh Dh Ch Bh Ah 9h 0h 8h 1h 2h 3h 4h 5h 6h 7h Binary 1111 1110 1101 1100 1011 1010 1001 0000 0001 0010 0011 0100 0101 0110 0111 1000 Table 2. Standards Compliance SDH/SONET (Fiber) Item STM1 OC3 155 50 Ω LVPECL NRZ OC3 OC3 Eye GR-253 STM1 155 75 Ω coax CMI G.703 CMI Template. CMI Eye G.813 G.825 STS-3 155 75 Ω coax CMI STSX-3 CMI Template. CMI Eye GR-253 SDH/SONET (Coax) Line Rate (Mbps) Line Interface Line Code Signal Templates 155 50 Ω LVPECL NRZ G.957 STM1 Eye G.958 G.825 Jitter Binary CMI 0 0 1 T/2 T/2 T Datasheet l Figure 6. Example of CMI Encoded Binary Signa 0 1 1 1 17 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 2.3 2.3.1 Clocks Parallel Mode The LXT6155 accepts TPICLK synchronized with transmit input parallel data TPID. The data is serialized and transmitted at TTIP0/TRING0 or TTIP1/TRING1 depending on which line encoding mode is selected. The LXT6155 in turn produces the receive output parallel clock RPOCLK, that is recovered from incoming line data RTIP/RRING, and is synchronized with receive output parallel data RPOD. 2.3.1.1 Transmit Parallel Input Clock (TPICLK) TPICLK is the transmit parallel input clock provided by the systems interface. This clock must be nominally 19.44 MHz, synchronized with parallel input data TPID. This clock is then internally multiplied by 8 to produce a serial clock, used for parallel-to-serial conversion, line drivers, and pulse reshaping. In HW mode (HWSEL = Low), TPID data is sampled on the falling edge of TPICLK. In SW mode (HWSEL = High), the clock polarity can be inverted (Reg #0, bit #3). 2.3.1.2 Receive Parallel Output Clock (RPOCLK) RPOCLK is the parallel output clock that is recovered from the line input data RTIP/RRING. This clock is at 19.44 MHz, synchronized with parallel output data RP0D. In HW mode (HWSEL = Low), the RPOCLK clock rising edge is at the center of eye opening of RPOD as shown in Figure 21. In SW mode (HWSEL = High), the clock polarity can be inverted (Reg #0, bit #2). Under LOS (LOS=High) or Rx PLL loss of lock (LOCK=Low) conditions RPOCLK is switched to the reference selected by the CIS control in HW mode, or Reg #0 bit #5 in SW mode. Also, the parallel output is forced to all zeros. This feature can be disabled in SW mode (HWSEL = High) via register #10, bit #7. 2.3.2 Serial Mode At the transmit systems interface, the LXT6155 accepts the transmit input clock TSICLKP/ TSICLKN that is synchronized to incoming serial differential data TPOS/TNEG. At the line interface, the LXT6155 accepts RTIP/RRING data and produces the clocks RSOCLKP/ RSOCLKN synchronized to receive output data RPOS/RNEG. RSOCLKP/RSOCLKN clock edges are at the center of RPOS/RNEG. 2.3.2.1 Transmit Serial Input Clock (TSICLKP/TSICLKN) TSICLKP/TSICLKN is the serial input clock from the overhead terminator. This 155.52 MHz clock is rising edge centered with input serial data on TPOS and TNEG. These clock pins should be left open when the LXT6155 operates in parallel mode. 2.3.2.2 Receive Serial Output Clock (RSOCLKP/RSOCLKN) RSOCLKP/RSOCLKN is the serial clock recovered from the line input data on RTIP/RRING. This 155.52 MHz clock is falling edge centered with receive serial output data on RPOS/RNEG. These clock pins should be left open when the LXT6155 operates in parallel mode. Under LOS 18 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 (LOS=High) or Rx PLL loss of lock (LOCK=Low) conditions RSOCLK P/N is switched to the Tx serial clock. Also the serial output data is forced to all zeros. This feature can be disabled in SW mode (HWSEL = High) via register #10, bit #7. 2.3.3 Crystal Reference Clock (XTALIN/XTALOUT) An optional 19.44 MHz crystal can be connected across the XTALIN and XTALOUT pins. This crystal reference provides an onchip clock that is independent of the external system clock (TSICLKP/TSICLKN or TPICLK). The main functions of the crystal reference clock are threefold: (1) to center the receive PLL at 155 MHz, (2) to keep the PLL centered at 155 MHz when LOS asserts, and (3) In the event incoming data is lost, to provide a reference clock for other devices which require it. The designer has the option to use this crystal reference clock or the transmit input clock (TSICLKP/TSICLKN or TPICLK) to center the receive PLL. 2.4 Jitter The Bellcore GR-253 standard defines jitter as the “short-term variations of a digital signal’s significant instants from their ideal positions in time”. Significant instants are the optimum data sampling instants. Jitter parameters can be measured at the line interface, with system interface in loopback mode, yielding jitter accumulated in both transmitter and receiver. Isolated jitter measurements for transmitter and receiver can also be performed. Jitter specs are divided into three categories: jitter tolerance, jitter generation, and jitter transfer. Jitter values, in effect, measure the performance of the receive PLL and the transmit synthesizer PLL. 2.4.1 Jitter Tolerance Jitter tolerance is the peak-to-peak amplitude of sinusoidal jitter applied at the line interface input that causes an equivalent 1 dB SNR loss measured as BER = 10-10. Refer to Figure 26 on page page 44 for the LXT6155 performance. 2.4.2 Jitter Generation (Intrinsic Jitter) Jitter generation is the amount of transmit jitter at the output of the equipment with a jitter-free transmit input data and clock. For SONET/SDH, jitter generation is less than 0.01 UI rms, measured with a band-pass filter from 12 kHz to 1.3 MHz. Refer to 27 on page 45 for the LXT6155 performance. 2.4.3 Jitter Transfer Jitter transfer is defined as the ratio of output jitter to input jitter amplitude versus jitter frequency for a given bit rate. Input jitter amplitude is shown in the Jitter Tolerance curve. Output jitter is under the Jitter Transfer template. Refer to Figures 27 and 28 on pages and for the LXT6155 performance. 2.5 Operational Modes The LXT6155 functions in both Hardware standalone and Software modes. The operating mode is set by the state of the HWSEL pin. Datasheet 19 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 2.5.1 Hardware Mode By setting HWSEL = Low, the LXT6155 operates in standalone hardware mode, without a serial microprocessor interface. A subset of the functions available in the Software Mode can be set in Hardware Mode. LXT6155 provides a comprehensive flexibility in configuring system clock preference settings, as well as providing pins for activating loopback test modes. Tables 3, 4 and 5 show the settings that enable the functions available in hardware mode. Figure 7. Hardware Mode Nevada HWSEL MODE RLIS LLIS CIS SP RIFE GND Line interface encode/ decode Remote loopback Local loopback Clock reference select Serial/Parallel Frame Enable Table 3. CIS Low High Reference Clock Settings1 Clock Reference TICLK XTAL Note Default mode. The LXT6155 uses the transmit input clock as the reference clock for on chip operations. No crystal is needed. The LXT6155 uses the clock signal at XTALIN as the reference clock for Rx operation. This can either be an applied 19.44MHz clock or a 19.44MHz crystal can be connected across XTALIN & XTALOUT. See Table 24 for the crystal specifications. 1. For explanation, see clock sections below. 2.5.1.1 PLL Clock Reference (CIS pin) The reference clock plays two roles: it centers the receive PLL, and it provides the receive output clocks RSOCLKP/RSOCKLN and RPOCLK in case of Loss of Signal. When the LXT6155 powers up, it looks for this reference clock to start-up internal blocks, including the receive PLL circuitry. 2.5.1.1.1 TICLK This is the transmit input clock(s): either TSICLKP/TSICLKN in serial mode or TPICLK in parallel mode. 2.5.1.1.2 XTAL XTAL is an optional clock, created using an external crystal, connected across the XTALIN and XTALOUT pins. The crystal provides an independent and stable clock source. This clock is also used as the reference for the Tx clock monitoring circuitry. 20 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 2.5.1.2 Loopback Test (RLIS and LLIS pins) The LXT6155 allows two types of loopback test: Remote loopback and Local loopback. In Remote loopback, the received data and clock are looped back to the transmit line interface. The LXT6155 still outputs recovered data and clock at the system interface. In Local loopback, the transmit data is looped back to the receive input at the line interface. The LXT6155 also transmit data onto the line interface while looping back. For descriptive diagrams, please refer to Figures 13 and 14. Table 4. Loopback Selection RLIS Low Low High High LLIS Low High Low High Description Normal operation. No loopback testing. Local loopback test activate. Remote loopback test activate. 2.5.1.3 Line Interface Selection (MODE Pin) The MODE pin sets one of the two line interfaces, as described in Table 5. Table 5. MODE Line Interface Settings MODE Low Description Sets LVPECL NRZ mode to interface to a fiber optic module. CMI related blocks (e.g. input/output buffers, equalizer) are disabled. Sets CMI mode to interface to a transformer and a 75Ω coax cable. NRZ related input/output buffers are disabled. High 2.5.1.4 Parallel/Serial Mode Selection (SP pin) In Hardware Mode, HWSEL = Low, the LXT6155 can be set to operate in serial or parallel data mode, depending on how the Serial/Parallel SP pin is set. Setting the SP pin = High sets the LXT6155 to an 8-bit parallel mode. Parallel pins TPID, TPICLK, RPOD, ROFP, RPOCLK, LOCK and LOS are be used. Serial pins TPOS, TNEG, TSICLKP, TSICLKN, RPOS, RNEG, RSOCLKP, RSOCLKN are unused and should be left open. Setting the SP pin = Low sets the LXT6155 to serial mode. Pins TPOS, TNEG, TSICLKP, TSICLKN, RPOS, RNEG, RSOCLKP, RSOCLKN, LOCK and LOS are used. Pins TPID, TPICLK, RPOD and RPOCLK are unused and should be left open. 2.5.1.5 Tx Amplitude Trim In Hardware, serial, coax mode, the line driver output amplitude can be controlled via pins 16 to 20. Setting TXTRIMENA (pin #20) high enables the trim capability. The trim rage is -21% to +24% in 3% steps controlled by TXTRIM0-TXTRIM3. The minimum amplitude is at 0000 and the maximum amplitude is at 1111. This is the same control range as in SW mode. Datasheet 21 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 2.5.2 Software Mode When HWSEL = High, the LXT6155 operates in Software Mode. Control is through an external serial µP interface. Figure 8 shows the pins used in Software Mode. The LXT6155 uses four pins for the industry standard Serial Control Interface (SCP) bus: SCLK, CS, SDI and SDO. SCLK is the serial input control clock pin. CS is the chip select input. SDI is the serial data input pin, and SDO is the serial data output pin. Figures 9 and 10 show the serial interface data structure. A data transaction is initiated by a falling edge on the Chip Select pin CS. A High-to-Low transition on CS is required for each access to the control registers. The first bit is a read/write bit (R/W), followed by seven address bits (A), and eight data bits (D). Every data transaction requires 16 SCLK cycles to complete. If R/W = High (Read), the LXT6155 outputs a data byte D on the SDO pin. If R/W = Low (Write), the LXT6155 accepts a data byte D on the SDI pin, while tristating SDO pin. It is recommended in SW mode operation, the registers are first initialized by writing a “0” to register #11 bit #6 (reset). 2.5.2.1 Serial Input Clock (SCLK) This pin accepts a clock up to 4.096 MHz for data transactions between the LXT6155 and the SCP bus. The LXT6155 clocks SDO data out on the falling edge, and clocks SDI data in on the rising edge of SCLK (see Figures 9 and 10). 2.5.2.2 Chip Select Input (CS) On the falling edge of CS, the LXT6155 starts data transactions. On the rising edge of CS, the LXT6155 stops data transaction. The CS pin must be held Low for at least 16 SCLK cycles to complete a full Read or Write data transaction. If CS is held Low less than 16 SCLK cycles, then the data transaction is ignored. At the end of each Write/Read transaction, CS must return High, between the 16th and 17th clock edges. 2.5.2.3 Serial Input Word (SDI) Figure 10 shows the serial interface input data word structure. When the first input bit R/W = Low, a Write operation is performed. The SCLK clocks data in on the SDI pin during the second 8 bits D of the Write operation. Data is clocked in on the rising edge of SCLK. During the entire 16 bit operation, SDO remains tristated. Refer to Tables 6 through 22 for control register descriptions. 2.5.2.4 Serial Output Word (SDO) The serial output word structure is shown in Figure 9. When the first input bit R/W = High, a Read operation is specified. SDO becomes active after A0 has been clocked in. The first bit out of SDO changes the state of SDO from High-Z to a Low/High. SDO is clocked out on the falling edge of SCLK. 22 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 8. Software Mode LXT6155 HWSEL VCC CS SDI SDO SCLK ADDR0, ADDR1 Chip select in Serial data in Serial data out Serial clock in Device address settings Figure 9. Serial Data Output Word Structure (Read Cycle: R/W=High) CS SCLK SDI SDO DON'T CARE DON'T CARE Don't Care R/W =1 A6 A5 A4 A3 A2 A1 A0 Don't Care High Impedance D7 D6 D5 D4 D3 D2 D1 D0 Figure 10. Serial Data Input Word Structure (Write Cycle: R/W = Low) CS SCLK SDI SDO R/W =0 A6 A5 A4 A3 A2 A1 A0 D7 D6 D5 D4 D3 D2 D1 D0 Don't Care Don't Care High Impedance 2.6 Serial System Interface The serial interface permits the LXT6155 to communicate with an Overhead Termination device at 155.52 Mbps. Data and clock lines are differential 3.3V LVPECL signals. Refer to Figure 11. 2.7 Parallel System Interface Parallel interface allows the LXT6155 to communicate with the system chip at 19.44 MHz, 8 bits per clock cycle. Data and clock lines are TTL compatible signals. Refer to Figure 12. Datasheet 23 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Figure 11. Serial Interface Nevada TPOS, TNEG TSICLKP, TSICLKN RPOS, RNEG RSOCLKP, RSOCLKN CMIERR, LOS 4 Overhead Terminator/ATM UNI DATA_OUT CLK_OUT DATA_IN CLK_IN LOS 4 µ Processor (optional) CS SDI SDO SCLK 4 Chip Select Data I/O Clock Figure 12. Parallel Interface Nevada TPID TPICLK RPOD RPOCLK LOS, ROFP/ CMIERR CS SDI SDO SCLK 9 Overhead Terminator/ATM UNI DATA_OUT BYTE_TCLK DATA_IN BYTE_RCLK 9 2 LOS, RIFP µProcessor (optional) 4 Chip Select Data I/O Clock 2.8 Loopback Modes The LXT6155 provides two loopback modes that can be executed in either hardware or software mode: local loopback and remote loopback. In remote loopback mode, the crystal reference clock is used to center the receive PLL to prevent illegal clock looping. 2.8.1 Local Loopback Local loopback routes the transmit line output signals (TTIP and TRING) back to the receive line inputs (RTIP and RRING). In this mode, the line transmit output signals are active (see Figure 13). 24 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 2.8.2 Remote Loopback Remote loopback routes the receive system output signals, both data and clock, to the transmit system input (see Figure 14). In this mode, system outputs (RPOD or RPOS/RNEG) are still active. Figure 13. Local Loopback TTIP0, TRING0, TTIP1, TTIP1 Line Buffer P/S TPID , TPICLK, TPOS/TNEG, TSICLKP/N RTIP, RRING Equalizer PLL S/P RPOD , RPOCLK, RPOS/RNEG, RSOCLKP/N Figure 14. Remote Loopback TTIP0, TRING0, TTIP1, TTIP1 Line Buffer P/S TPID , TPICLK, TPOS/TNEG, TSICLKP/N RTIP, RRING Equalizer PLL S/P RPOD , RPOCLK, RPOS/RNEG, RSOCLKP/N Datasheet 25 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 3.0 Register Definitions There are a total of sixteen (16) control registers in the LXT6155 addressed by the lowest four address bits, A. See Tables 8 through 22 for details . Table 6. A Device Address/Control Byte Description A LXT6155 Device Select. By using pins ADDR1 and ADDR0, up to four LXT6155 devices can be addressed. For a successful data transaction to occur, A6 and A5 must match the polarity settings on ADDR1 and ADDR0, respectively. Using these controls, up to four LXT6155 devices can be independently controlled. Not Used. Set to 0 during transactions. LXT6155 Register Map (see Table 7). A4 A Table 7. Register # LXT6155 Register Map (A) A Register Name Type 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 Primary Control Transmit Control Transmit PLL1 Transmit PLL2 Equalizer load Equalizer/AGC Matching filter2 Slicer Receive PLL 1 Receive PLL 2 Test Reset and Bias Receive Digital 1 Receive Digital 2 Status/Interrupt Control Status/Interrupt Output R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W Read-only 26 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 8. Bit Primary Control Register Settings, Register #0 (Address A=0000) Mnemonic Description Default 7 0 lpbk_cntl Local loopback: 0 = No loopback 1 = Activate local loopback Remote loopback: 0 = No loopback 1 = Activate remote loopback 6 0 5 0 pll_ref PLL/Equalizer reference clock control: 0 = Use TPICLK clock 1 = Use external crystal (XTALIN) Not used TPICLK polarity at system interface: 0 = TPID sampled on the rising edge of TPICLK 1 = TPID sampled on the falling edge of TPICLK RPOCLK polarity at system interface: 0 = RPOD transitions on the rising edge of RPOCLK 1 = RPOD transitions on the falling edge of RPOCLK 4 3 0 1 clk_inv 2 1 1 0 sys_int Systems interface mode selection: 0 = Serial mode 1 = Parallel 8 bit mode Media and line code selection: 0 = Fiber (NRZ) 1 = Coax (CMI) 0 0 media_sel . Table 9. Bit Tx Control, Register #1 (Address A=0001) Mnemonic Description Default 7 1 tx_ena Tx output enable: 0 = outputs disabled 1 = outputs active Tx digital circuitry reset. This can be used to minimize power comsumption when the device is disabled but not powered down. It must be enabled when the device is active. 0 = reset 1 = active 6 1 tx_dig_reset 5 4:1 0 0.1.1.1 tx_amp_trim Transmit amplitude trim: 0000 = -21% 1111 = +24% Tx clock detection enable. This must be disabled in SW mode when pll_ref=0 (reg#0=0) 0 = disable 1 = enable 0 1 tx_clk_sw_ena Datasheet 27 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver . Table 10. Transmit PLL1, Register #2 (Address A=0010) Bit Default Mnemonic Description 7:5 4:3 2:1 0 0.1.1 0.0 1.0 1 Not for customer use Not for customer use Not for customer use Not for customer use . Table 11. Transmit PLL2, Register #3 (Address A=0011) Bit Default Mnemonic Description 7 6 5 4 3 2 1:0 1 1 1 0 0 0 1.0 Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Table 12. Equalizer Load, Register #4 (Address A=0100) Bit Default Mnemonic Description 7 6:2 1 0 0 0.0.0.0.0 0 1 Not for customer use Not for customer use Not for customer use Not for customer use Table 13. Equalizer & AGC, Register #5 (Address A=0101) Bit Default Mnemonic Description 7 1 eq_adapt_enab Equalizer adaption enable: 0 = freeze adaption 1 = activate adaption Equalizer adaption step size: 00 = 1 01 = 2 10 = 4 11 = 8 AGC adaption enable: 0 = freeze adaption 1 = activate adaption 6:5 0.0 eq_adapt_gain 4 1 agc_adapt_ena 28 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 13. Equalizer & AGC, Register #5 (Address A=0101) (Continued) Bit Default Mnemonic Description 3:2 0.0 agc_adapt_gain AGC adaption step size: 00 = 1 01 = 2 10 = 4 11 = 8 Analog front end enable (also enables matching filter oscillator core): 0 = disabled (no bias) 1 = enabled 1 1 afe_ena 0 0 Table 14. Matching Filter 2, Register #6 (Address A=0110) Bit Default Mnemonic Description 7:5 4:3 2:1 0 0.1.0 1.0 0.0 1 Not for customer use Not for customer use Not for customer use Not for customer use 1. This register is used in CMI (co-ax) mode only. Table 15. Slicer, Register #7 (Address A=0111) Bit Default Mnemonic Description 7:4 3 2 1 0 0.0.0.0 1 0 0 0 - Not for customer use Unused Not for customer use Not for customer use Not for customer use Table 16. RxPLL 1, Register #8 (Address A=1000) Bit Default Mnemonic Description 7:5 4:3 2 1 0 0.1.1 0.0 0 0 1 Not for customer use Not for customer use Not for customer use Unused Not for customer use Datasheet 29 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 17. Rx PLL 2, Register #9 (Address A=1001) Bit Default Mnemonic Description 7 6 5:3 2 1 0 1 1 0.1.1 1 1 1 freq_det_pw Not for customer use Not for customer use Frequency detector output pulse width ({1 to 8} * 6.43 ns) Not for customer use Not for customer use Not for customer use Table 18. Test, Register #10 (Address A=1010) Bit Default Mnemonic Description 7 1 los_clk_ena Enables Rx clock switching under LOS/LOCK condition: 0 = disable 1 = enable Not for customer use Not for customer use Not for customer use Not for customer use 6 5:2 1 0 0 0.0.0.0 1 0 Table 19. Register, Bias and Fuse Controls, Register #11 (Address A=1011) Bit Default Mnemonic Description 7 0 bias_pwrdn Power down all bias generators. This bit can be used to power down all the active analog circuitry on the device. 0= active 1=power down Register array reset, ignores remainder of transaction (active low). This register is write only. Not for customer use Not for customer use 6 5:2 1:0 1 1.0.0.0 0.0 . reg_reset Table 20. Rx Digital 1, Register #12 (Address A=1100) Bit Default Mnemonic Description 7 0 los_format Combine (logical OR) LOS/LOCK function onto LOS pin: 0 = disable 1 = enable Amplitude LOS threshold trim: 0 = Reduced ALOS dessert threshold (-3db) 1 = Nominal ALOS thresholds 6 1 los_amp_trim 30 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 20. Rx Digital 1, Register #12 (Address A=1100) (Continued) Bit Default Mnemonic Description 5:4 1.1 los_ena LOS disable controls (amplitude LOS & digital LOS): 0 = disable 1 = enable Byte align enable: If used, this feature must be enabled during system configuration prior to applying data to the receiver. If this is not possible see application note AN141 for further details. 0 = byte align disabled 1 = byte align enabled Not for customer use Not for customer use Not for customer use 3 0 frame_ena 2 1 0 0 0 1 . Figure 15. Rx Digital 2, Register #13 (Address A=11001) Bit Default Mnemonic Description 7 1 rx_dig_reset Rx digital circuitry reset. This can be used to minimize power comsumption when the device is disabled but not powered down. It must be enabled when the device is active 0 = reset 1 = normal operation Frame pulse position. Refer to figure 5 for usage. D-LOS transition density count for assertion: 00 = 128 01 = 512 10 = 3112 11 = 4096 A-LOS assertion integration period: 00 = 2048 bits 01 = 512 bits 10 = 128 bits 11 = 32 bits D-LOS transition density count for de-assertion: 0 = 4/32 1 = SONET compliant1 A-LOS de-assertion integration period: 0 = 0 bits 1 = 128 bits 6:3 2:1 0.0.0.0 1.0 cnffp los_tran_assert 0 1 los_tran_deassert 1. SONET compliant LOS de-assertion refers to Bellcore GR-253, pages 6-16 (section 6.2.1.1.1), recommendation R6-54, LOS alarm is de-asserted (cleared) when two valid frame headers have been received with no LOS events in the interval. . Table 21. Status Control, Register #14 (Address A=1110) Bit Default Mnemonic Description 7:4 3:0 0.0.0.0 0.0.0.0 stat_cont Unused Status register (register #15) mux control (indirect addressing to increase read space) Datasheet 31 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 22. Read-only Register #15 (Address A=1111) Value of: stat_cont Status Output bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 00 (Status register) 01 02 03 (Fuse contentsupper bits) 04 (Fuse contentsupper bits) 051,2 (Interrupt register) Analog LOS Digital LOS Tx clock activity alarm status SONET OOF signal Unused3 Rx PLL frequency lock alarm Unused3 Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Not for customer use Analog LOS interrupt (los_ana_i) Digital LOS interrupt (los_dig_i) Tx clock alarm interrupt OOF interrupt (oof_i) Unused3 Unused3 Rx PLL frequency lock alarm interrupt (rx_lock_i) CMI coding error alarm interrupts (cmi_err_i) LSB 064 (Device ID) MSB 1. Bits 7:1 are cleared upon reading the status register (stat_cont = 00). 2. Bit 0 is cleared upon reading interrupt register (stat_cont = 05). 3. Ignore these bits during register transactions, unpredictable contents 4. Contains device revision number in hexadecimal notation. 32 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 4.0 Application Information The following provides application examples of interfacing the LXT6155 to the line side and the overhead terminator side. Line side encoding schemes can be one of two types: LVPECL NRZ encoded for a fiber optic module, or CMI encoded for a 75Ω coax cable. On the systems side, serial differential or parallel eight-bit modes can be used. All signals are TTL level compatible, except serial interface signals (TPOS, TNEG, TSICLKP, TSICLKN, RSOCLKP, RSOCLKN, RPOS, and RNEG) which are 3.3V LVPECL compatible. 4.1 Fiber Optic Module Interface The LXT6155 is designed to directly drive a 3.3V LVPECL fiber optic transceiver. The LVPECL drivers require the proper transmission line impedance to correctly drive the fiber module. Signal traces should be 50 Ω controlled impedance lines and should be biased to the appropriate level. Please refer to Figure 16 for the proper interface. To interface the LXT6155 LVPECL signals to a 5V PECL fiber optic module, please refer to the LXT6155 application note AN141. 4.2 Coax Interface As shown in 17 on page 35, the LXT6155 directly drives a transformer connected to a 75 Ω coaxial cable, up to12.7dB cable loss at 78MHz. This is approximately 110m of RG59U. Please refer to manufacturers specifications for maximum cable lengths. Output CMI waveform conform to the ITU G.703 specifications. Rise and fall times are less than 2.0 ns. . Datasheet 33 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Figure 16. 3.3 V LVPECL to 3.3 V LVPECL Interface DVCC RAVCC TAVCC Vcc RAGND 53 42 35 11 RAGND 50 57 SUB TAVCC 5 41 RDVCC 38 PVCC 25 VCC TDVCC 6 46 RAVCC 58 Well RDGND GND TDGND R1 R2 49 330 nF RXISH 50 ohm controlled impedance 48 VBIAS RTIP 52 RD 15k, 1% 4 TXISH RRING 51 RD* Vcc R3 R4 R5 68nF R6 3.3V Fiber Optic module NC 47 ATST TTIP1 63 TD LXT6155 LXT6155 1) R1,R2,R5,R6 = 127 Ohms, 1% 2) R3,R4,R7,R8 = 87.5 Ohms 1% 3) Transmission lines should be 50 ohm, controlled impedance strip lines. Keep length as short as possible. 4) Vcc = 3.3V for both resistor network, and Fiber Optic module. TRING1 62 TD* R7 R8 34 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 17. 75 Ω Coax Cable Interface TAVCC DVCC RAVCC RAGND RDGND GND TDGND RAGND SUB 49 330 nF RXISH TAVCC 41 RDVCC 38 PVCC 25 VCC TDVCC 6 RAVCC 46 58 Well 53 42 35 11 50 57 5 1.0 nF 1.0 uF 48 VBIAS RTIP 52 1:1 75 ohm, 1% 75 ohm coax 15k, 1% 4 TXISH 37.5 ohm strip line 75 ohm strip line RRING 51 Vcc 68nF 37.5 ohm, 1% NC 47 ATST 37.5 ohm, 1% 1:1 TTIP0 61 75 ohm coax 37.5 ohm strip line LXT6155 LXT6155 TRING0 60 1.0 nF 1.0 uF Table 23. Transformer Specifications Parameter Min Typ Max Unit Notes Transmission, S12 -3dB Low -3dB High -20dB Low -20dB High 250 320 10 5 0.5 -10 -40 0.97 1.0 1.03 MHz MHz MHz MHz dB dB dB 30 MHz ~ 300 MHZ DC~250MHz DC~156MHz Return Loss, S11 In-band Loss Common mode rejection Cross-talk in dual packages Turns ratio Datasheet 35 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 24. Crystal Specifications Parameter Min Typ Max Unit Notes Center frequency Freq tolerance Temperature drift Aging Mode Shunt capacitance Equivalent resistance Temperature Range -40 -20 -20 -10 19.44 20 20 10 Fundamental 5 8.4 85 MHz ppm ppm ppm At 25°C -40 ~ 85°C First 10 years pF W °C 36 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 5.0 Test Specifications Information in Table 25 through 34 and Figures 18 through 28 represent the performance specifications of the LXT6155 and are guaranteed by test, except as noted by design. Table 25. Absolute Maximum Ratings Parameter Sym Min Max Unit DC supply (reference to GND) Input voltage, TTL pins Input voltage, other pins Input current, any pin Storage temperature Vcc Vin (TTL) Vin Iin Tstg GND -0.3 GND -0.3 -10 -65 4.0 5.5 VCC +0.3 25 150 V V V mA °C CAUTION Operating at or beyond these limits may result in damage to the device. Normal operation not guaranteed at these extremes. Table 26. Recommended Operating Conditions Parameter Sym Min Typ Max Unit DC supply (referenced to GND) Ambient operating temperature serial/fiber serial/coax parallel/fiber parallel/coax Vcc Ta 3.0 -40 3.3 25 3.6 85 150 210 100 150 V °C mA Total current consumption Table 27. DC Electrical Characteristics (Vcc = 3.0 V to 3.6 V; TA = -40 °C to 85 °C) Parameter Sym Min Typ1 Max Unit Test Conditions High level input voltage (LVPECL) Low level input voltage (LVPECL) High level output voltage (LVPECL) Low level output voltage (LVPECL) High level input voltage (TTL) Low level input voltage (TTL) High level output voltage (TTL) Low level output voltage (TTL) Input leakage current, low (TTL) Input leakage current, high (TTL) Vih1 Vil1 Voh1 Vol1 Vih2 Vil2 Voh2 Vol2 Ill Ilh Vcc-1.03 Vcc-1.81 Vcc-1.03 Vcc-1.81 2.0 Vcc-0.95 Vcc-1.70 Vcc-0.88 Vcc-1.62 Vcc-0.88 Vcc-1.62 V V V V V 50 Ω pulled down to VCC -2.0 V. 0.8 2.4 0.4 10 10 V V V µA µA IOH = 4 mA IOL = 4 mA 1 Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. Datasheet 37 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 28. Transmit Timing Characteristics (See Figures 18 and 19) Parameter Sym Min Typ1 Max Unit Test Conditions Transmit serial input clock frequency Transmit serial input clock frequency error Transmit serial input clock duty cycle Transmit serial input clock and data rise /fall time2 Transmit parallel input clock frequency Transmit parallel input clock frequency error Transmit parallel input clock duty cycle Transmit parallel input data & clock rise/fall time2 TPICLK to TPID hold time TPICLK to TPID setup time TSICLKP(TSICLKN) to TPOS (TNEG) setup time TSICLKP (TSICLKN) to TPOS (TNEG) hold time Thtpid Tstpid Tstpos Thtpos -20 45 2 3 2 1.25 0.75 -20 45 155.52 +20 55 1.2 19.44 +20 55 10 MHz ppm % ns MHz ppm % ns ns ns ns ns 20% - 80% Compliant with GR253 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. Figure 18. Transmit Parallel Input Data Timing (See Table 28) TPICLK* TPID Tstpid Thtpid *HW mode timing shown. In SW mode (HWSEL=1) TPICLK polarity can be inverted. See Table 8 for details. Figure 19. Transmit Serial Input Data Timing (See Table 28) TSICLKP TSICLKN TPOS TNEG Tstpos Thtpos 38 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 29. Transmit Analog Characteristics Parameters Note 2 Min Typ1 Max Unit Test Conditions Transmit jitter generation (Intrinsic jitter SONET spec) Transmit jitter generation2 (Intrinsic jitter SDH spec) Transmit jitter transfer function peaking2 Synthesizer capture range Synthesizer track range Synthesizer lock time Transmit output rise and fall times - CMI signals Transmit output amplitude - CMI signals TTIP0/TRING0 output impedance 12 kHz - 1.3 MHz 0.1 0.01 UIpp UIrms UIpp UIpp dB ppm ppm µs 500 Hz - 1.3 MHz 65 kHz - 1.3 MHz DC - 230 kHz Fcap Ftrack Tlock TTIP0 TRING0 TTIP0 TRING0 Zout 0.9 1.6 2.0 -20 -20 1.5 0.075 0.4 +20 +20 100 2.2 1.1 PRBS(23) pattern. Transmit input data and clock have no input jitter. Receive line input is all zeros. PRBS(23) data. Input jitter as shown in Figure 26. parallel mode ns Vpp kΩ 10% - 90% 0m cable length 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. Table 30. Receive Timing Characteristics (See Figures 20 and 21) Parameter Sym Min Typ1 Max Unit Test Conditions Receive serial output clock frequency Receive serial output clock duty cycle Receive serial output clock and data rise/fall time2 RSOCLKP/RSOCLKN to RPOS/ RNEG propagation delay Receive parallel output clock frequency Receive parallel output clock duty cycle Receive parallel output data & clock rise/fall time RPOCLK to RPOD propagation delay RPOCLK to ROFP propagation delay Reference Input Clock into XTALIN pin (TTL) RSOCLKp RSOCLKn RSOCLKdc RSOCLKpd RPOCLK RPOCPdc RPOCLKt RPOCLKpd ROFPpd REFCLK 45 2 0 0 -0.5 45 155.52 55 1.2 1.5 19.44 55 5 7 4 19.44 MHz % ns ns MHz % ns ns ns MHz The REFCLK replaces the crystal 20% - 80%. 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. Datasheet 39 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Table 30. Receive Timing Characteristics (See Figures 20 and 21) (Continued) Parameter Sym Min Typ1 Max Unit Test Conditions Reference Clock Offset from Nominal -100 100 ppm 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. Figure 20. Receive Serial Output Data Timing (See Table 30) RSOCLKP RSOCLKN RSOCLKPD RPOS RNEG Figure 21. Receive Parallel Output Data Timing (See Table 30) RPOCLK* RPOCLKPD RPOD ROFPPD ROFP *This shows timing in HW mode. In SW mode (HWSEL=1) this clock polarity can be inverted. See Table 8 for details. Table 31. Receive Analog Characteristics Parameter Note Min Typ1 Max Unit Test Conditions End to end loss budget (coax)1 - 15 dB BER=1E-12. PRBS (23) data. CMI encoded. Input white noise = 5 mV RMS max. No data transition. Default LOS setting. No LOS events. Default LOS settings. Assert LOS - fiber De-assert 20 187.5 µsec µsec 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. 40 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 31. Receive Analog Characteristics (Continued) Parameter Note Min Typ1 Max Unit Test Conditions Assert LOS Thresholds - Coax De-assert HYS LOS hysteresis - coax Receive jitter generation2 (intrinsic jitter SONET spec) Receive jitter generation2 (intrinsic jitter SDH spec) Receive jitter transfer peaking2 12 kHz - 1.3 MHz 18 17 1.0 4.0 dB dB dB Attenuation measured at 78 MHz, CMI, 75 Ω load. 12.7 dB cable loss plus remaining flat loss. Measured from the level where LOS is asserted. PRBS(23) data. CMI encoded PRBS(23) at RTIP/RRING with no data jitter. Transmit input = all zeros Refer to Figure 27 and Table 33. PRBS(23) Data. Input jitter as the max. tolerance curve shown in Figure 26. BER=1E-10. Tolerated jitter meets Figure 26 0.01 0.1 UIrms UIpp UIpp UIpp dB 500 Hz - 1.3 MHz 65 kHz - 1.3 MHz DC - 230 kHz 1.5 0.075 0.4 0.1 Hz - 19.3 Hz Receive jitter tolerance2 500 Hz - 6.5 kHz 65 kHz PLL nominal center frequency PLL capture range PLL track range PLL lock time Equalizer adaptation time Line input impedance (RTIP and RRING) RIN Fnom Fcap Ftrack Tlock 39 1.5 0.15 155.52 -20 -20 100 +20 +20 UIpp UIpp UIpp MHz ppm ppm µs PRBS(23) pattern, from data applied at RTIP/RRING. Device in fiber optic mode. From data applied Differential resistance 500 4 bits kΩ 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. 2. Not production tested, guaranteed by design and other correlation factors. Parameter Sym Min Typ Max Unit Test Conditions1 Rise/Fall time - All TTL outputs SDI to SCLK setup time SCLK to SDI hold time SCLK low time SCLK high time SCLK rise and fall time CS to SCLK setup time SCLK to CS hold time CS inactive time SCLK to SDO valid tRF tDC tCDH tCL tCH tR, tF tCC tCCH tCWH tCDV 5 5 5 0 5 5 120 120 25 ns ns ns ns ns Load 1.6mA, 50pF 25 ns ns ns ns 20 ns 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. Datasheet 41 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Parameter Sym Min Typ Max Unit Test Conditions1 SCLK falling edge to SDO high Z CS rising edge to SDO high Z tCDZ tCZ 0 0 20 20 ns ns 1. Typical values are at 25C and 3.3V. They are for design aid only; not guaranteed and not subject to production testing. Figure 22. Microprocessor Input Timing Diagram CS tCC tCH tCL tCCH tCWH SCLK tDC tCDH R/W CONTROL BYTE DATA BYTE SDI Figure 23. Microprocessor Output Timing Diagram CS tCZ SCLK tCDV High Z tCDZ High Z SDO 42 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 24. CMI Encoded Zero per G.703 and STS-3 T = 6.43 ns V 0.60 0.55 0.50 0.45 0.40 (Note 1) 1 ns 0.1 ns 0.1 ns 0.35 ns (Note 1) 1.608 ns 1 ns 0.35 ns 1.608 ns 1 ns 0.1 ns 0.1 ns Nominal pulse Nominal zero level (Note 2) 0.05 –0.05 1 ns –0.40 –0.45 –0.50 –0.55 –0.60 1.608 ns 1 ns 1 ns 1.608 ns (Note 1) (Note 1) T1818930-92 Negative transitions Positive transition at mid-unit interval Figure 25. CMI Encoded One per G.703 and STS-3 T = 6.43 ns V 0.60 0.55 0.50 0.45 0.40 (Note 1) 1 ns (Note 1) Nominal pulse 0.1 ns 1 ns 0.5 ns 0.5 ns 0.1 ns Nominal 0.05 zero level –0.05 (Note 2) 3.215 ns 1.2 ns 1 ns –0.40 –0.45 –0.50 –0.55 –0.60 1.608 ns (Note 1) Negative transition Positive transition T1818940-92 3.215 ns 1.2 ns 1 ns 1.608 ns Datasheet 43 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Note: The maximum “steady state” amplitude should not exceed the 0.55 V limit. Overshoots and other transients are permitted to fall into the dotted area. Note: With the signal applied, the vertical position of the trace can be adjusted with the objective of meeting the limits of the masks. Any such adjustment should be the same for both masks and should not exceed ±0.05 V. Table 32. Jitter Tolerance (in UIpp) Frequency OC3 STM1 10 Hz 19.3 Hz 30 Hz 300 Hz 500 Hz 6.5 kHz 65 kHz 1.3 MHz 15 39 15 1.5 1.5 1.5 0.15 0.15 1.5 0.15 0.15 Figure 26. Jitter Tolerance 100 Measured Data Input Jitter [UI(pk-pk)] OC3 Template 10 STM1 Template 1 0.1 1Hz 10Hz 100Hz 1KHz 10KHz Frequency 100KHz 1MHz 10MHz 44 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Table 33. Jitter Generation Signal f1 f2 Measured Jitter OC3 12 kHz 1.3 MHz 0.01 UI rms 0.1 UIpp STM1 500 Hz 65 kHz 1.3 MHz 1.3 MHz 1.5 UIpp 0.075 UIpp Table 34. Jitter Transfer Signal f1 A1 Unit OC3 STM1 230 kHz 230 kHz 0.4 0.4 dB dB Figure 27. Generation Measurement Filter Characteristics 0 dB f1 f2 Datasheet 45 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver Figure 28. Typical Coax Jitter Transfer 10 A1 0 Gain -10 Coax mode LXT6155 spec. ITU G.825 template -20 -30 -40 1 10 100 1000 10000 100000 1000000 1000000 0 Frequency [Hz] f1 Note: Measured with the device in remote loopback. Data reflects total jitter in both Tx and Rx path 46 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 Figure 29. Typical Fiber Jitter Transfer 10 A1 0 Fiber mode -10 Gain LXT6155 spec. ITU G.825 spec. -20 -30 -40 1 10 100 1000 10000 100000 1000000 1E+07 f1 Frequency [Hz] Note: Measured with the device in remote loopback. Data reflects total jitter in both Tx and Rx path Datasheet 47 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 6.0 Mechanical Specifications Figure 30. LXT6155LE Package Specification D D1 e for sides with even number of pins /2 e E1 E L1 A for sides with odd number of pins θ3 A2 θ A1 L B θ3 64-pin Low-profile Quad Flat Pack — Part Number LXT6155LE — Extended Temperature Range: -40° to 85 °C Inches Dim Min Max Min Max Millimeters A A1 A2 B D D1 E E1 e L L1 θ3 .063 .002 .053 .007 0.472 BSC 0.394 BSC .006 .057 .011 1 1 1.60 0.05 1.35 0.17 12.00 BSC 0.15 1.45 0.27 1 10.00 BSC1 12.00 BSC1 10.00 BSC1 0.50 BSC1 0.45 1.00 REF 13° 7° 11° 0° 13° 7° 0.75 0.472 BSC1 0.394 BSC 1 0.020 BSC1 0.018 0.030 0.039 REF 11° 0° q 1. BSC—Basic Spacing between Centers 48 Datasheet 155 Mbps SDH/SONET/ATM Transceiver — LXT6155 7.0 Notes Datasheet 49 LXT6155 — 155 Mbps SDH/SONET/ATM Transceiver 50 Datasheet