LXT388 Dual T1/E1/J1 Transceiver Datasheet The LXT388 is a dual short haul Pulse Code Modulation (PCM) transceiver for use in both 1.544 Mbps (T1) and 2.048 Mbps (E1) applications. It incorporates four receivers and two transmitters in a single LQFP-100 package. The transmit drivers provide low impedance independent of the transmit pattern and supply voltage variations. The LXT388 transmits shaped waveforms meeting G.703 and T1.102 specifications. The LXT388 meets the latest transmit return loss specifications, such as ETSI ETS-300166. The LXT388 differential receivers provide high noise margin for T1/E1 short-haul operation. In addition, the LXT388 includes two extra receiver/jitter attenuation blocks that can be used for Driver Performance Monitoring (DPM) in the active channels. These blocks can also be used to provide jitter attenuation in the receive and transmit paths simultaneously. Jitter attenuation performance meets the latest international specifications such as CTR12/13. The jitter attenuator was optimized for Synchronous Optical NETwork/Synchronous Digital Hierarchy (SONET/SDH) applications including a 32/64 bit FIFO and a second order DPLL. The LXT388 includes Intel Hitless Protection Switching (Intel HPS) feature which helps increase quality of service and eliminates relays in redundancy and 1+1 protection applications. Fast tristate-able drivers and a constant delay jitter attenuator are critical to achieving Intel HPS. Applications ■ ■ ■ SONET/SDH tributary interfaces Digital cross connects Public/private switching trunk line interfaces ■ ■ Microwave transmission systems M13, E1-E3 MUX Product Features ■ ■ ■ ■ Driver Performance Monitor (DPM) Tx and Rx Jitter Attenuator Single rail 3.3V supply with 5V tolerant inputs Superior crystal-less jitter attenuator — Meets ETSI CTR12/13, ITU G.736, G.742, G.823 and AT&T Pub 62411 specifications — Optimized for SONET/SDH applications, meets ITU G.783 mapping jitter specification — Constant throughput delay jitter attenuator ■ ■ ■ ■ ■ ■ ■ Intel HPS for 1 to 1 protection without relays HDB3, B8ZS, or AMI line encoder/decoder Analog/digital and remote loopback testing functions LOS per ITU G.775, ETS 300 233 and T1.231 JTAG Boundary Scan test port per IEEE 1149.1 100 pin LQFP package Low power consumption of 150mW per channel (typical) As of January 15, 2001, this document replaces the Level One document LXT388 — Dual T1/E1/J1 Transceiver. Order Number: 249269-002 February 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. Intel products are not intended for use in medical, life saving, or life sustaining applications. Intel may make changes to specifications and product descriptions at any time, without notice. Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them. The LXT388 may contain design defects or errors known as errata which may cause the product to deviate from published specifications. Current characterized errata are available on request. Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order. Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800548-4725 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. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Contents 1.0 Pin Assignments and Signal Description ......................................................10 2.0 Functional Description...........................................................................................21 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 2.10 2.11 2.12 2.13 2.14 Initialization..........................................................................................................21 2.1.1 Reset Operation .....................................................................................21 Receiver ..............................................................................................................22 2.2.1 Loss of Signal Detector ..........................................................................23 2.2.2 Alarm Indication Signal (AIS) Detection .................................................23 2.2.3 In Service Code Violation Monitoring .....................................................24 Transmitter ..........................................................................................................24 2.3.1 Transmit Pulse Shaping .........................................................................25 Line Protection ....................................................................................................26 Driver Failure Monitor..........................................................................................26 Driver Performance Monitor ................................................................................29 Jitter Attenuation .................................................................................................30 2.7.1 Transmit and Receive Jitter Attenuation ................................................31 Loopbacks ...........................................................................................................32 2.8.1 Analog Loopback....................................................................................32 2.8.2 Digital Loopback.....................................................................................33 2.8.3 Remote Loopback ..................................................................................33 2.8.4 Transmit All Ones (TAOS)......................................................................34 Intel Hitless Protection Switching (Intel HPS) ................................................35 Operation Mode Summary ..................................................................................35 Interfacing with 5V logic ......................................................................................36 Parallel Host Interface .........................................................................................36 2.12.1 Motorola Interface ..................................................................................37 2.12.2 Intel Interface..........................................................................................38 Interrupt Handling................................................................................................38 2.13.1 Interrupt Sources....................................................................................38 2.13.2 Interrupt Enable......................................................................................38 2.13.3 Interrupt Clear ........................................................................................38 Serial Host Mode.................................................................................................39 3.0 Register Descriptions .............................................................................................40 4.0 JTAG Boundary Scan .............................................................................................47 4.1 4.2 4.3 4.4 Datasheet Overview .............................................................................................................47 Architecture .........................................................................................................47 TAP Controller.....................................................................................................47 JTAG Register Description..................................................................................49 4.4.1 Boundary Scan Register (BSR)..............................................................50 4.4.2 Device Identification Register (IDR) .......................................................52 4.4.3 Bypass Register (BYR) ..........................................................................52 4.4.4 Analog Port Scan Register (ASR) ..........................................................52 4.4.5 Instruction Register (IR) .........................................................................53 3 LXT388 — Dual T1/E1/J1 Transceiver 5.0 Test Specifications .................................................................................................. 55 5.1 6.0 Recommendations and Specifications ................................................................ 77 Mechanical Specifications ................................................................................... 78 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 31 32 33 34 35 36 37 4 LXT388 Block Diagram ......................................................................................... 9 LXT388 Low-Profile Quad Flate Package (LQFP) 100 Pin Assignments and Package Markings............................................................................................... 10 Pullup Resistor to RESET ................................................................................... 22 50% AMI Encoding.............................................................................................. 25 External Transmit/Receive Line Circuitry ............................................................ 28 Driver Performance Monitoring ........................................................................... 29 Jitter Attenuator Loop.......................................................................................... 31 Transmit and Receive Jitter Attenuation ............................................................. 32 Analog Loopback ................................................................................................ 33 Digital Loopback.................................................................................................. 33 Remote Loopback ............................................................................................... 34 TAOS Data Path ................................................................................................. 34 TAOS with Digital Loopback ............................................................................... 35 TAOS with Analog Loopback .............................................................................. 35 Serial Host Mode Timing..................................................................................... 39 LXT388 JTAG Architecture ................................................................................. 47 JTAG State Diagram ........................................................................................... 49 Analog Test Port Application............................................................................... 54 Transmit Clock Timing Diagram.......................................................................... 61 Receive Clock Timing Diagram........................................................................... 62 JTAG Timing ....................................................................................................... 63 Non-Multiplexed Intel Mode Read Timing ........................................................... 64 Multiplexed Intel Read Timing............................................................................. 65 Non-Multiplexed Intel Mode Write Timing ........................................................... 66 Multiplexed Intel Mode Write Timing ................................................................... 67 Non-Multiplexed Motorola Mode Read Timing.................................................... 68 Multiplexed Motorola Mode Read Timing............................................................ 69 Non-Multiplexed Motorola Mode Write Timing .................................................... 70 Multiplexed Motorola Mode Write Timing ............................................................ 71 Serial Input Timing .............................................................................................. 72 Serial Output Timing ........................................................................................... 72 E1, G.703 Mask Templates................................................................................. 73 T1, T1.102 Mask Templates ............................................................................... 74 Jitter Tolerance Performance.............................................................................. 75 Jitter Transfer Performance ................................................................................ 76 Output Jitter for CTR12/13 applications .............................................................. 77 Low Quad Flat Package (LQFP) Dimensions ..................................................... 78 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Tables 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 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 Datasheet Assignments and Signal Descriptions - Power and N/C .....................................11 Pin Assignments and Signal Descriptions - Digital Interface...............................11 Pin Assignments and Signal Descriptions - Analog Interface .............................15 Pin Assignments and Signal Descriptions - JTAG Port.......................................15 Pin Assignments and Signal Descriptions - Microprocessor/Configuration.........16 Line Length Equalizer Inputs...............................................................................26 Jitter Attenuation Specifications ..........................................................................30 Operation Mode Summary ..................................................................................35 Microprocessor Parallel Interface Selection ........................................................37 Serial and Parallel Port Register Addresses .......................................................40 Register Bit Names .............................................................................................40 ID Register, ID (00H)...........................................................................................41 Analog Loopback Register, ALOOP (01H)..........................................................42 Remote Loopback Register, RLOOP (02H) ........................................................42 TAOS Enable Register, TAOS (03H) ..................................................................42 LOS Status Monitor Register, LOS (04H) ...........................................................42 DFM Status Monitor Register, DFM (05H) ..........................................................42 LOS Interrupt Enable Register, LIE (06H)...........................................................43 DFM Interrupt Enable Register, DIE (07H)..........................................................43 LOS Interrupt Status Register, LIS (08H)............................................................43 DFM Interrupt Status Register, DIS (09H)...........................................................43 Software Reset Register, RES (0AH)..................................................................43 Reserved (0BH)...................................................................................................43 Digital Loopback Register, DL (0CH) ..................................................................44 LOS/AIS Criteria Register, LCS (0DH)................................................................44 Automatic TAOS Select Register, ATS (0EH).....................................................44 Global Control Register, GCR (0FH)...................................................................44 Pulse Shaping Indirect Address Register, PSIAD (10H) .....................................45 Pulse Shaping Data Register, PSDAT (11H) ......................................................45 Output Enable Register, OER (12H) ...................................................................46 AIS Status Monitor Register, AIS (13H) ..............................................................46 AIS Interrupt Enable Register, AISIE (14H) ........................................................46 AIS Interrupt Status Register, AISIS (15H) .........................................................46 TAP State Description .........................................................................................48 Boundary Scan Register (BSR)...........................................................................50 Device Identification Register (IDR) ....................................................................52 Analog Port Scan Register (ASR) .......................................................................53 Instruction Register (IR) ......................................................................................53 Absolute Maximum Ratings.................................................................................55 Recommended Operating Conditions .................................................................55 DC Characteristics ..............................................................................................56 E1 Transmit Transmission Characteristics..........................................................57 E1 Receive Transmission Characteristics...........................................................57 T1 Transmit Transmission Characteristics ..........................................................58 T1 Receive Transmission Characteristics ...........................................................59 Jitter Attenuator Characteristics ..........................................................................60 Analog Test Port Characteristics.........................................................................61 Transmit Timing Characteristics..........................................................................61 Receive Timing Characteristics...........................................................................62 5 LXT388 — Dual T1/E1/J1 Transceiver 50 51 52 53 54 55 56 58 57 6 Intel Mode Read Timing Characteristics ............................................................. 63 JTAG Timing Characteristics .............................................................................. 63 Intel Mode Write Timing Characteristics ............................................................. 65 Motorola Bus Read Timing Characteristics......................................................... 67 Motorola Mode Write Timing Characteristics ...................................................... 69 Serial I/O Timing Characteristics......................................................................... 71 Transformer Specifications3 ................................................................................ 72 T1.102 1.544 Mbit/s Pulse Mask Specifications.................................................. 73 G.703 2.048 Mbit/s Pulse Mask Specifications ................................................... 73 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Revision History Datasheet Revision Date -002 02/12/01 Description Figure 2, changed pin 70 from TCK to TDI. Figure 2, changed pin 71 from GND to TCK. Moved Product Features from page 9 to page 1. Added Intel to page 1, 3, and 35. 7 LXT388 — Dual T1/E1/J1 Transceiver 8 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 1. LXT388 Block Diagram MODE JTAG LOOP 0..3 SERIAL/ PARALLEL PORT HARDWARE / SOFTWARE CONTROL JASEL CLKE MCLK LOS LOS DATA SLICER TTIP LINE DRIVER PULSE PULSE SHAPER DIGITAL LOOPBACK RRING ANALOG LOOPBACK DATA CLOCK CLOCK RECOVERY TRING JITTER ATTENUATOR RX OR TX PATH JITTER ATTENUATOR RX OR TX PATH RPOS REMOTE LOOPBACK RTIP B8ZS / HDB3 DECODER RCLK RNEG TPOS B8ZS / HDB3 ENCODER TCLK TNEG 0 RTIP 1 LOS LOS DATA SLICER DATA CLOCK CLOCK RECOVERY RRING MONITORING / JA DIGITAL LOOPBACK RTIP RPOS JITTER ATTENUATOR RX OR TX PATH B8ZS / HDB3 DECODER JITTER ATTENUATOR RX OR TX PATH B8ZS / HDB3 ENCODER RCLK RNEG TPOS TCLK TNEG 2 3 Datasheet 9 LXT388 — Dual T1/E1/J1 Transceiver 1.0 Pin Assignments and Signal Description A2 A1 A0 CLKE OE ALE ACK INT MODE MCLK AT1 AT2 87 86 85 84 83 82 81 79 78 77 76 80 A4 A3 88 92 89 D4 94 93 D1 D0 D6 D5 96 95 90 CS D7 98 97 91 MUX 99 D3 D2 RESET 100 Figure 2. LXT388 Low-Profile Quad Flate Package (LQFP) 100 Pin Assignments and Package Markings 1 2 75 VCC R/W 74 GND DS 3 73 TDO VCC 4 72 TRST GND VCC 5 6 71 70 TMS TDI GND 7 69 TCK VCC 8 68 VCC VCC GND GND 9 VCC 10 67 66 11 65 GND GND 64 TCLK2 MOT TCLK1 12 TPOS1 13 TNEG1 14 RCLK1 RPOS1 15 16 RNEG1 17 LOS1 18 58 LOS2 TCLK0 19 TCLK3 TPOS0 TNEG0 20 57 56 Rev # LXT388LE XX XXXXXX XXXXXXXX Part # LOT # FPO # 63 TPOS2 62 TNEG2 61 60 RCLK2 RPOS2 59 RNEG2 50 N/C RTIP3 48 49 47 TVCC1 RRING3 46 45 N/C N/C TGND3 42 RTIP2 RRING2 43 44 39 40 41 N/C TGND2 N/C 38 37 RTIP1 TVCC0 36 35 TVCC1 RRING1 LOS3 33 34 51 32 25 TGND1 LOS0 TRING1 TTIP1 RNEG3 30 31 52 RTIP0 RRING0 24 29 RPOS3 RNEG0 TRING0 TGND0 53 27 28 RCLK3 23 26 54 RPOS0 TTIP0 TPOS3 TNEG3 TVCC0 55 RCLK0 21 22 Package Topside Markings Marking Part # Unique identifier for this product family. Rev # Identifies the particular silicon “stepping” — refer to the specification update for additional stepping information. Lot # Identifies the batch. FPO # 10 Definition Identifies the Finish Process Order. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 1. Assignments and Signal Descriptions - Power and N/C Pin # LQFP Symbol I/O1 5, 7, 10, 11, 65, 66, 74 GND S Power Supply Ground. Connect all pins to power supply ground. 4, 6, 8, 9, 67, 68, 75, VCC S Power Supply. Connect all pins to +3.3 volt power supply - TVCC S Transmit Driver Power Supply. Power supply pins for the output drivers. TVCC pins can be connected to either a 3.3V or 5V power supply. Refer to “Transmitter” on page 24 for details. 26 TVCC0 S Transmit Driver Power Supply. Power supply pin for the port 0 output driver. TVCC pins can be connected to either a 3.3V or 5V power supply. Refer to the Transmitter description. Description 29 TGND0 S Transmit Driver Ground. Ground pin for the output driver. 32 TGND1 S Transmit Driver Ground. 35 TVCC1 S Transmit Driver Power Supply. Power supply pin for the port 1 output driver. TVCC pins can be connected to either a 3.3V or 5V power supply. Refer to the Transmitter description. 38 TVCC0 S Transmit Driver Power Supply. Power supply pin for the port 0 output driver. TVCC pins can be connected to either a 3.3V or 5V power supply. Refer to the Transmitter description. N/C N/C 41 TGND2 S Transmit Driver Ground. 44 TGND3 S Transmit Driver Ground. N/C N/C 47 TVCC1 S 50 N/C NC 39 40 45 46 Not Connected. These pins must be left open for normal operation. Not Connected. These pins must be left open for normal operation. Transmit Driver Power Supply. Power supply pin for the port 1 output driver. TVCC pins can be connected to either a 3.3V or 5V power supply. Refer to the Transmitter description. Not Connected. These pins must be left open for normal operation. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Table 2. Pin Assignments and Signal Descriptions - Digital Interface Pin # LQFP Symbol I/O1 12 TCLK1 DI Transmit Clock. 13 14 15 Description TPOS1/ DI Transmit Positive Data. TDATA1 DI Transmit Data. TNEG1/ DI Transmit Negative Data. UBS1 DI Unipolar/Bipolar Select. RCLK1 DO Receive Clock. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Datasheet 11 LXT388 — Dual T1/E1/J1 Transceiver Table 2. Pin # LQFP 16 17 18 Pin Assignments and Signal Descriptions - Digital Interface (Continued) Symbol I/O1 Description RPOS1/ DO Receive Positive Data. RDATA1 DO Receive Data. RNEG1/ DO Receive Negative Data. BPV1 DO Bipolar Violation Detect. LOS1 DO Loss of Signal. Transmit Clock. During normal operation TCLK is active, and TPOS and TNEG are sampled on the falling edge of TCLK. If TCLK is Low, the output drivers enter a low power high Z mode. If TCLK is High for more than 16 clock cycles the pulse shaping circuit is disabled and the transmit output pulse widths are determined by the TPOS and TNEG duty cycles. TCLK Operating Mode Clocked 19 TCLK0 DI Normal operation H TAOS (if MCLK supplied) H Disable transmit pulse shaping (when MCLK is not available) L Driver outputs enter tri-state When pulse shaping is disabled, it is possible to overheat and damage the LXT384 device by leaving transmit inputs high continuously. For example a programmable ASIC might leave all outputs high until it is programmed. To prevent this clock one of these signals: TPOS, TNEG, TCLK or MCLK. Another solution is to set one of these signals low: TPOS, TNEG, TCLK, or OE. Note that the TAOS generator uses MCLK as a timing reference. In order to assure that the output frequency is within specification limits, MCLK must have the applicable stability. Transmit Positive Data. Transmit Data. Transmit Negative Data. 20 TPOS0/ TDATA0 DI DI Unipolar/Bipolar Select. Bipolar Mode: TPOS/TNEG are active high NRZ inputs. TPOS indicates the transmission of a positive pulse whereas TNEG indicates the transmission of a negative pulse. . Unipolar Mode: When TNEG/UBS is pulled High for more than 16 consecutive TCLK clock cycles, unipolar I/O is selected. In unipolar mode, B8ZS/HDB3 or AMI encoding/decoding is determined by the CODEN pin (hardware mode) or by the CODEN bit in the GCR register (software mode). TDATA is the data input in unipolar I/O mode. 21 TNEG0/ DI UBS0 DI TPOS TNEG Selection 0 0 Space 1 0 Positive Mark 0 1 Negative Mark 1 1 Space 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. 12 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 2. Pin # LQFP Pin Assignments and Signal Descriptions - Digital Interface (Continued) Symbol I/O1 Description Receive Clock. Normal Mode: 22 RCLK0 DO This pin provides the recovered clock from the signal received at RTIP and RRING. Under LOS conditions there is a transition from RCLK signal (derived from the recovered data) to MCLK signal at the RCLK output. Data Recovery Mode: If MCLK is High, the clock recovery circuit is disabled and RPOS and RNEG are internally connected to an EXOR that is fed to the RCLK output for external clock recovery applications. RCLK will be in high impedance state if the MCLK pin is Low. Receive Positive. Receive Data. Receive Negative Data. Bipolar Violation Detect. 23 RPOS0/ RDATA0 DO Bipolar Mode: DO In clock recovery mode these pins act as active high bipolar non return to zero (NRZ) receive signal outputs. A High signal on RPOS corresponds to receipt of a positive pulse on RTIP/RRING. A High signal on RNEG corresponds to receipt of a negative pulse on RTIP/RRING. These signals are valid on the falling or rising edges of RCLK depending on the CLKE input. In Data recovery Mode these pins act as RZ data receiver outputs. The output polarity is selectable with CLKE (Active High output polarity when CLKE is High and Active Low Polarity when CLKE is Low). RPOS and RNEG will go to the high impedance state when the MCLK pin is Low. Unipolar Mode: 24 RNEG0/ DO BPV0 DO In uni-polar mode, the LXT388 asserts BPV High if any in-service Line Code Violation is detected. RDATA acts as the receive data output. Hardware Mode: During a LOS condition, RPOS and RNEG will remain active. Host Mode: RPOS and RNEG will either remain active or insert AIS into the receive path. Selection is determined by the RAISEN bit in the GCR register. 25 LOS0 51 LOS3 52 53 54 55 56 57 DO D DO Loss of Signal. LOS goes High to indicate a loss of signal, i.e. when the incoming signal has no transitions for a specified time interval. The LOS condition is cleared and the output pin returns to Low when the incoming signal has sufficient number of transitions in a specified time interval. see “Loss of Signal Detector” on page 23 Loss of Signal. RNEG3/ DO Receive Negative Data. BPV3 DO Bipolar Violation Detect. RPOS3/ DO Receive Positive Data. RDATA3 DO Receive Data. RCLK3 DO Receive Clock. TNEG3/ DI Transmit Negative Data. UBS3 DI Unipolar/Bipolar Select. TPOS3/ DI Transmit Positive Data. TDATA3 DI Transmit Data. TCLK3 DI Transmit Clock. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Datasheet 13 LXT388 — Dual T1/E1/J1 Transceiver Table 2. Pin Assignments and Signal Descriptions - Digital Interface (Continued) Pin # LQFP Symbol I/O1 58 LOS2 DO Loss of Signal. RNEG2/ DO Receive Negative Data. BPV2 DO Bipolar Violation Detect. RPOS2/ DO Receive Positive Data. RDATA2 DO Receive Data. RCLK2 DO Receive Clock. TNEG2/ DI Transmit Negative Data. UBS2 DI Unipolar/Bipolar Select. 59 60 61 62 63 64 Description TPOS2/ DI Transmit Positive Data. TDATA2 DI Transmit Data. TCLK2 DI Transmit Clock. Master Clock. MCLK is an independent, free-running reference clock. It’s frequency should be 1.544 MHz for T1 operation and 2.048 MHz for E1 operation. This reference clock is used to generate several internal reference signals: • Timing reference for the integrated clock recovery unit • Timing reference for the integrated digital jitter attenuator • Generation of RCLK signal during a loss of signal condition • Reference clock during a blue alarm transmit all ones condition 78 MCLK DI • Reference timing for the parallel processor wait state generation logic If MCLK is High, the PLL clock recovery circuit is disabled. In this mode, the LXT388 operates as simple data receiver. If MCLK is Low, the complete receive path is powered down and the output pins RCLK, RPOS and RNEG are switched to Tri-state mode. MCLK is not required if LXT388 is used as a simple analog front-end without clock recovery and jitter attenuation. Note that wait state generation via RDY/ACK is not available if MCLK is not provided. 100 RESET DI Reset Input. (Added in Revision B1) In either hardware mode or software mode, setting RESET low will begin to initialize the LXT388 and freeze the device until set high. One microsecond after setting RESET high, initialization will complete and the LXT388 will be ready for normal operation. Only revision B1 requires a pull up resistor to VCC at this pin between 1 and 10 kohms in value. It is necessary to retain the pull up resistor for other revisions. Please refer to the section on Reset Operation for more information. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. 14 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 3. Pin # LQFP Pin Assignments and Signal Descriptions - Analog Interface Symbol I/O1 Description Transmit Tip. Transmit Ring. 27 TTIP0 AO 28 TRING0 AO 30 RTIP0 AI Receive Ring. 31 RRING0 AI These pins are the inputs to the differential line receiver. Data and clock are recovered and output on the RPOS/RNEG and RCLK pins. 33 TRING1 AO Transmit Ring. 34 TTIP1 AO Transmit Tip. 36 RRING1 AI Receive Ring. 37 RTIP1 AI Receive Tip. 42 RTIP2 AI Receive TIP. 43 RRING2 AI Receive Ring. 48 RRING3 AI Receive Ring. 49 RTIP3 AI Receive Tip. These pins are differential line driver outputs. TTIP and TRING will be in high impedance state if the TCLK pin is Low or the OE pin is Low. In software mode, TTIP and TRING can be tristated on a port-by-port basis by writing a ‘1’ to the OEx bit in the Output Enable Register (OER). Receive Tip. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Table 4. Pin Assignments and Signal Descriptions - JTAG Port Pin # LQFP Symbol I/O1 76 AT2 AO JTAG Analog Output Test Port 2. 77 AT1 AI JTAG Analog Input Test Port 1. 72 TRST 71 TMS DI JTAG Test Mode Select. Used to control the test logic state machine. Sampled on rising edge of TCK. TMS is pulled up internally and may be left disconnected. 69 TCK DI JTAG Clock. Clock input for JTAG. Connect to GND when not used. 73 TDO DO JTAG Data Output. Test Data Output for JTAG. Used for reading all serial configuration and test data from internal test logic. Updated on falling edge of TCK. 70 TDI DI JTAG Data Input. Test Data input for JTAG. Used for loading serial instructions and data into internal test logic. Sampled on rising edge of TCK. TDI is pulled up internally and may be left disconnected. Description JTAG Controller Reset. Input is used to reset the JTAG controller. TRST is pulled up internally and may be left disconnected. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Datasheet 15 LXT388 — Dual T1/E1/J1 Transceiver Table 5. Pin # LQFP Pin Assignments and Signal Descriptions - Microprocessor/Configuration Symbol I/O1 Description Motorola/Intel/Codec Enable Select. Host Mode: 1 MOT/INTL/ DI When Low, the host interface is configured for Motorola microcontrollers. When High, the host interface is configured for Intel microcontrollers. CODEN DI Hardware Mode: This pin determines the line encode/decode selection when in unipolar mode: When Low, B8ZS/HDB3 encoders/decoders are enabled for T1/E1 respectively. When High, enables AMI encoder/decoder (transparent mode). Read/Write (Motorola Mode). Read Enable (Intel mode). 2 R / W/ DI RD/ DI LEN1 DI Line Length Equalizer (Hardware Mode). Host Mode This pin functions as the read/write signal in Motorola mode and as the Read Enable in Intel mode. Hardware Mode This pin determines the shape and amplitude of the transmit pulse. Refer to Table 6. Data Strobe (Motorola Mode). Write Enable (Intel mode). 3 DS/ DI WR/ DI SDI/ DI LEN0 DI Serial Data Input (Serial Mode). Line Length Equalizer (Hardware Mode). Host Mode This pin acts as data strobe in Motorola mode and as Write Enable in Intel mode. In serial mode this pin is used as Serial Data Input. Hardware Mode This pin determines the shape and amplitude of the transmit pulse. Refer to Table 6. Mode Select. This pin is used to select the operating mode of the LXT386. In Hardware Mode, the parallel processor interface is disabled and hardwired pins are used to control configuration and report status. In Parallel Host Mode, the parallel port interface pins are used to control configuration and report status. In Serial Host Mode the serial interface pins: SDI, SDO, SCLK and CS are used 79 MODE DI MODE Operating Mode L Hardware Mode H Parallel Host Mode Vcc/2 Serial Host Mode For Serial Host Mode, the pin should connected to a resistive divider consisting of two 10 kΩ resistors across VCC and Ground. 80 INT DO Interrupt. This active Low, maskable, open drain output requires an external 10k pull up resistor. If the corresponding interrupt enable bit is enabled, INT goes Low to flag the host when the LXT388 changes state (see details in the interrupt handling section). The microprocessor INT input should be set to level triggering. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. 16 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 5. Pin # LQFP Pin Assignments and Signal Descriptions - Microprocessor/Configuration Symbol I/O1 Description Data Transfer acknowledge (Motorola Mode). Ready (Intel mode). Serial Data Output (Serial Mode). Motorola Mode 81 ACK/ DO RDY/ DO A Low signal during a databus read operation indicates that the information is valid. A Low signal during a write operation acknowledges that a data transfer into the addressed register has been accepted (acknowledge signal).Wait states only occur if a write cycle immediately follows a previous read or write cycle (e.g. read modify write). SDO DO Intel Mode A High signal acknowledges that a register access operation has been completed (Ready Signal). A Low signal on this pin signals that a data transfer operation is in progress. The pin goes tristate after completion of a bus cycle. Serial Mode If CLKE is High, SDO is valid on the rising edge of SCLK. If CLKE is Low, SDO is valid on the falling edge of SCLK. This pin goes into high Z state during a serial port write access. Address Latch Enable (Host Mode). Shift Clock (Serial Mode). Address Strobe (Motorola Mode). Line Length Equalizer (Hardware Mode). 82 ALE/ DI Host Mode SCLK/ DI AS/ DI The address on the multiplexed address/data bus is clocked into the device with the falling edge of ALE. LEN2 DI In serial Host mode this pin acts as serial shift clock. In Motorola mode this pin acts a an active Low address strobe. Hardware Mode This pin determines the shape and amplitude of the transmit pulse in transceivers 0 and 1. It also determines the receiver setting (T1 or E1) in all the receivers. Please refer to Table 6 on page 26. 83 OE DI Output Driver Enable. If this pin is asserted Low all analog driver outputs immediately enter a high impedance mode to support redundancy applications without external mechanical relays. All other internal circuitry stays active. In software mode, TTIP and TRING can be tristated on a port-by-port basis by writing a ‘1’ to the OEx bit in the Output Enable Register (OER). Clock Edge Select. In clock recovery mode, setting CLKE High causes RDATA or RPOS and RNEG to be valid on the falling edge of RCLK and SDO to be valid on the rising edge of SCLK. Setting CLKE Low makes RDATA or RPOS and RNEG to be valid on the rising edge of RCLK and SDO to be valid on the falling edge of SCLK. In Data recovery Mode, RDATA or RPOS/RNEG are active High output polarity when CLKE is High and active low polarity when CLKE is Low. 84 CLKE DI CLKE RPOS/RNEG SDO Low RCLK SCLK High RCLK SCLK 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Datasheet 17 LXT388 — Dual T1/E1/J1 Transceiver Table 5. Pin Assignments and Signal Descriptions - Microprocessor/Configuration Pin # LQFP Symbol I/O1 89 A4 DI 88 A3 DI 87 A2 DI 86 A1 DI 85 A0 DI Description Address Select Inputs. Host Mode In non-multiplexed host mode, these pins function as non-multiplexed address pins. In multiplexed host mode, these pins must be connected to Ground. Hardware Mode These pins must be grounded. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. 18 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 5. Pin # LQFP Pin Assignments and Signal Descriptions - Microprocessor/Configuration Symbol I/O1 Description Loopback Mode Select/Parallel Data bus. Host Mode: When a non-multiplexed microprocessor interface is selected, these pins function as a bidirectional 8-bit data port. When a multiplexed microprocessor interface is selected, these pins carry both bidirectional 8-bit data and address inputs A0 -A7. In serial Mode, D0-7 should be grounded. Hardware Mode: In hardware mode, these pins control the operation of transceivers 0, 1 and receivers 2, 3 according to the table below. 90 D0/LOOP0 DI/O 91 D1/LOOP1 DI/O 92 D2/LOOP2 DI/O 93 D3/LOOP3 DI/O 94 D4/DLOOP0 DI/O 95 D5/DLOOP1 DI/O 96 D6/DLOOP2 DI/O 97 D7/DLOOP3 DI/O During remote loopback mode, data on TPOS and TNEG is ignored and data received on RTIP and RRING is looped around and retransmitted on TTIP and TRING. Note: in data recovery mode, the pulse template cannot be guaranteed while in a remote loopback. In analog local loopback mode, data received on RTIP and RRING is ignored and data transmitted on TTIP and TRING is internally looped around and routed back to the receiver inputs. Operating Mode Transceivers 0,1 Operating Mode Receivers 2, 3 LOOP DLOOP Open x Normal Mode Normal Mode 0 x Remote Loopback - 1 0 Analog Local Loopback - 1 1 Digital Local Loopback Digital Local Loopback In digital local loopback mode, data received on TCLK/TPOS/TNEG is digitally looped back to RCLK/RPOS/RNEG. Figure 9 through Figure 14 illustrate the different loopback modes. Note: When these inputs are left open, they stay in a high impedance state. Therefore, the layout design should not route signals with fast transitions near the LOOP pins. This practice will minimize capacitive coupling. Multiplexed/Non-Multiplexed Select. 99 MUX DI When Low the parallel host interface operates in non-multiplexed mode. When High the parallel host interface operates in multiplexed mode. In hardware mode tie this unused input low. 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. Datasheet 19 LXT388 — Dual T1/E1/J1 Transceiver Table 5. Pin # LQFP Pin Assignments and Signal Descriptions - Microprocessor/Configuration Symbol I/O1 Description Chip Select/Jitter Attenuator Select. Host Mode This active Low input is used to access the serial/parallel interface. For each read or write operation, CS must transition from High to Low, and remain Low. Hardware Mode 98 CS/ DI JASEL DI This input determines the Jitter Attenuator position in the data path. JASEL JA Position L Transmit path H Receive path Z Disabled 1. DI: Digital Input; DO: Digital Output; DI/O: Digital Bidirectional Port; AI: Analog Input; AO: Analog Output S: Power Supply; N.C.: Not Connected. 20 Datasheet Dual T1/E1/J1 Transceiver — LXT388 2.0 Functional Description The LXT388 is a fully integrated dual line interface unit designed for T1 1.544 Mbps and E1 2.048 Mbps short haul applications. It features two complete transceivers and two additional receiver and jitter attenuation blocks. These block allow the LXT388 to work as a quad T1/E1 receiver with jitter attenuation. Alternatively, these blocks can be used for Driver Performance Monitoring (DPM) in the transceiver channel. They can also be used for jitter attenuation in the receive and transmit paths simultaneously as discussed in “Driver Performance Monitoring” on page 29. Each transceiver front end interfaces with four lines, one pair for transmit, one pair for receive. These two lines comprise a digital data loop for full duplex transmission. The LXT388 can be controlled through hard-wired pins or by a microprocessor through a serial or parallel interface (Host mode). The transmitter timing reference is TCLK, and the receiver reference clock is MCLK. The LXT388 is designed to operate without any reference clock when used as an analog front-end (line driver and data recovery). MCLK is mandatory if the on chip clock recovery capability is used. All four clock recovery circuits share the same reference clock defined by the MCLK input signal. 2.1 Initialization During power up, the transceiver remains static until the power supply reaches approximately 60% of VCC. During power-up, an internal reset sets all registers to their default values and resets the status and state machines for the LOS. 2.1.1 Reset Operation With revision B1, no-connect pin 100 converted to the RESET pin. Only revsion B1 requires a pull up resistor to VCC at pin 100 in the LQFP package as shown in Figure 3. There are two methods of resetting the LXT388: 1. Override Reset - Setting the RESET pin low in either hardware mode or host mode. Until the RESET pin returns high, the LXT388 remains frozen and will not function. Once the RESET pin has returned high, the LXT388 will operaate normally. Override Reset changes all the internal registers to their default values. 2. Software Reset - Writing to the RES reset register initiates a 1microsecond reset cycle, except in Intel non-multiplexed mode. In Intel non-multiplexed mode, the reset cycle takes 2 microseconds. Please refer to Host Mode section for more information. This operation changes all LXT388 registers to their default values. Datasheet 21 LXT388 — Dual T1/E1/J1 Transceiver Figure 3. Pullup Resistor to RESET VCC 1K 100 RESET LXT388 2.2 Receiver The four receivers in the LXT388 are identical. The following paragraphs describe the operation of one. The twisted-pair input is received via a 1:2 step down transformer. Positive pulses are received at RTIP, negative pulses at RRING. Recovered data is output at RPOS and RNEG in the bipolar mode and at RDATA in the unipolar mode. The recovered clock is output at RCLK. RPOS/RNEG validation relative to RCLK is pin selectable using the CLKE pin. The receive signal is processed through the peak detector and data slicers. The peak detector samples the received signal and determines its maximum value. A percentage of the peak value is provided to the data slicers as a threshold level to ensure optimum signal-to-noise ratio. For DSX-1 applications (line length inputs LEN2-0 from 011 to 111) the threshold is set to 70% (typical) of the peak value. This threshold is maintained above the specified level for up to 15 successive zeros over the range of specified operating conditions. For E1 applications (LEN2-0 = 000), the threshold is set to 50% (typical). The receiver is capable of accurately recovering signals with up to 12 dB of attenuation (from 2.4 V), corresponding to a received signal level of approximately 500 mV. Maximum line length is 1500 feet of ABAM cable (approximately 6 dB of attenuation). Regardless of received signal level, the peak detectors are held above a minimum level of 0.150 V (typical) to provide immunity from impulsive noise. After processing through the data slicers, the received signal goes to the data and timing recovery section. The data and timing recovery circuits provide an input jitter tolerance better than required by Pub 62411 and ITU G.823, as shown in Test Specifications, Figure 34. Depending on the options selected, recovered clock and data signals may be routed through the jitter attenuator, through the B8ZS/HDB3/AMI decoder, and may be output to the framer as either bipolar or unipolar data. 22 Datasheet Dual T1/E1/J1 Transceiver — LXT388 2.2.1 Loss of Signal Detector The loss of signal detector in the LXT388 uses a dedicated analog and digital loss of signal detection circuit. It is independent of its internal data slicer comparators and complies to the latest ITU G.775 and ANSI T1.231 recommendations. Under software control, the detector can be configured to comply to the ETSI ETS 300 233 specification (LACS Register). In hardware mode, the LXT388 supports LOS per G.775 for E1 and ANSI T1.231 for T1 operation. The receiver monitor loads a digital counter at the RCLK frequency. The counter is incremented each time a zero is received, and reset to zero each time a one (mark) is received. Depending on the operation mode, a certain number of consecutive zeros sets the LOS signal. The recovered clock is replaced by MCLK at the RCLK output. When the LOS condition is cleared, the LOS flag is reset and another transition replaces MCLK with the recovered clock at RCLK. RPOS/RNEG will reflect the data content at the receiver input during the entire LOS detection period for that channel. 2.2.1.1 E1 Mode In G.775 mode a loss of signal is detected if the signal is below 200mV (typical) for 32 consecutive pulse intervals. When the received signal reaches 12.5% ones density (4 marks in a sliding 32-bit period) with no more than 15 consecutive zeros and the signal level exceeds 250mV (typical), the LOS flag is reset and another transition replaces MCLK with the recovered clock at RCLK. In ETSI 300 233 mode, a loss of signal is detected if the signal is below 200mV for 2048 consecutive intervals (1 ms). The LOS condition is cleared and the output pin returns to Low when the incoming signal has transitions when the signal level is equal or greater than 250mV for more than 32 consecutive pulse intervals. This mode is activated by setting the LACS register bit to one. If it is necessary to use AIS with LOS, see errata 10.3 for a way to implement this. 2.2.1.2 T1 Mode The T1.231 LOS detection criteria is employed. LOS is detected if the signal is below 200mV for 175 contiguous pulse positions. The LOS condition is terminated upon detecting an average pulse density of 12.5% over a period of 175 contiguous pulse positions starting with the receipt of a pulse. The incoming signal is considered to have transitions when the signal level is equal or greater than 250mV. 2.2.1.3 Data Recovery Mode In data recovery mode the LOS digital timing is derived from a internal self timed circuit. RPOS/ RNEG stay active during loss of signal. The analog LOS detector complies with ITU-G.775 recommendation. The LXT388 monitors the incoming signal amplitude. Any signal below 200mV for more than 30µs (typical) will assert the corresponding LOS pin. The LOS condition is cleared when the signal amplitude rises above 250mV. The LXT388 requires more than 10 and less than 255 bit periods to declare a LOS condition in accordance to ITU G.775. 2.2.2 Alarm Indication Signal (AIS) Detection The AIS detection is performed by the receiver independent of any loopback mode. This feature is available in host mode only. Because there is no clock in data recovery mode, AIS detection will not work in that mode. AIS requires MCLK to have clock applied, since this function depends on the clock to count the number of ones in an interval. Datasheet 23 LXT388 — Dual T1/E1/J1 Transceiver 2.2.2.1 E1 Mode One detection mode suitable for both ETSI and ITU is available when the LACS register bits are cleared to zero. If the LACS register bit is set to one, see errata 10.3 to implement this. ETSI ETS300233 and G.775 detection The AIS condition is declared when the received data stream contains less than 3 zeros within a period of 512 bits. The AIS condition is cleared when 3 or more zeros within 512 bits are detected. 2.2.2.2 T1 Mode ANSI T1.231 detection is employed. The AIS condition is declared when less than 9 zeros are detected in any string of 8192 bits. This corresponds to a 99.9% ones density over a period of 5.3 ms. The AIS condition is cleared when the received signal contains 9 or more zeros in any string of 8192 bits. 2.2.3 In Service Code Violation Monitoring In unipolar I/O mode with HDB3/B8ZS decoding, the LXT388 reports bipolar violations on RNEG/BPV for one RCLK period for every HDB3/B8ZS code violation that is not part of the zero code substitution rules. In AMI mode, all bipolar violations (two consecutive pulses with the same polarity) are reported at the BPV output. 2.3 Transmitter The two low power transmitters of the LXT388 are identical. Transmit data is clocked serially into the device at TPOS/TNEG in the bipolar mode or at TDATA in the unipolar mode. The transmit clock (TCLK) supplies the input synchronization. Unipolar I/O and HDB3/B8ZS/AMI encoding/decoding is selected by pulling TNEG High for more than 16 consecutive TCLK clock cycles. The transmitter samples TPOS/TNEG or TDATA inputs on the falling edge of TCLK. Refer to the Test Specifications Section for MCLK and TCLK timing characteristics. If TCLK is not supplied, the transmitter remains powered down and the TTIP/ TRING outputs are held in a High Z state. In addition, fast output tristatability is also available through the OE pin (all ports) and/or the port’s OEx bit in the Output Enable Register (OER). Zero suppression is available only in Unipolar Mode. The two zero-suppression types are B8ZS, used in T1 environments, and HDB3, used in E1 environments. The scheme selected depends on whether the device is set for T1 or E1 operation (determined by LEN2-0 pulse shaping settings). The LXT388 also supports AMI line coding/decoding as shown in Figure 4. In Hardware mode, AMI coding/decoding is selected by the CODEN pin. In host mode, AMI coding/decoding is selected by bit 4 in the GCR (Global Control Register). 24 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 4. 50% AMI Encoding TTIP Bit Cell 1 0 1 TRING Each output driver is supplied by a separate power supply (TVCC and TGND). The transmit pulse shaper is bypassed if no MCLK is supplied while TCLK is pulled high. In this case TPOS and TNEG control the pulse width and polarity on TTIP and TRING. With MCLK supplied and TCLK pulled high the driver enters TAOS (Transmit All Ones pattern). Note: The TAOS generator uses MCLK as a timing reference. In order to assure that the output frequency is within specification limits, MCLK must have the applicable stability.TAOS is inhibited during Remote Loopback. 2.3.0.1 Hardware Mode In hardware mode, pins LEN0-2 determine the pulse shaping as described in Table 6 on page 26. The LEN settings also determine whether the operating mode is T1 or E1. Note that in T1 operation mode, all four ports will share the same pulse shaping setting. Independent pulse shaping for each channel is available in host mode. 2.3.0.2 Host Mode In Host Mode, the contents of the Pulse Shaping Data Register (PSDAT) determines the shape of pulse output at TTIP/TRING. Refer to Table 28 on page 45 and Table 29 on page 45. 2.3.1 Transmit Pulse Shaping The transmitted pulse shape is internally generated using a high speed D/A converter. Shaped pulses are further applied to the line driver for transmission onto the line at TTIP and TRING. The line driver provides a constant low output impedance regardless of whether it is driving marks, spaces or if it is in transition. This well controlled dynamic impedance provides excellent return loss when used with external precision resistors (± 1% accuracy) in series with the transformer. 2.3.1.1 Output Driver Power Supply The output driver power supply (TVCC pins) can be either 3.3V or 5V nominal. When TVCC=5V, LXT388 drives both E1 (75Ω/120Ω) and T1 100Ω lines through a 1:2 transformer and 11Ω/9.1Ω series resistors. When TVCC=3.3V, the LXT388 drives E1 (75Ω/120Ω) lines through a 1:2 transformer and 11Ω series resistor. A configuration with a 1:2 transformer and without series resistors should be used to drive T1 100Ω lines. Datasheet 25 LXT388 — Dual T1/E1/J1 Transceiver Table 6. Line Length Equalizer Inputs Line Length1 Cable Loss2 LEN2 LEN1 LEN0 0 1 1 0 - 133 ft. ABAM 0.6 dB 1 0 0 133 - 266 ft. ABAM 1.2 dB 1 0 1 266 - 399 ft. ABAM 1.8 dB 0 399 - 533 ft. ABAM 2.4 dB 533 - 655 ft. ABAM 3.0 dB 1 1 1 1 1 0 0 0 E1 G.703, 75Ω coaxial cable and 120Ω twisted pair cable. Operation Mode T1 E1 1. Line length from LXT388 to DSX-1 cross-connect point. 2. Maximum cable loss at 772KHz. Removing the series resistors for T1 applications with TVCC=3.3V, improves the power consumption of the device. See Table 40 on page 55. Series resistors in the transmit configuration improve the transmit return loss performance. Good transmit return loss performance minimizes reflections in harsh cable environments. In addition, series resistors provide protection against surges coupled to the device. The resistors should be used in systems requiring protection switching without external relays. Please refer to Figure 5 on page 28 for the recommended external line circuitry. 2.3.1.2 Power Sequencing For the LXT384, we recommend sequencing TVCC first then VCC second or at the same time as TVCC to prevent excessive current draw. 2.4 Line Protection Figure 5 on page 28 shows recommended line interface circuitry. In the receive side, the 1 kΩ series resistors protect the receiver against current surges coupled into the device. Due to the high receiver impedance (70 kΩ typical) the resistors do not affect the receiver sensitivity. In the transmit side, the Schottky diodes D1-D4 protect the output driver.While not mandatory for normal operation, these protection elements are strongly recommended to improve the design robustness. 2.5 Driver Failure Monitor The LXT388 transceiver incorporates a internal power Driver Failure Monitor (DFM) in parallel with TTIP and TRING that is capable of detecting secondary shorts without cable. DFM is available only in configurations with no transmit series resistors (T1 mode with TVCC=3.3V). This feature is available in the serial and parallel host modes but not available in the hardware mode of operation. A capacitor, charged via a measure of the driver output current and discharged by a measure of the maximum allowable current, is used to detect a secondary short failure. Secondary shorted lines draw excess current, overcharging the cap. When the capacitor charge deviates outside the nominal 26 Datasheet Dual T1/E1/J1 Transceiver — LXT388 charge window, a driver short circuit fail (DFM) is reported in the respective register by setting an interrupt. During a long string of spaces, a short-induced overcharge eventually bleeds off, clearing the DFM flag. Note: Unterminated lines of adequate length (λ/4) may effectively behave as short-circuits as seen by the driver and therefore trigger the DFM. Under these circumstances, the alarm should be disabled. In addition, the LXT388 features output driver short-circuit protection. When the output current exceeds 100 mA, LXT388 limits the driver’s output voltage to avoid damage. Datasheet 27 LXT388 — Dual T1/E1/J1 Transceiver Figure 5. External Transmit/Receive Line Circuitry TVCC TVCC 68µF TVS1 1 0.1µF TVCC TGND TVCC D4 RT 1:2 TTIP D3 3.3V VCC TVCC 0.1µF Tx LINE 2 560pF D2 GND TRING RT 3 D1 LXT388 (ONE CHANNEL) 1kΩ 1:2 RTIP RR Rx LINE 0.22µF RR RRING 1kΩ 28 1 Common decoupling capacitor for all TVCC and TGND pins. 2 Typical value. Adjust for actual board parasitics to obtain optimum return loss. 3 Refer to Transformer Specifications Table for transformer specifications. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 6. Driver Performance Monitoring TVCC D4 RT 1:2 TTIP D3 560pF TRANSMITTER # 0/1 TVCC D2 TRING RT D1 LXT388 0.1µF 0.1µF 1.8 kΩ 1.8 kΩ RTIP 470Ω 0.22µF RECEIVER # 2/3 470Ω LOS / DPM 2.6 RRING Driver Performance Monitor The two additional receiver blocks in the LXT388 can be used to monitor the transmitter performance in channels 0 and 1 as illustrated in Figure 6. The transmitter outputs in channels 0 and 1 are connected to receivers 2 and 3 through capacitive coupling. If the output driver stops transmitting data, the LOS output in the monitoring receiver will be asserted indicating a driver failure. Therefore, the LOS output effectively acts as a driver performance monitor indicator (DPM). This alarm is also available in host mode through the LOS registers. The DPM set and reset operation is identical to the LOS set and reset operation as described in “Loss of Signal Detector” on page 23. Datasheet 29 LXT388 — Dual T1/E1/J1 Transceiver Note: 2.7 T1/E1 receiver operation in channels 2 and 3 is determined by the LEN settings as described in Table 6 on page 26. Jitter Attenuation A digital Jitter Attenuation Loop (JAL) combined with a FIFO provides Jitter attenuation. The JAL is internal and requires no external crystal nor high-frequency (higher than line rate) reference clock. The FIFO is a 32 x 2-bit or 64 x 2-bit register (selected by the FIFO64 bit in the GCR). Data is clocked into the FIFO with the associated clock signal (TCLK or RCLK), and clocked out of the FIFO with the dejittered JAL clock. See Figure 7. When the FIFO is within two bits of overflowing or underflowing, the FIFO adjusts the output clock by 1/8 of a bit period. The Jitter Attenuator produces a control delay of 17 or 33 bits in the associated path (refer to test specifications). This feature is required for hitless switching applications. This advanced digital jitter attenuator meets latest jitter attenuation specifications. See Table 7. Under software control, the low limit jitter attenuator corner frequency depends on FIFO length and the JACF bit setting (this bit is in the GCR register). In Hardware Mode, the FIFO length is fixed to 64 bits. The corner frequency is fixed to 6 Hz for T1 mode and 3.5 Hz for E1 mode. Table 7. Jitter Attenuation Specifications T1 E1 AT&T Pub 62411 1 GR-253-CORE ITU-T G.736 ITU-T G.7423 ITU-T G.7834 TR-TSY-0000092 ETSI CTR12/13 BAPT 220 1. 2. 3. 4. 30 Category I, R5-203. Section 4.6.3. Section 6.2 When used with the SXT6234 E2-E1 mux/demux. Section 6.2.3.3 combined jitter when used with the SXT6251 21E1 mapper. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 7. Jitter Attenuator Loop FIFO64 TPOS RPOSi TPOSo RPOS TNEG RNEGi IN CK TCLK RCLKi IN OUT CK DPLL TCLK RCLK OUT JASEL0-1 MCLK TNEGo RNEG FIFO JASEL0-1 x 32 JACF GCR control bits In Host Mode, the Global Control Register (GCR) determines whether the JAL is positioned in the receive path, transmit path or disabled. In Hardware Mode, the JAL position is determined by the JASEL pin. 2.7.1 Transmit and Receive Jitter Attenuation Simultaneous transmit and receive jitter attenuation can be implemented using the additional jitter attenuators in the receiver/JA blocks 2 and 3. Please refer to Figure 8. In this example, the jitter attenuator in channels 0 and 1 is placed in the transmit path. Receive path jitter attenuation is obtained by routing the corresponding RCLK/RPOS/RNEG signals through the JAs in blocks 2 and 3. This is accomplished by enabling a digital loopback in these channels. Note that the CLKE pin should be tied High to allow direct connection between RCLK/RPOS/RNEG and TCLK/ TPOS/TNEG. Connections in Figure 8 are shown for bipolar mode operation. In unipolar mode (TNEG=High), RCLK and RDATA should be connected to TCLK and TDATA. Bipolar violations for channels 0 and 1 will be reported at the BPV (RNEG) outputs in those channels. Datasheet 31 LXT388 — Dual T1/E1/J1 Transceiver Figure 8. Transmit and Receive Jitter Attenuation RCLK RPOS RNEG Timing & Control JA HDB3/B8ZS Decoder* TCLK TPOS TNEG HDB3/B8ZS Encoder* TRANSCEIVERS, #0, 1 TTIP TRING RTIP Timing & Data Recovery RRING LOS 1 HDB3/B8ZS Encoder* RCLK RPOS RNEG JA DIGITAL LOOPBACK TCLK TPOS TNEG HDB3/B8ZS Decoder* MONITORING/JA, #2, 3 RTIP Timing & Data Recovery RRING LOS/DPM * If Enabled 1 2.8 Inverter not necessary if CLKE is high. However, if CLKE is low, inverter required. Loopbacks The LXT388 offers three loopback modes for diagnostic purposes. In hardware mode, the loopback mode is selected with the LOOPn pins. In software mode, the ALOOP, DLOOP and RLOOP registers are employed. 2.8.1 Analog Loopback When selected, the transmitter outputs (TTIP & TRING) are connected internally to the receiver inputs (RTIP & RRING) as shown in Figure 9. Data and clock are output at RCLK, RPOS & RNEG pins for the corresponding transceiver. Note that signals on the RTIP & RRING pins are ignored during analog loopback. 32 Datasheet Dual T1/E1/J1 Transceiver — LXT388 TCLK TPOS TNEG HDB3/B8ZS Encoder* JA* RCLK RPOS RNEG HDB3/B8ZS Decoder* Figure 9. Analog Loopback JA* Timing & Control TTIP Timing Recovery RTIP TRING RRING * If Enabled 2.8.2 Digital Loopback The digital loopback function is available in software and Hardware mode. When selected, the transmit clock and data inputs (TCLK, TPOS & TNEG) are looped back and output on the RCLK, RPOS & RNEG pins (Figure 10). The data presented on TCLK, TPOS & TNEG is also output on the TTIP & TRING pins. Note that signals on the RTIP & RRING pins are ignored during digital loopback. RCLK RPOS RNEG HDB3/B8ZS Encoder* TCLK TPOS TNEG Timing & Control TTIP JA* HDB3/B8ZS Decoder* Figure 10. Digital Loopback JA* Timing Recovery RTIP TRING RRING * If Enabled 2.8.3 Remote Loopback During remote loopback (Figure 11) the RCLK, RPOS & RNEG outputs routed to the transmit circuits and output on the TTIP & TRING pins. Note that input signals on the TCLK, TPOS & TNEG pins are ignored during remote loopback. Datasheet 33 LXT388 — Dual T1/E1/J1 Transceiver TCLK TPOS TNEG HDB3/B8ZS Encoder* JA* RCLK RPOS RNEG HDB3/B8ZS Decoder* Figure 11. Remote Loopback JA* Timing & Control TTIP Timing Recovery RTIP TRING RRING * If Enabled Note: 2.8.4 In data recovery mode, the pulse template cannot be guaranteed while in a remote loopback. Transmit All Ones (TAOS) In Hardware mode, the TAOS mode is set by pulling TCLK High for more than 16 MCLK cycles. In software mode, TAOS mode is set by asserting the corresponding bit in the TAOS Register. In addition, automatic ATS insertion (in case of LOS) may be set using the ATS Register. Note that the TAOS generator uses MCLK as a timing reference, therefore TAOS doesn’t work in data recovery mode. In order to assure that the output frequency is within specification limits, MCLK must have the applicable stability. DLOOP does not function with TOAS active. Figure 12. TAOS Data Path MCLK TCLK TPOS TNEG HDB3/B8ZS Encoder* RCLK RPOS RNEG HDB3/B8ZS Decoder* TAOS mode Timing & Control TTIP TRING (ALL 1’s) JA* Timing Recovery RTIP RRING * If Enabled 34 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 13. TAOS with Digital Loopback MCLK HDB3/B8ZS Encoder* JA* RCLK RPOS RNEG HDB3/B8ZS Decoder* TAOS Mode TCLK TPOS TNEG JA* Timing & Control TTIP TRING (ALL 1’s) Timing Recovery RTIP RRING * If Enabled Figure 14. TAOS with Analog Loopback MCLK TAOS Mode RCLK RPOS RNEG HDB3/B8ZS Encoder* Timing & Control TTIP TRING (ALL 1’s) HDB3/B8ZS Decoder* TCLK TPOS TNEG JA* Timing Recovery RTIP RRING * If Enabled 2.9 Intel Hitless Protection Switching (Intel HPS) The LXT388 transceivers include an output driver tristatability feature for T1/E1/J1 redundancy applications. This feature greatly reduces the cost of implementing redundancy protection by eliminating external relays. Please refer to Application Note 249134 “LXT380/1/4/6/8 Redundancy Applications” for guidelines on implementing redundancy systems for both T1/E1/J1 operation using the LXT380/1/4/6/8. 2.10 Operation Mode Summary Table 8 lists summarizes all LXT388 hardware settings and corresponding operating modes. Table 8. Operation Mode Summary MCLK TCLK LOOP1 Receive Mode Transmit Mode Loopback Clocked Clocked Open Data/Clock recovery Pulse Shaping ON No Loopback Clocked Clocked L Data/Clock recovery Pulse Shaping ON Remote Loopback Clocked Clocked H Data/Clock recovery Pulse Shaping ON Analog Loopback 1. Hardware mode only. Datasheet 35 LXT388 — Dual T1/E1/J1 Transceiver Table 8. Operation Mode Summary (Continued) MCLK TCLK LOOP1 Clocked L Open Data/Clock recovery Power down No Loopback Clocked L L Data/Clock Recovery Power down No effect on op. Clocked L H Data/Clock Recovery Power down No Analog Loopback Clocked H Open Data/Clock Recovery Transmit All Ones No Loopback Receive Mode Transmit Mode Loopback Clocked H L Data/Clock Recovery Pulse Shaping ON Remote Loopback Clocked H H Data/Clock Recovery Transmit All Ones No effect on op. L Clocked Open Power Down Pulse Shaping ON No Loopback L Clocked L Power Down Pulse Shaping ON No Remote Loopback L Clocked H Power Down Pulse Shaping ON No effect on op. L H Open Power Down Pulse Shaping OFF No Loopback L H L Power Down Pulse Shaping OFF No Remote Loop L H H Power Down Pulse Shaping OFF No effect on op. L L X Power Down Power down No Loopback H Clocked Open Data Recovery Pulse Shaping ON No Loopback H Clocked L Data Recovery Pulse Shaping OFF Remote Loopback H Clocked H Data Recovery Pulse Shaping ON Analog Loopback H L Open Data Recovery Power down No Loopback H L L Data Recovery Pulse Shaping OFF Remote Loopback H H Open Data Recovery Pulse Shaping OFF No Loopback H H L Data Recovery Pulse Shaping OFF Remote Loopback H H H Data Recovery Pulse Shaping OFF Analog Loopback 1. Hardware mode only. 2.11 Interfacing with 5V logic The LXT388 can interface directly with 5V logic. The internal input pads are tolerant to 5V outputs from TTL and CMOS family devices. 2.12 Parallel Host Interface The LXT388 incorporates a highly flexible 8-bit parallel microprocessor interface. The interface is generic and is designed to support both non-multiplexed and multiplexed address/data bus systems for Motorola and Intel bus topologies. Two pins (MUX and MOT/INTL) select four different operating modes as shown in Table 9. 36 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 9. Microprocessor Parallel Interface Selection MUX MOT/INTL Operating Mode Low Low Motorola Non-Multiplexed Low High Intel Non-Multiplexed High Low Motorola Multiplexed High High Intel Multiplexed The interface includes an address bus (A4 - A0) and a data bus (D7 - D0) for non-multiplexed operation and an 8-bit address/data bus for multiplexed operation. WR, RD, R/W, CS, ALE, DS, INT and RDY/ACK are used as control signals. A significant enhancement is an internal wait-state generator that controls an Intel and Motorola compatible handshake output signal (RDY/ACK). In Motorola mode ACK Low signals valid information is on the data bus. During a write cycle a Low signal acknowledges the acceptance of the write data. In Intel mode RDY High signals to the controlling processor that the bus cycle can be completed. While Low the microprocessor must insert wait states. This allows the LXT388 to interface with wait-state capable micro controllers, independent of the processor bus speed. To activate this function a reference clock is required on the MCLK pin. There is one exception to write cycle timing for Intel non-multiplexed mode: Register 0Ah, the reset register. Because of timing issues, the RDY line remains high after the first part of the cycle is done, not signalling write cycle completion with another transition low. Add 2 microseconds of delay to allow the reset cycle to completely initialize the device before proceeding. An additional active Low interrupt output signal indicates alarm conditions like LOS and DFM to the microprocessor. The LXT388 has a 5 bit address bus and provides 18 user accessible 8-bit registers for configuration, alarm monitoring and control of the chip. 2.12.1 Motorola Interface The Motorola interface is selected by asserting the MOT/INTL pin Low. In non-multiplexed mode the falling edge of DS is used to latch the address information on the address bus. In multiplexed operation the address on the multiplexed address data bus is latched into the device with the falling edge of AS. In non-multiplexed mode, AS should be pulled High. The R/W signal indicates the direction of the data transfer. The DS signal is the timing reference for all data transfers and typically has a duty cycle of 50%. A read cycle is indicated by asserting R/ W High with a falling edge on DS. A write cycle is indicated by asserting R/W Low with a rising edge on DS. Both cycles require the CS signal to be Low and the Address pins to be actively driven by the microprocessor. Note that CS and DS can be connected together in Motorola mode. In a write cycle the data bus is driven by the microprocessor. In a read cycle the bus is driven by the LXT388. Datasheet 37 LXT388 — Dual T1/E1/J1 Transceiver 2.12.2 Intel Interface The Intel interface is selected by asserting the MOT/INTL pin High. The LXT388 supports nonmultiplexed interfaces with separate address and data pins when MUX is asserted Low, and multiplexed interfaces when MUX is asserted High. The address is latched in on the falling edge of ALE. In non-multiplexed mode, ALE should be pulled High. R/W is used as the RD signal and DS is used as the WR signal. A read cycle is indicated to the LXT388 when the processor asserts RD Low while the WR signal is held High. A write operation is indicated to the LXT388 by asserting WR Low while the RD signal is held High. Both cycles require the CS signal to be Low. 2.13 Interrupt Handling 2.13.1 Interrupt Sources There are three interrupt sources: 1. Status change in the Loss Of Signal (LOS) status register (04H). The LXT388’s analog/digital loss of signal processor continuously monitors the receiver signal and updates the specific LOS status bit to indicate presence or absence of a LOS condition. 2. Status change in the Driver Failure Monitoring (DFM) status register (05H). The LXT388’s smart power driver circuit continuously monitors the output drivers signal and updates the specific DFM status bit to indicate presence or absence of a secondary driver short circuit condition. 3. Status change in the Alarm Indication Signal (AIS) status register (13H).The LXT388’s receiver monitors the incoming data stream and updates the specific AIS status bit to indicate presence or absence of a AIS condition. 2.13.2 Interrupt Enable The LXT388 provides a latched interrupt output (INT). An interrupt occurs any time there is a transition on any enabled bit in the status register. Registers 06H, 07H and 14H are the LOS, DFM and AIS interrupt enable registers (respectively). Writing a logic “1” into the mask register will enable the respective bit in the respective Interrupt status register to generate an interrupt. The power-on default value is all zeroes. The setting of the interrupt enable bit does not affect the operation of the status registers. Registers 08H, 09H and 15H are the LOS, DFM and AIS (respectively) interrupt status registers. When there is a transition on any enabled bit in a status register, the associated bit of the interrupt status register is set and an interrupt is generated (if one is not already pending). When an interrupt occurs, the INT pin is asserted Low. The output stage of the INT pin consists only of a pull-down device; an external pull-up resistor of approximately 10k ohm is required to support wired-OR operation. 2.13.3 Interrupt Clear When an interrupt occurs, the interrupt service routine (ISR) should read the interrupt status registers (08H, 09H and 15H) to identify the interrupt source. Reading the Interrupt Status register clears the "sticky" bit set by the interrupt. Automatically clearing the register prepares it for the next interrupt. The ISR should then read the corresponding status monitor register to obtain the current status of the device. Note: there are three status monitor registers: the LOS (04H), the DFM 38 Datasheet Dual T1/E1/J1 Transceiver — LXT388 (05H) and the AIS (013H). Reading either status monitors register will clear its corresponding interrupts on the rising edge of the read or data strobe. When all pending interrupts are cleared, the INT pin goes High. 2.14 Serial Host Mode The LXT388 operates in Serial Host Mode when the MODE pin is tied to VCC÷2. Figure 15 shows the SIO data structure. The registers are accessible through a 16 bit word: an 8bit Command/ Address byte (bits R/W and A1-A7) and a subsequent 8bit data byte (bits D0-7). Bit R/W determines whether a read or a write operation occurs. Bits A5-0 in the Command/Address byte address specific registers (the address decoder ignores bits A7-6). The data byte depends on both the value of bit R/W and the address of the register as set in the Command/Address byte. Figure 15. Serial Host Mode Timing CS SCLK INPUT DATA BYTE ADDRESS/COMMAND BYTE SDI R/W A1 A2 A3 A4 A5 SDO - REMAINS HIGH Z A6 X A7 X D0 D1 D2 D3 D4 D5 D6 D7 SDO IS DRIVEN IF R/W = 1 R/W = 1: Read from the LXT388 R/W = 0: Write to the LXT388 X = Don’t care Datasheet 39 LXT388 — Dual T1/E1/J1 Transceiver 3.0 Register Descriptions Table 10. Serial and Parallel Port Register Addresses Address Name Symbol ID Register Mode Serial Port A7-A1 Parallel Port A7-A0 ID xx00000 xxx00000 R Analog Loopback ALOOP xx00001 xxx00001 R/W Remote Loopback RLOOP xx00010 xxx00010 R/W TAOS Enable TAOS xx00011 xxx00011 R/W LOS Status Monitor LOS xx00100 xxx00100 R DFM Status Monitor DFM xx00101 xxx00101 R LOS Interrupt Enable LIE xx00110 xxx00110 R/W DFM Interrupt Enable DIE xx00111 xxx00111 R/W LOS Interrupt Status LIS xx01000 xxx01000 R DFM Interrupt Status DIS xx01001 xxx01001 R Software Reset Register RES xx01010 xxx01010 R/W Performance Monitoring MON xx01011 xxx01011 R/W Digital Loopback DL xx01100 xxx01100 R/W LOS/AIS Criteria Selection LOSC xx01101 xxx01101 R/W Automatic TAOS Select ATS xx01110 xxx01110 R/W Global Control Register GCR xx01111 xxx01111 R/W Pulse Shaping Indirect Address Register PSIAD xx10000 xxx10000 R/W Pulse Shaping Data Register PSDAT xx10001 xxx10001 R/W Output Enable Register OER xx10010 xxx10010 R/W AIS Status Register AIS xx10011 xxx10011 R AIS Interrupt Enable AISIE xx10100 xxx10100 R/W AIS Interrupt Status AISIS xx10101 xxx10101 R Table 11. Register Bit Names Register Name Bit Sym RW 7 6 5 4 3 2 1 0 ID R ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0 Analog Loopback ALOOP R/W - - - - reserve d reserved AL1 AL0 Remote Loopback RLOOP R/W - - - - reserve d reserved RL1 RL0 ID Register 40 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 11. Register Bit Names (Continued) Register Bit Name Sym RW 7 6 5 4 3 2 1 0 TAOS Enable TAOS R/W - - - - reserve d reserved TAOS1 TAOS0 LOS Status Monitor LOS R - - - - LOS3 LOS2 LOS1 LOS0 DFM Status Monitor DFM R - - - - reserve d reserved DFM1 DFM0 LOS Interrupt Enable LIE R/W - - - - LIE3 LIE2 LIE1 LIE0 DFM Interrupt Enable DIE R/W - - - - reserve d reserved DIE1 DIE0 LOS Interrupt Status LIS R - - - - LIS3 LIS2 LIS1 LIS0 DFM Interrupt Status DIS R - - - - reserve d reserved DIS1 DIS0 Software Reset Register RES R/W - - - - RES3 RES2 RES1 RES0 Reserved - R/W reserve d reserve d reserve d reserve d reserve d reserved reserved reserved Digital Loopback DL R/W - - - - DL3 DL2 DL1 DL0 LOS/AIS Criteria Select LACS R/W - - - - LACS3 LACS2 LACS1 LACS0 Automatic TAOS Select ATS R/W - - - - reserve d reserved ATS1 ATS0 Global Control Register GCR R/W reserve d RAISE N CDIS CODEN FIFO64 JACF JASEL1 JASEL0 Pulse Shaping Indirect Address Register PSIAD R/W reserve d reserve d reserve d reserve d reserve d LENAD2 LENAD1 LENAD0 Pulse Shaping Data Register PSDAT R/W reserve d reserve d reserve d reserve d reserve d LEN2 LEN1 LEN0 Output Enable Register OER R/W - - - - reserve d reserved OE1 OE0 AIS Status Register AIS R - - - - AIS3 AIS2 AIS1 AIS0 AIS Interrupt Enable AISIE R/W - - - - AISIE3 AISIE2 AISIE1 AISIE0 AIS Interrupt Status AISIS R - - - - AISIS3 AISIS2 AISIS1 AISIS0 Table 12. ID Register, ID (00H) Bit Name Function This register contains a unique revision code and is mask programmed. 7-0 Datasheet ID7-ID0 Revision ID Code A1 00h B1 21h B2 22h 41 LXT388 — Dual T1/E1/J1 Transceiver Table 13. Analog Loopback Register, ALOOP (01H) Bit Name 1-0 AL1-AL0 7-2 - Function Setting a bit to “1” enables analog local loopback for transceivers 1- 0 respectively. Write “0” to these positions for normal operation. Table 14. Remote Loopback Register, RLOOP (02H) Bit Name 1-0 RL1-RL0 7-2 - Function Setting a bit to “1” enables remote loopback for transceivers 1-0 respectively. Write “0” to these positions for normal operation. Table 15. TAOS Enable Register, TAOS (03H) Bit1 Name 1-0 TAOS1-TAOS0 7-2 - Function2 Setting a bit to “1” causes a continuous stream of marks to be sent out at the TTIP and TRING pins of the respective transceiver 1-0. Write “0” to these positions for normal operation. 1. On power up all register bits are set to “0”. 2. MCLK is used as timing reference. If MCLK is not available then the channel TCLK is used as the reference. TAOS is not available in data recovery mode and line driver mode (MCLK=TCLK=High). Table 16. LOS Status Monitor Register, LOS (04H) Bit1 Name Function 3-0 LOS3-LOS0 Respective bit(s) are set to “1” every time the LOS processor detects a valid loss of signal condition in receivers 3-0. 1. On power up all register bits are set to “0”. Any change in the state causes an interrupt. All LOS interrupts are cleared by a single read operation. Table 17. DFM Status Monitor Register, DFM (05H) Bit1 Name 1-0 DFM1-DFM0 7-2 - Function Respective bit(s) are set to “1” every time the short circuit monitor detects a valid secondary output driver short circuit condition in transceivers 1-0. Note that DFM is available only in configurations with no transmit series resistors (T1 mode with TVCC=3.3V). Write “0” to these positions for normal operation. 1. On power-up all the register bits are set to “0”. All DFM interrupts are cleared by a single read operation. 42 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 18. LOS Interrupt Enable Register, LIE (06H) Bit1 Name 3-0 LIE1-LIE0 7-4 - Function Receiver 3-0 LOS interrupts are enabled by writing a “1” to the respective bit. Write “0” to these positions for normal operation. 1. On power-up all the register bits are set to “0”and all interrupts are disabled. Table 19. DFM Interrupt Enable Register, DIE (07H) Bit1 Name 1-0 DIE13-DIE0 7-2 - Function Transceiver 1-0 DFM interrupts are enabled by writing a “1” to the respective bit. Write “0” to these positions for normal operation. 1. On power-up all the register bits are set to “0”and all interrupts are disabled. Table 20. LOS Interrupt Status Register, LIS (08H) Bit Name Function 3-0 LIS3-LIS0 These bits are set to “1” every time a LOS status change has occurred since the last clear interrupt in receivers 3-0 respectively. Table 21. DFM Interrupt Status Register, DIS (09H) Bit Name 1-0 DIS1-DIS0 Function These bits are set to “1” every time a DFM status change has occurred since the last cleared interrupt in transceivers 1-0 respectively. Table 22. Software Reset Register, RES (0AH) Bit Name 3-0 RES3-RES0 Function Writing to this register initiates a 1 microsecond reset cycle, except in Intel nonmultiplexed mode. When using Intel non-multiplexed host mode, extend cycle time to 2 microseconds. Please refer to Host Mode section for more information. This operation sets all LXT388 registers to their default values. Table 23. Reserved (0BH) Bit Name 7-0 reserved Datasheet Function Write “0” to these positions for normal operation. 43 LXT388 — Dual T1/E1/J1 Transceiver Table 24. Digital Loopback Register, DL (0CH) Bit1 Name 3-0 DL3-DL0 Function2 Setting a bit to “1” enables digital loopback for the respective channel. 1. On power up all register bits are set to “0”. 2. During digital loopback LOS and TAOS stay active and independent of TCLK, while data received on TPOS/TNEG/TCKLK is looped back to RPOS/RNEG/RCLK. Table 25. LOS/AIS Criteria Register, LCS (0DH) Bit1 Function2 Name T1 Mode2 Don’t care. T1.231 compliant LOS/AIS detection is used. 3-0 1 LCS3-LCS0 E1 Mode Setting a bit to “1” selects the ETS1 300233 LOS. Setting a bit to “0” selects G.775 LOS mode. AIS works correctly for both ETSI and ITU when the bit is cleared to “0”. See errata revision 10.3 or higher for a way to implement ETSI LOS and AIS. 1. On power-on reset the register is set to “0”. 2. T1 or E1 operation mode is determined by the PSDR settings. Table 26. Automatic TAOS Select Register, ATS (0EH) Bit1 Name 1-0 ATS1-ATS0 7-2 - Function Setting a bit to “1” enables automatic TAOS generation whenever a LOS condition is detected in the respective transceiver. Write “0” to these positions for normal operation. 1. On power-on reset the register is set to “0”.This feature is not available in data recovery and line driver mode (MCLK= High and TCLK = High) Table 27. Global Control Register, GCR (0FH) Bit1 Name 0 JASEL0 1 Function These bits determine the jitter attenuator position. JASEL0 JASEL1 JA Position 1 0 Transmit Path 1 1 Receive Path 0 x Disabled JASEL1 2 JACF 3 FIFO64 This bit determines the jitter attenuator low limit 3dB corner frequency. Refer to the Jitter Attenuator specifications for details (Table 46 on page 60). This bit determines the jitter attenuator FIFO depth: 0 = 32 bit 1 = 64 bit 1. On power-on reset the register is set to “0”. 44 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 27. Global Control Register, GCR (0FH) (Continued) Bit1 Name 4 CODEN 5 CDIS Function This bit selects the zero suppression code for unipolar operation mode: 0 = B8ZS/HDB3 (T1/E1 respectively) 1 = AMI This bit controls enables/disables the short circuit protection feature: 0 = enabled 1 = disabled This bit controls automatic AIS insertion in the receive path when LOS occurs: 6 RAISEN 0 = Receive AIS insertion disabled on LOS 1 = RPOS/RNEG = AIS on LOS Note: this feature is not available in data recovery mode (MCLK=High). Disable AIS interrupts when changing this bit value to prevent inadvertent interrupts. 7 - Reserved. 1. On power-on reset the register is set to “0”. Table 28. Pulse Shaping Indirect Address Register, PSIAD (10H) Bit1 Name Function The three bit value written to these bits determine the channel to be addressed: 0-2 LENAD 0-2 0H = channel 0 1H = channel 1 2H = receiver 2 3H = receiver 3 Data can be read from (written to) the Pulse Shaping Data Register (PSDAT). 3-7 - Reserved. 1. On power-on reset the register is set to “0”. Table 29. Pulse Shaping Data Register, PSDAT (11H) Bit Name Function LEN0-2 determine the LXT388 operation mode (T1 or E1) in all the receivers. In addition, for T1 operation, LEN2-0 set transmit pulse shaping in order to meet T1.102 pulse template at the DSX-1 cross-connect point for various cable lengths. LEN2 0-2 LEN 0-2 1,3 - LEN0 Line Length Cable Loss2 0 1 1 0 - 133 ft. ABAM 0.6 dB 1 0 0 133 - 266 ft. ABAM 1.2 dB 1 0 1 266 - 399 ft. ABAM 1.8 dB 1 1 0 399 - 533 ft. ABAM 2.4 dB 1 1 1 533 - 655 ft. ABAM 3.0 dB 0 E1 G.703, 75Ω coaxial cable and 120 Ω twisted pair cable. 0 3-7 LEN1 0 Operation Mode T1 E1 Reserved. 1. On power-on reset the register is set to “0”. 2. Maximum cable loss at 772 KHz. 3. When reading LEN, bit values appear inverted. “B1” revision silicon will fix this so the bits read back correctly. Datasheet 45 LXT388 — Dual T1/E1/J1 Transceiver Table 30. Output Enable Register, OER (12H) Bit1 Name 1-0 OE1 - OE0 7-2 - Function Setting a bit to “1” tristates the output driver of the corresponding transceiver. Write “0” to these positions for normal operation. 1. On power-up all the register bits are set to “0”. Table 31. AIS Status Monitor Register, AIS (13H) Bit1 Name Function 3-0 AIS3-AIS0 Respective bit(s) are set to “1” every time the receiver detects a AIS condition in receivers 3-0. 1. On power-up all the register bits are set to “0”. All AIS interrupts are cleared by a single read operation. Table 32. AIS Interrupt Enable Register, AISIE (14H) Bit1 Name 3-0 AISIE3-AISIE0 7-4 - Function Transceiver 3-0 AIS interrupts are enabled by writing a “1” to the respective bit. Write “0” to these positions for normal operation. 1. On power-up all the register bits are set to “0”. Table 33. AIS Interrupt Status Register, AISIS (15H) Bit1 Name Function 3-0 AISIS3-AISIS0 These bits are set to “1” every time a AIS status change has occurred since the last clear interrupt in receivers 3-0 respectively. 1. On power-up all the register bits are set to “0”. 46 Datasheet Dual T1/E1/J1 Transceiver — LXT388 4.0 JTAG Boundary Scan 4.1 Overview The LXT388 supports IEEE 1149.1 compliant JTAG boundary scan. Boundary scan allows easy access to the interface pins for board testing purposes. In addition to the traditional IEE1149.1 digital boundary scan capabilities, the LXT388 also includes analog test port capabilities. This feature provides access to the TIP and RING signals in each channel (transmit and receive). This way, the signal path integrity across the primary winding of each coupling transformer can be tested. 4.2 Architecture Figure 16 represents the LXT388 basic JTAG architecture. The LXT388 JTAG architecture includes a TAP Test Access Port Controller, data registers and an instruction register. The following paragraphs describe these blocks in detail. Figure 16. LXT388 JTAG Architecture Boundry Scan Data Register BSR Analog Port Scan Register ASR TDI Device Identification Register IDR MUX TDO Bypass Register BYR Instruction Register IR TCK TMS TAP Controller TRST 4.3 TAP Controller The TAP controller is a 16 state synchronous state machine controlled by the TMS input and clocked by TCK (Figure 17).The TAP controls whether the LXT388 is in reset mode, receiving an instruction, receiving data, transmitting data or in an idle state. Table 34 describes in detail each of the states represented in Figure 17. Datasheet 47 LXT388 — Dual T1/E1/J1 Transceiver Table 34. TAP State Description State 48 Description Test Logic Reset In this state the test logic is disabled. The device is set to normal operation mode. While in this state, the instruction register is set to the ICODE instruction. Run -Test/Idle The TAP controller stays in this state as long as TMS is low. Used to perform tests. Capture - DR The Boundary Scan Data Register (BSR) is loaded with input pin data. Shift - DR Shifts the selected test data registers by one stage word its serial output. Update - DR Data is latched into the parallel output of the BSR when selected. Capture - IR Used to load the instruction register with a fixed instruction. Shift - IR Shifts the instruction register by one stage. Update - IR Loads a new instruction into the instruction register. Pause - IR Pause - DR Momentarily pauses shifting of data through the data/instruction registers. Exit1 - IR Exit1 - DR Exit2 - IR Exit2 - DR Temporary states that can be used to terminate the scanning process. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 17. JTAG State Diagram 1 TEST-LOGIC RESET 0 0 RUN TEST/IDLE 1 SELECT-DR 1 SELECT-IR 0 1 0 1 CAPTURE-DR CAPTURE-IR 0 0 0 0 SHIFT-DR SHIFT-IR 1 1 EXIT1-DR 1 EXIT1-IR 0 0 PAUSE-DR PAUSE-IR 1 1 EXIT2-DR 0 EXIT2-IR 1 0 UPDATE-DR 1 4.4 1 0 0 0 1 0 UPDATE-IR 1 0 JTAG Register Description The following paragraphs describe each of the registers represented in Figure 16. Datasheet 49 LXT388 — Dual T1/E1/J1 Transceiver 4.4.1 Boundary Scan Register (BSR) The BSR is a shift register that provides access to all the digital I/O pins. The BSR is used to apply and read test patterns to/from the board. Each pin is associated with a scan cell in the BSR register. Bidirectional pins or tristatable pins require more than one position in the register. Table 35 shows the BSR scan cells and their functions. Data into the BSR is shifted in LSB first. Table 35. Boundary Scan Register (BSR) Bit # Pin Signal I/O Type Bit Symbol 0 LOS3 O LOS3 RNEG3 O RNEG3 N/A - HIZ3 RPOS3 O RPOS3 RCLK3 O RCLK3 TNEG3 I TNEG3 TPOS3 I TPOS3 TCLK3 I TCLK3 LOS2 O LOS2 RNEG2 O RNEG2 N/A - HIZ2 RPOS2 O RPOS2 RCLK2 O RCLK2 TNEG2 I TNEG2 TPOS2 I TPOS2 TCLK2 I TCLK2 MCLK I MCLK MODE I MODE INT O INTRUPTB N/A - SDORDYENB ACK O SDORDY ALE I ALE OE I OE CLKE I CLKE A0 I A0 A1 I A1 A2 I A2 1. 2. 3. 4. 50 Comments HIZ3 controls the RPOS3, RNEG3 and RCLK3 pins. Setting HIZ3 to “0” enables output on the pins. Setting HIZ3 to “1” tristates the pins. HIZ2 controls the RPOS2, RNEG2 and RCLK2 pins. Setting HIZ2 to “0” enables output on the pins. Setting HIZ2 to “1” tristates the pins. SDORDYENB controls the ACK pin. Setting SDORDYENB to “0” enables output on ACK pin. Setting SDORDYENB to “1” tristates the pin. LOOP4 corresponds to DLOOP0. LOOP5 corresponds to DLOOP1. LOOP6 corresponds to DLOOP2. LOOP7 corresponds to DLOOP3.. Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 35. Boundary Scan Register (BSR) (Continued) Bit # Pin Signal I/O Type Bit Symbol A3 I A3 A4 I A4 LOOP0 I/O PADD0 LOOP0 I/O PDO0 LOOP1 I/O PADI1 LOOP1 I/O PDO1 LOOP2 I/O PADI2 LOOP2 I/O PDO2 LOOP3 I/O PADI3 LOOP3 I/O PDO3 LOOP41 I/O PADI4 LOOP41 I/O PDO4 2 I/O PADI5 2 LOOP5 I/O PDO5 LOOP63 I/O PADI6 LOOP63 I/O PDO6 4 I/O PADI7 LOOP5 LOOP7 Comments PDOENB controls the LOOP0 through LOOP7 pins. N/A - PDOENB Setting PDOENB to “0” configures the pins as outputs. The output value to the pin is set in PDO[0..7]. Setting PDOENB to “1” tristates all the pins. The input value to the pins can be read in PADD[0..7]. LOOP7 1. 2. 3. 4. I/O PDO7 CS I CSB MUX I MUX RESET I RSTB MOT/INTL I IMB R/W I RDB DS I WRB TCLK1 I TCLK1 TPOS1 I TPOS1 TNEG1 I TNEG1 RCLK1 O RCLK1 RPOS1 O RPOS1 N/A - HIZ1 HIZ1 controls the RPOS1, RNEG1 and RCLK1 pins. Setting HIZ1 to “0” enables output on the pins. Setting HIZ1 to “1” tristates the pins. LOOP4 corresponds to DLOOP0. LOOP5 corresponds to DLOOP1. LOOP6 corresponds to DLOOP2. LOOP7 corresponds to DLOOP3.. Datasheet 51 LXT388 — Dual T1/E1/J1 Transceiver Table 35. Boundary Scan Register (BSR) (Continued) Bit # 1. 2. 3. 4. Pin Signal I/O Type Bit Symbol RNEG1 O RNEG1 LOS1 O LOS1 TCLK0 I TCLK0 TPOS0 I TPOS0 TNEG0 I TNEG0 RCLK0 O RCLK0 RPOS0 O RPOS0 N/A - HIZ0 RNEG0 O RNEG0 LOS0 O LOS0 Comments HIZ0 controls the RPOS0, RNEG0 and RCLK0 pins. Setting HIZ0 to “0” enables output on the pins. Setting HIZ0 to “1” tristates the pins. LOOP4 corresponds to DLOOP0. LOOP5 corresponds to DLOOP1. LOOP6 corresponds to DLOOP2. LOOP7 corresponds to DLOOP3.. 4.4.2 Device Identification Register (IDR) The IDR register provides access to the manufacturer number, part number and the LXT388 revision. The register is arranged per IEEE 1149.1 and is represented in Table 36. Data into the IDR is shifted in LSB first. Table 36. Device Identification Register (IDR) 4.4.3 Bit # Comments 31 - 28 Revision Number 27 - 12 Part Number 11 - 1 Manufacturer Number 0 Set to “1” Bypass Register (BYR) The Bypass Register is a 1 bit register that allows direct connection between the TDI input and the TDO output. 4.4.4 Analog Port Scan Register (ASR) The ASR is a 5 bit shift register used to control the analog test port at pins AT1, AT2. When the INTEST_ANALOG instruction is selected, TDI connects to the ASR input and TDO connects to the ASR output. After 5 TCK rising edges, a 5 bit control code is loaded into the ASR. Data into the ASR is shifted in LSB first. 52 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 37 shows the 8 possible control codes and the corresponding operation on the analog port. The Analog Test Port can be used to verify continuity across the coupling transformers primary winding. The Analog Test Port can be used to verify continuity across the coupling transformer’s primary winding as shown in Figure 18. By applying a stimulus to the AT1 input, a known voltage will appear at AT2 for a given load. This, in effect, tests the continuity of a receive or transmit interface. Table 37. Analog Port Scan Register (ASR) ASR Control Code 4.4.5 AT1 Forces Voltage To: AT2 Senses Voltage From: 11111 TTIP0 TRING0 11110 TTIP1 TRING1 11101 Reserved 11100 Reserved 11011 Reserved 11010 Reserved 11001 Reserved 11000 Reserved 10111 RTIP0 RRING0 10110 RTIP1 RRING1 10101 RTIP2 RRING2 10100 RTIP3 RRING3 10011 Reserved 10010 Reserved 10001 Reserved 10000 Reserved Instruction Register (IR) The IR is a 3 bit shift register that loads the instruction to be performed. The instructions are shifted LSB first. Table 38 shows the valid instruction codes and the corresponding instruction description. Table 38. Instruction Register (IR) Instruction Code # EXTEST 000 Connects the BSR to TDI and TDO. Input pins values are loaded into the BSR. Output pins values are loaded from the BSR. INTEST_ANALOG 010 Connects the ASR to TDI and TDO. Allows voltage forcing/sensing through AT1 and AT2. Refer to Table 37. SAMPLE / PRELOAD 100 Connects the BSR to TDI and TDO. The normal path between the LXT388 logic and the I/O pins is maintained. The BSR is loaded with the signals in the I/O pins. IDCODE 110 Connects the IDR to the TDO pin. BYPASS 111 Serial data from the TDI input is passed to the TDO output through the 1 bit Bypass Register. Datasheet Comments 53 LXT388 — Dual T1/E1/J1 Transceiver Figure 18. Analog Test Port Application JTAG Port ASR Register RTIP3 Receiver w/JA 3 RRING3 n/c n/c n/c n/c RTIP1 RRING1 Analog Mux RTIP2 RRING2 Receiver w/JA 2 Transceiver 1 TTIP1 TRING1 1K RTIP0 RRING0 n/ c Transceiver 0 1K TTIP0 TRING0 AT2 AT1 54 Datasheet Dual T1/E1/J1 Transceiver — LXT388 5.0 Test Specifications Table 39 through Table 58 and Figure 19 through Figure 36 represent the performance specifications of the LXT388 and are guaranteed by test except, where noted, by design. The minimum and maximum values listed in Table 41 through Table 58 are guaranteed over the recommended operating conditions specified in Table Table 40. Table 39. Absolute Maximum Ratings Parameter Symbol Min Max Unit DC supply voltage Vcc -0.5 4.0 V DC supply voltage Tvcc 0-3 -0.5 7.0 V Input voltage on any digital pin Vin GND-0.5 5.5 V Input voltage on RTIP, RRING1 Vin GND-0.5 VCC + 0.5 VCC + 0.5 V ESD voltage on any Pin 2 Vin 2000 Transient latch-up current on any pin Iin Input current on any digital pin 3 Iin Iin DC input current on TTIP, TRING 3 DC input current on RTIP, RRING 3 – V 100 mA -10 10 mA – ±100 mA Iin – ±100 mA Storage temperature Tstor -65 +150 °C Case Temperature, 100 pin LQFP package Tcase – 120 mW Case Temperature, 160 pin PBGA package Tcase – 120 °C/W Caution: Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 1. Referenced to ground. 2. Human body model. 3. Constant input current. Table 40. Recommended Operating Conditions Parameter LEN Sym Min Typ Max Unit Test Condition VCC 3.135 3.3 3.465 V 3.3V ± 5% Transmitter supply voltage, TVCC=5V nominal TVCC 4.75 5.0 5.25 V 5V ± 5% Transmitter supply voltage, TVCC=3.3V nominal TVCC 3.135 3.3 3.465 V 3.3V ± 5% Ta -40 25 +85 °C IVCC - 45 60 mA Digital supply voltage (VCC) Ambient operating temperature Average Digital Power Supply Current 1, 4 1. Maximum power and current consumption over the full operating temperature and power supply voltage range. Includes all channels. 2. Power consumption includes power absorbed by line load and external transmitter components. 3. T1 maximum values measured with maximum cable length (LEN = 111). Typical values measured with typical cable length (LEN = 101). 4. Digital inputs are within 10% of the supply rails and digital outputs are driving a 50pF load. Datasheet 55 LXT388 — Dual T1/E1/J1 Transceiver Table 40. Recommended Operating Conditions (Continued) Parameter LEN Average Transmitter Power Supply Current, T1 Mode 1, 2, 3 Output load at TTIP and TRING Sym Min ITVCC - Rl 25 Typ Max Unit Test Condition 108 123 mA 100% 1’s 60 - mA 50% 1’s – – Ω Typ Max1,2 Unit Test Condition Device Power Consumption Mode TVCC E1 Load LEN 75 Ω 000 120 Ω 000 100 Ω 101-111 75 Ω 000 120 Ω 000 100 Ω 101-111 - - 350 - mW 50% 1’s - - - 470 mW 100% 1’s - - 330 - mW 50% 1’s - - - 430 mW 100% 1’s 3.3V T13 3.3V E1 - - 410 - mW 50% 1’s - - - 640 mW 100% 1’s - - 470 - mW 50% 1’s - - - 640 mW 100% 1’s 5.0V T13 5.0V - - 440 - mW 50% 1’s - - - 650 mW 100% 1’s - - 580 - mW 50% 1’s - - - 870 mW 100% 1’s 1. Maximum power and current consumption over the full operating temperature and power supply voltage range. Includes all channels. 2. Power consumption includes power absorbed by line load and external transmitter components. 3. T1 maximum values measured with maximum cable length (LEN = 111). Typical values measured with typical cable length (LEN = 101). 4. Digital inputs are within 10% of the supply rails and digital outputs are driving a 50pF load. Table 41. DC Characteristics Parameter Sym High level input voltage Low level input voltage Typ Max Unit Vih 2 – – V Vil – – 0.8 V VCC V IOUT= 400µA IOUT= 1.6mA 1 Voh 2.4 – 1 Vol High level output voltage Low level output voltage Min Low level input voltage – – 0.4 V Vinl – – 1/3VCC-0.2 V MODE, LOOP0-3 Midrange level input voltage Vinm 1/3VCC+0.2 1/2VCC 2/3VCC-0.2 V and High level input voltage Vinh 2/3VCC+0.2 – – V JASEL Low level input current Iinl – – 50 µA High level input current Iinh – – 50 µA Iil -10 +10 µA Ihz -10 +10 µA Input leakage current Tri state leakage current 56 Test Condition Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 41. DC Characteristics (Continued) Parameter Tri state output current Sym Min Typ Max Unit Ihz – – 1 µA Line short circuit current – – – 50 Input Leakage (TMS, TDI, TRST) – – – 50 mA RMS Test Condition TTIP, TRING 2 x 11 Ω series resistors and 1:2 transformer µA Table 42. E1 Transmit Transmission Characteristics Parameter Sym 75Ω Output pulse amplitude Typ Max Unit 2.14 2.37 2.60 V 2.7 3.0 3.3 V -0.237 0.237 V -0.3 0.3 V – 120Ω Peak voltage of a space Min 75Ω – 120Ω Transmit amplitude variation with supply – Difference between pulse sequences – Pulse width ratio of the positive and negative pulses – Transmit transformer turns ratio for -1 0.95 % mV Tested at the line side For 17 consecutive pulses At the nominal half amplitude 1.05 – 75/120Ω characteristic impedance +1 200 Test Condition Rt = 11 Ω ± 1% 1:2 Note: 51kHz to 102 kHz Note: Transmit return loss 75 Ω coaxial cable1 Transmit return loss 120 Ω twisted pair cable1 Note: 102 kHz to 2.048 MHz – Note: 2.048 MHz to 3.072 MHz 51kHz to 102 kHz 102 kHz to 2.048 MHz – 2.048 MHz to 3.072 MHz Transmit intrinsic jitter; 20Hz to 100kHz – 15 17 15 17 15 17 15 20 15 20 15 20 – 0.030 dB – dB Using components in the LXD384 evaluation board. dB dB – dB 0.050 U.I. Using components in the LXD384 evaluation board. dB Bipolar mode 2 U.I. Unipolar mode 7 U.I. Transmit path delay Tx path TCLK is jitter free JA Disabled 1. Guaranteed by design and other correlation methods. Table 43. E1 Receive Transmission Characteristics Parameter Permissible cable attenuation Sym Min Typ Max Unit Test Condition – – – 12 dB Receiver dynamic range DR 0.5 – – Vp Signal to noise interference margin S/Ι -15 – – dB Per G.703, O.151 @ 6 dB cable Attenuation SRE 43 50 57 % Rel. to peak input voltage – – 150 – mV Data decision threshold Data slicer threshold @1024 kHz 1. Guaranteed by design and other correlation methods. Datasheet 57 LXT388 — Dual T1/E1/J1 Transceiver Table 43. E1 Receive Transmission Characteristics (Continued) Parameter Sym Min Typ Max Unit Loss of signal threshold – – 200 – mV LOS hysteresis – – 50 – mV Consecutive zeros before loss of signal – – – – LOS reset – 12.5% – – – – 1.5 – – Low limit 1Hz to 20Hz input jitter 20Hz to 2.4kHz tolerance 1 18kHz to 100kHz 32 2048 36 0.2 G.775 recommendation ETSI 300 233 specification 1’s density U.I. G735 recommendation U.I. Note 1 U.I. Cable Attenuation is 6 dB @1.024 MHz Differential receiver input impedance – – 70 – kΩ Input termination resistor tolerance – – – ±1 % Common mode input impedance to ground – – 20 – kW 51 kHz - 102 kHz Input return loss1 102 - 2048 kHz 20 – dB Measured against nominal impedance using components in the LXD384 evaluation board. dB 20 2048kHz - 3072 kHz Test Condition – dB 20 LOS delay time – – 30 – ∝σ Data recovery mode LOS reset – 10 – 255 marks Data recovery mode – – 0.040 0.0625 U.I. Receive intrinsic jitter, RCLK output Receive path delay Bipolar mode 1 U.I. Unipolar mode 6 U.I. Wide band jitter JA Disabled 1. Guaranteed by design and other correlation methods. Table 44. T1 Transmit Transmission Characteristics Parameter Sym Min Typ Max Unit – 2.4 3.0 3.6 V – -0.15 – +0.15 V – – 1 – Ω Transmit amplitude variation with power supply – -1 – +1 % Ratio of positive to negative pulse amplitude – 0.95 – 1.05 – T1.102, isolated pulse Difference between pulse sequences – – – 200 mV Pulse width variation at half amplitude – – – 20 ns For 17 consecutive pulses, GR-499-CORE Output pulse amplitude Peak voltage of a space Driver output impedance 1 8KHz - 40KHz 10Hz - 40KHz – – – @ 772 KHz @ 1544 KHz @ 772 KHz 0.025 0.025 UIpk-pk AT&T Pub 62411 TCLK is jitter free. 0.050 Wide Band Output power levels2 Measured at the DSX 0.020 10Hz - 8KHz Jitter added by Transmitter1 Test Condition – 12.6 -29 – 17.9 dBm dBm T1.102 - 1993 Referenced to power at 772 KHz 1. Guaranteed by design and other correlation methods. 2. Power measured in a 3 KHz bandwidth at the point the signal arrives at the distribution frame for an all 1’s pattern. 58 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 44. T1 Transmit Transmission Characteristics (Continued) Parameter Sym Min Typ 15 21 15 21 15 21 dB Bipolar mode 2 U.I. Unipolar mode 7 U.I. 51kHz to 102 kHz Transmit return loss 1 102 kHz to 2.048 MHz – 2.048 MHz to 3.072 MHz Max Unit dB – dB Transmit path delay Test Condition With transmit series resistors (TVCC=5V). Using components in the LXD384 evaluation board. JA Disabled 1. Guaranteed by design and other correlation methods. 2. Power measured in a 3 KHz bandwidth at the point the signal arrives at the distribution frame for an all 1’s pattern. Table 45. T1 Receive Transmission Characteristics Parameter Permissible cable attenuation Sym Min Typ Max Unit Test Condition – – – 12 dB Receiver dynamic range DR 0.5 – – Vp Signal to noise interference margin S/I -16.5 – – dB @ 655 ft. of 22 ABAM cable SRE 63 70 77 % Rel. to peak input voltage Data slicer threshold – – 150 – mV Loss of signal threshold – – 200 – mV LOS hysteresis – – 50 – mV Consecutive zeros before loss of signal – 100 175 250 – T1.231 - 1993 LOS reset – 12.5% – – – 1’s density Data decision threshold Low limit 0.1Hz to 1Hz input jitter 4.9Hz to 300Hz tolerance 1 10KHz to 100KHz 138 - 28 - - Input termination resistor tolerance - - Common mode input impedance to ground - - 51 KHz - 102 KHz Input return loss1 102 - 2048 KHz - - - 20 U.I. 70 20 - kΩ ±1 % - kΩ - - 20 30 - @772 kHz dB Measured against nominal impedance. Using components in the LXD384 evaluation board. µs Data recovery mode dB dB - - LOS reset - 10 - 255 - Receive intrinsic jitter, RCLK output1 - - 0.035 0.0625 U.I. Receive path delay AT&T Pub. 62411 U.I. 20 2048 KHz - 3072 KHz LOS delay time U.I. 0.4 Differential receiver input impedance @ 772 KHz Bipolar mode 1 U.I. Unipolar mode 6 U.I. Data recovery mode Wide band jitter JA Disabled 1. Guaranteed by design and other correlation methods. Datasheet 59 LXT388 — Dual T1/E1/J1 Transceiver Table 46. Jitter Attenuator Characteristics Parameter Min Typ Max Unit - 2.5 - Hz - 3.5 - Hz - 2.5 - Hz - 3.5 - Hz - 3 - Hz - 3 - Hz - 6 - Hz - 6 - Hz E1 - 3.5 - Hz T1 - 6 - Hz - 17 - UI - 33 - UI - 24 - UI - 56 - UI 32bit JACF = 0 E1 jitter attenuator 3dB corner frequency, host mode1 FIFO 64bit FIFO 32bit JACF = 1 FIFO 64bit FIFO 32bit JACF = 0 T1 jitter attenuator 3dB corner frequency, host mode1 FIFO 64bit FIFO 32bit JACF = 1 FIFO 64bit FIFO Jitter attenuator 3dB corner frequency, hardware mode1 32bit FIFO Data latency delay 64bit FIFO 32bit Input jitter tolerance before FIFO overflow or underflow FIFO 64bit FIFO Test Condition Sinusoidal jitter modulation Delay through the Jitter attenuator only. Add receive and transmit path delay for total throughput delay. E1 jitter attenuation @ @ @ @ 3 Hz 40 Hz 400 Hz 100 KHz -0.5 -0.5 +19.5 +19.5 – – dB ITU-T G.736, See Figure 35 on page 76 T1 jitter attenuation @ @ @ @ @ 1 Hz 20 Hz 1 KHz 1.4 KHz 70 KHz 0 0 33.3 40 40 – – dB AT&T Pub. 62411, See Figure 35 on page 76 0.060 0.11 UI ETSI CTR12/13 Output jitter Output Jitter in remote loopback1 1. Guaranteed by design and other correlation methods. 60 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 47. Analog Test Port Characteristics Parameter Sym 3 dB bandwidth Min Typ Max Unit At13db - 5 - MHz Input voltage range At1iv 0 - VCC V Output voltage range At2ov 0 - VCC V Test Condition Figure 19. Transmit Clock Timing Diagram TCLK tSUT TPOS tHT TNEG Table 48. Transmit Timing Characteristics Parameter Sym Min Typ Max Unit E1 MCLK – 2.048 – MHz T1 MCLK – 1.544 – MHz – -100 – 100 ppm Test Condition Master clock frequency Master clock tolerance Master clock duty cycle – 40 – 60 % E1 Tw 219 244 269 ns T1 Tw 291 324 356 ns E1 Tclke1 - 2.048 - MHz T1 Output pulse width Transmit clock frequency Tclkt1 - 1.544 - MHz Transmit clock tolerance Tclkt -50 – +50 ppm Transmit clock burst rate Tclkb - – 20 MHz Transmit clock duty cycle Tdc 10 – 90 % NRZ mode Tmpwe1 236 – 252 ns RZ mode (TCLK = H for >16 clock cycles) TPOS/TNEG to TCLK setup time Tsut 20 - - ns TCLK to TPOS/TNEG hold time Tht 20 - - ns Delay time OE Low to driver High Z Toez - - 1 µs Delay time TCLK Low to driver High Z Ttz 50 60 75 µs E1 TPOS/TNEG pulse width (RZ mode) Datasheet Gapped transmit clock 61 LXT388 — Dual T1/E1/J1 Transceiver Table 49. Receive Timing Characteristics Parameter Sym Min Typ Max Unit Test Condition E1 – – ±80 – ppm Relative to nominal frequency T1 – – ±180 – ppm MCLK = ±100 ppm Rckd 40 50 60 % E1 Tpw 447 488 529 ns T1 Tpw 583 648 713 ns E1 Tpwl 203 244 285 ns T1 Tpwl 259 324 389 ns E1 Tpwh 203 244 285 ns T1 Tpwh 259 324 389 ns Tr 20 – – ns E1 Tpwdl 200 244 300 ns T1 Tpwdl 250 324 400 ns 200 244 – ns 200 324 – ns 200 244 – ns 200 324 – ns – – 5 ns Clock recovery capture range Receive clock duty cycle 1 Receive clock pulse width 1 Receive clock pulse width Low time Receive clock pulse width High time Rise/fall time 4 RPOS/RNEG pulse width (MCLK=H) 2 E1 RPOS/RNEG to RCLK rising setup time @ CL=15 pF Tsur T1 E1 RCLK Rising to RPOS/RNEG hold time Thr T1 Delay time between RPOS/RNEG and RCLK – MCLK = H 3 1. RCLK duty cycle widths will vary depending on extent of received pulse jitter displacement. Maximum and minimum RCLK duty cycles are for worst case jitter conditions (0.2UI displacement for E1 per ITU G.823). 2. Clock recovery is disabled in this mode. 3. If MCLK = H the receive PLLs are replaced by a simple EXOR circuit. 4. For all digital outputs. Figure 20. Receive Clock Timing Diagram tPW RCLK tPWH tPWL tSUR tHR RPOS RNEG CLKE = 1 tSUR tHR RPOS RNEG CLKE = 0 62 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 50. Intel Mode Read Timing Characteristics Parameter2 Sym Address setup time to latch Typ1 Min Max Unit Tsalr 10 – – ns Valid address latch pulse width Tvl 30 – – ns Latch active to active read setup time Tslr 10 – – ns Chip select setup time to active read Tscsr 0 – – ns – – ns Chip select hold time from inactive read Thcsr 0 Address hold time from inactive ALE Thalr 5 Active read to data valid delay time Tprd 10 – 50 ns Address setup time to RD inactive Thar 1 – – ns Test Conditions ns Address hold time from RD inactive Tsar 5 – – ns Inactive read to data tri-state delay time Tzrd 3 – 35 ns Valid read signal pulse width Tvrd 60 – – ns Inactive read to inactive INT delay time Tint – – 10 ns Active chip select to RDY delay time Tdrdy 0 – 12 ns Active ready Low time Tvrdy – – 40 ns Inactive ready to tri-state delay time Trdyz – – 3 ns 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. Table 51. JTAG Timing Characteristics Parameter Sym Min Typ Max Unit Cycle time Tcyc 200 - - ns J-TMS/J-TDI to J-TCK rising edge time Tsut 50 - - ns Tht 50 - - ns Tdod - - 50 ns J-CLK rising to J-TMS/L-TDI hold time J-TCLK falling to J-TDO valid Test Conditions Figure 21. JTAG Timing tCYC TCK tSUR tHT TMS TDI tDOD TDO Datasheet 63 LXT388 — Dual T1/E1/J1 Transceiver Figure 22. Non-Multiplexed Intel Mode Read Timing tSAR ADDRESS A4 - A0 tHAR ALE (pulled High) tHCSR tSCSR CS tVRD RD tPRD tZRD D7 - D0 DATA OUT tINT INT tDRDY tDRDY Tristate tVRDY tRDYZ Tristate RDY 64 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 23. Multiplexed Intel Read Timing tVL tSLR ALE tSCSR tHSCR CS tVRD tPRD RD tSALR tZRD tHALR ADDRESS AD7-AD0 DATA OUT tINT INT tDRDY tDRDY tVRDY tRDYZ Tristate Tristate RDY Table 52. Intel Mode Write Timing Characteristics Parameter2 Address setup time to latch Sym Min Typ1 Max Unit Tsalw 10 – – ns Valid address latch pulse width Tvl 30 – – ns Latch active to active write setup time Tslw 10 – – ns Chip select setup time to active write Tscsw 0 – – ns Chip select hold time from inactive write Thcsw 0 – – ns Address hold time from inactive ALE Thalw 5 Data valid to write active setup time Tsdw 40 – – ns Data hold time to active write Thdw 30 – – ns Address setup time to WR inactive Thaw 2 – – ns Address hold time from WR inactive Tsaw 6 – – ns Test Conditions ns 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. 3. These times don’t apply for Reset Register 0Ah, since RDY line goes low once during the cycle. Please refer to Reset Operation and Host Mode sections for more information. Datasheet 65 LXT388 — Dual T1/E1/J1 Transceiver Table 52. Intel Mode Write Timing Characteristics (Continued) Parameter2 Sym Min Typ1 Valid write signal pulse width Tvwr 60 Inactive write to inactive INT delay time Tint – Tdrdy Chip select to RDY delay time 3 Active ready Low time Inactive ready to tri-state delay time 3 Max Unit – – ns – 10 ns 0 – 12 ns Tvrdy – – 40 ns Trdyz – – 3 ns Test Conditions 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. 3. These times don’t apply for Reset Register 0Ah, since RDY line goes low once during the cycle. Please refer to Reset Operation and Host Mode sections for more information. Figure 24. Non-Multiplexed Intel Mode Write Timing tSAW A4-A0 ALE ADDRESS (pulled High) tHAW tSCSW tHCSW CS tVWR WR tHDW tSDW D7-D0 WRITE DATA tINT INT tDRDY tDRDY Tristate tVRDY tRDYZ Tristate RDY 66 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 25. Multiplexed Intel Mode Write Timing tSLW ALE tVL tSCSW tHCSW CS tVWR WR tHALW tHDW tSALW tSDW ADDRESS AD7-AD0 WRITE DATA tINT INT tDRDY tDRDY tDRDYZ tVRDY Tristate Tristate RDY Table 53. Motorola Bus Read Timing Characteristics Parameter2 Sym Min Typ1 Max Unit Address setup time to address or data strobe Tsar 10 – – ns Address hold time from address or data strobe Thar 5 – – ns Valid address strobe pulse width Tvas 95 – – ns R/W setup time to active data strobe Tsrw 10 – – ns R/W hold time from inactive data strobe Thrw 0 – – ns Chip select setup time to active data strobe Tscs 0 – – ns Chip select hold time from inactive data strobe Thcs 0 – – ns Address strobe active to data strobe active delay Tasds 20 – – ns Delay time from active data strobe to valid data Tpds 3 – 30 ns Delay time from inactive data strobe to data High Z Tdz 3 – 30 ns Valid data strobe pulse width Tvds 60 – – ns Inactive data strobe to inactive INT delay time Tint – – 10 ns Data strobe inactive to address strobe inactive delay Tdsas 15 – – ns DS asserted to ACK asserted delay Tdackp – – 40 ns DS deasserted to ACK deasserted delay Tdack – – 10 ns Active ACK to valid data delay Tpack – – 0 ns Test Conditions 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. Datasheet 67 LXT388 — Dual T1/E1/J1 Transceiver Figure 26. Non-Multiplexed Motorola Mode Read Timing A4-A0 ADDRESS tSAR AS tHAR (pulled High) tSRW tHRW R/W tSCS tHCS CS tVDS DS tPDS tDZ D7-D0 DATA OUT tINT INT tDACKP tPACK tDACK ACK 68 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 27. Multiplexed Motorola Mode Read Timing tVAS tDSAS AS tSRW tHRW R/W tSCS tHCS CS tASDS tVDS DS tPDS tSAR D7-D0 tHAR tDZ DATA OUT ADDRESS tINT INT tDACKP tDACK tPACK ACK Table 54. Motorola Mode Write Timing Characteristics Parameter2 Sym Min Typ1 Max Unit Address setup time to address strobe Tsas 10 – – ns Address hold time to address strobe Thas 5 – – ns Valid address strobe pulse width Tvas 95 – – ns R/W setup time to active data strobe Tsrw 10 – – ns R/W hold time from inactive data strobe Thrw 0 – – ns Chip select setup time to active data strobe Tscs 0 – – ns Chip select hold time from inactive data strobe Thcs 0 – – ns Address strobe active to data strobe active delay Tasds 20 – – ns Data setup time to DS deassertion Tsdw 40 – – ns Data hold time from DS deassertion Thdw 30 – – ns Valid data strobe pulse width Tvds 60 – – ns Inactive data strobe to inactive INT delay time Tint – – 10 ns Test Conditions 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. Datasheet 69 LXT388 — Dual T1/E1/J1 Transceiver Table 54. Motorola Mode Write Timing Characteristics (Continued) Parameter2 Sym Min Typ1 Data strobe inactive to address strobe inactive delay Tdsas 15 Active data strobe to ACK output enable time Tdack 0 DS asserted to ACK asserted delay Tdackp Max Unit – – ns – 12 ns – 40 ns Test Conditions 1. Typical figures are at 25 C and are for design aid only; not guaranteed and not subject to production testing. 2. CL= 100pF on D0-D7, all other outputs are loaded with 50pF. Figure 28. Non-Multiplexed Motorola Mode Write Timing A4-A0 ADDRESS tSAS tHAS AS (pulled High) tSRW tHRW R/W tSCS tHCS CS tVDS DS tSDW tHDW WRITE DATA D7-D0 tINT INT tDACKP tDACK ACK 70 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 29. Multiplexed Motorola Mode Write Timing tVAS tDSAS AS tHRW tSRW R/W tHCS tSCS CS tASDS tVDS DS tSAS D7-D0 tHDW tHAS tSDW ADDRESS WRITE DATA tINT INT tDACKP tDACK ACK Table 55. Serial I/O Timing Characteristics Sym Min Typ1 Max Unit Rise/fall time any pin Trf - - 100 ns SDI to SCLK setup time Tdc 5 - - ns SCLK to SDI hold time Parameter Tcdh 5 - - ns SCLK Low time Tcl 25 - - ns SCLK High time Tch 25 - - ns Tr, Tf - - 50 ns SCLK rise and fall time CS falling edge to SCLK rising edge Tcc 10 - - ns Last SCLK edge to CS rising edge Tcch 10 - - ns CS inactive time Tcwh 50 - - ns SCLK to SDO valid delay time Tcdv - - 5 ns SCLK falling edge or CS rising edge to SDO High Z Tcdz - 10 - ns Test Condition Load 1.6mA, 50 pF 1. Typical figures are at 25 C° and are for design aid only; not guaranteed and not subject to production testing. Datasheet 71 LXT388 — Dual T1/E1/J1 Transceiver Figure 30. Serial Input Timing CS tCWH tCC tCH tCCH tCL SCLK tCDH tDC tCDH LSB LSB SDI MSB CONTROL BYTE DATA BYTE Figure 31. Serial Output Timing CLKE = 0 1 2 3 4 5 6 7 8 9 10 11 1 2 12 13 14 15 5 6 16 SCLK CS tCCH tCDZ SDO 0 4 3 7 CLKE = 1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 SCLK CS 0 SDO 1 2 3 4 5 tCDZ 6 tCCH 7 Table 56. Transformer Specifications3 Leakage Inductance µH (max.) Interwinding Capacitance pF (max.) Tx/Rx Turns Ratio Primary Inductance mH (min.) TX 1:2 1.2 0.60 60 RX 1:2 1.2 0.60 60 1 DCR Ω (max.) 0.70 pri 1.20 sec 1.10 pri 1.10 sec Dielectric Breakdown Voltage V2 (min.) 1500 Vrms 1500 Vrms 1. Transformer turns ratio accuracy is ± 2%. 2. This parameter is application dependent.LIU side: Line side. 3. Refer to the FAQ or Application Note “Transformer Specification for Intel Transceiver Applications “ for recommended magnetics. 72 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Table 57. G.703 2.048 Mbit/s Pulse Mask Specifications Cable Parameter Unit TWP Coax Test load impedance 120 75 Ω Nominal peak mark voltage 3.0 2.37 V Nominal peak space voltage 0 ±0.30 0 ±0.237 V Nominal pulse width 244 244 ns Ratio of positive and negative pulse amplitudes at center of pulse 95-105 95-105 % Ratio of positive and negative pulse amplitudes at nominal half amplitude 95-105 95-105 % Figure 32. E1, G.703 Mask Templates 20% 20% V = 100% 10% 10% 269 ns (244+25) 194 ns (244- 50) NOMINAL PULSE 50% 244 ns 20% 10% 10% 0% 10% 10% 219 ns (244-25) 488 ns (244+244) Table 58. T1.102 1.544 Mbit/s Pulse Mask Specifications Cable Parameter Unit TWP Test load impedance 100 Ω Nominal peak mark voltage 3.0 V Nominal peak space voltage 0 ±0.15 V 324 ns 95-105 % Nominal pulse width Ratio of positive and negative pulse amplitudes Datasheet 73 LXT388 — Dual T1/E1/J1 Transceiver Figure 33. T1, T1.102 Mask Templates 1.20 1.00 0.80 Normalized Amplitude 0.60 0.40 0.20 -0.80 -0.60 -0.40 -0.20 0.00 0.00 0.20 0.40 0.60 0.80 1.00 1.20 -0.20 -0.40 -0.60 Tim e [UI] 74 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 34. Jitter Tolerance Performance 1000 UI Jitter 100 UI 28 UI @ 4.9 Hz AT&T 62411, Dec 1990 (T1) 18 UI @ 1.8 Hz LXT388 typ. 28 UI @ 300 Hz 10 UI GR-499-CORE, Dec 1995 (T1) 5 UI @ 500 Hz 0.4 UI @ 10 kHz ITU G.823, Mar 1993 (E1) 1 UI 1.5 UI @ 2.4 kHz 1.5 UI @ 20 Hz .1 UI 1 Hz 0.2 UI @ 18 kHz 0.1 UI @ 8 kHz 10 Hz 100 Hz 1 kHz 10 kHz 100 kHz Frequency Datasheet 75 LXT388 — Dual T1/E1/J1 Transceiver Figure 35. Jitter Transfer Performance 10 dB E1 ITU G.736 Template 0.5 dB @ 3Hz 0 dB 0.5 dB @ 40Hz -10 dB Gain f 3dB =2.5 Hz -19.5 dB @ 20 kHz -20 dB f 3dB =3.5 Hz -19.5 dB @ 400 Hz -30 dB -40 dB LXT388 typ. -60 dB -80 dB 1 Hz 10 Hz 100 Hz 1 kHz 10 kHz 100 kHz Frequency 10 dB T1 0 dB @ 1 Hz 0 dB @ 20 Hz 0.1 dB @ 40 Hz 0.5 dB @ 350 Hz 0 dB AT&T Pub 62411 GR-253-CORE TR-TSY-000009 Gain -10 dB -20 dB -6 dB @ 2 Hz -33.3 dB @ 1 kHz -33.7 dB @ 2.5kHz f 3dB = 3 Hz -30 dB -40 dB @ 1.4 kHz f 3dB = 6 Hz -40 dB -40 dB @ 70 kHz -49.2 dB @ 15kHz LXT388 typ. -60 dB -60 dB @ 57 Hz -80 dB 1 Hz 10 Hz 100 Hz 1 kHz 10 kHz 100 kHz Frequency 76 Datasheet Dual T1/E1/J1 Transceiver — LXT388 Figure 36. Output Jitter for CTR12/13 applications Jitter Amplitude (Ulpp) 0.2 0.15 0.1 LXT388 typ, f 3dB = 2.5Hz & 3.5 Hz 0.05 0 10 Hz 5.1 20 Hz 100 Hz 1 kHz Frequency 10 kHz 100 kHz Recommendations and Specifications AT&T Pub 62411 ANSI T1.102 - 199X Digital Hierarchy Electrical Interface ANSI T1.231 - 1993 Digital Hierarchy Layer 1 In-Service Digital Transmission Performance Monitoring Bellcore TR-TSY-000009 Asynchronous Digital Multiplexes Requirements and Objectives Bellcore GR-253-CORE SONET Transport Systems Common Generic Criteria Bellcore GR-499-CORE Transport Systems Generic Requirements G.703 Physical/electrical characteristics of hierarchical digital interfaces G. 704 Functional characteristics of interfaces associated with network nodes G.735 Characteristics of Primary PCM multiplex equipment operating at 2048 kbit/s and offering digital access at 384 kbit/s and/or synchronous digital access at 64 kbit/s G.736 Characteristics of a synchronous digital multiplex equipment operating at 2048 kbit/s G.772 Protected Monitoring Points provided on Digital Transmission Systems G.775 Loss of signal (LOS) and alarm indication (AIS) defect detection and clearance criteria G.783 Characteristics of Synchronous Digital Hierarchy (SDH) Equipment Functional Blocks G.823 The control of jitter and wander within digital networks which are based on the 2048 kbit/s hierarchy O.151 Specification of instruments to measure error performance in digital systems OFTEL OTR-001 Short Circuit Current Requirements ETS 300166 Physical and Electrical Characteristics ETS 300386-1 Electromagnetic Compatibility Requirement Datasheet 77 LXT388 — Dual T1/E1/J1 Transceiver 6.0 Mechanical Specifications Figure 37. Low Quad Flat Package (LQFP) Dimensions 100 Pin LQFP • Part Number LXT388LE • Extended Temperature Range (-40°C to 85° C) ALL DIMENSIONS IN MILLIMETERS All dimensions and tolerances conform to ANSI Y14.5M-1982. 16.00 BSC 14.00 BSC 12.00 BSC 16.00 BSC 14.00 BSC 0.22 ±0.05 12.00 BSC Pin #1 Index 0.50 BSC 1 2 3 1.40 ±0.05 1.60 max See Detail "A" 0.05 min 0.15 max DETAIL "A" 0.60 ±0.15 0.20 min 1.00 REF 78 Datasheet