October 1994 DP83256/56-AP/57 PLAYER a TM Device (FDDI Physical Layer Controller) Y General Description The DP83256/56-AP/57 Enhanced Physical Layer Controller (PLAYER a device) implements one complete Physical Layer (PHY) entity as defined by the Fiber Distributed Data Interface (FDDI) ANSI X3T9.5 standard. The PLAYER a device integrates state of the art digital clock recovery and improved clock generation functions to enhance performance, eliminate external components and remove critical layout requirements. FDDI Station Management (SMT) is aided by Link Error Monitoring support, Noise Event Timer (TNE) support, Optional Auto Scrubbing support, an integrated configuration switch and built-in functionality designed to remove all stringent response time requirements such as PCÐReact and CFÐReact. Y Y Y Y Y Y Y Y Y Y Features Y Y Y Y Single chip FDDI Physical Layer (PHY) solution Integrated Digital Clock Recovery Module provides enhanced tracking and greater lock acquisition range Integrated Clock Generation Module provides all necessary clock signals for an FDDI system from an external 12.5 MHz reference Y Y Y Y Y Alternate PMD Interface (DP83256-AP/57) supports UTP twisted pair FDDI PMDs with no external clock recovery or clock generation functions required No External Filter Components Connection Management (CMT) Support (LEM, TNE, PCÐReact, CFÐReact, Auto Scrubbing) Full on-chip configuration switch Low Power CMOS-BIPOLAR design using a single 5V supply Full duplex operation with through parity Separate management interface (Control Bus) Selectable Parity on PHY-MAC Interface and Control Bus Interface Two levels of on-chip loopback 4B/5B encoder/decoder Framing logic Elasticity Buffer, Repeat Filter, and Smoother Line state detector/generator Supports single attach stations, dual attach stations and concentrators with no external logic DP83256 for SAS/DAS single path stations DP83257 for SAS/DAS single/dual path stations DP83256-AP for SAS/DAS single path stations that require the alternate PMD interface TL/F/11708 – 1 FIGURE 1-1. FDDI Chip Set Overview TRI-STATEÉ is a registered trademark of National Semiconductor Corporation. BMACTM , BSITM , CDDTM , CDLTM , CRDTM , CYCLONETM , MACSITM , PLAYERTM , PLAYER a TM and TWISTERTM are trademarks of National Semiconductor Corporation. C1995 National Semiconductor Corporation TL/F/11708 RRD-B30M115/Printed in U. S. A. DP83256/56-AP/57 PLAYER a Device (FDDI Physical Layer Controller) PRELIMINARY Table of Contents 5.21 Current State Prescale Count Register (CSPCR) 1.0 FDDI CHIP SET OVERVIEW 1.1 FDDI 2-Chip Set 5.22 Link Error Threshold Register (LETR) 1.2 FDDI TP-PMD Solutions 5.23 Current Link Error Count Register (CLECR) 5.24 User Definable Register (UDR) 5.25 Device ID Register (DIR) 5.26 Current Injection Count Register (CIJCR) 5.27 Interrupt Condition Comparison Register (ICCR) 5.28 Current Transmit State Comparison Register (CTSCR) 5.29 Receive Condition Comparison Register A (RCCRA) 5.30 Receive Condition Comparision Register B (RCCRB) 5.31 Mode Register 2 (MODE2) 5.32 CMT Condition Comparison Register (CMTCCR) 5.33 CMT Condition Register (CMTCR) 5.34 CMT Condition Mask Register (CMTCMR) 5.35 Reserved Registers 22H-23H (RR22H-RR23H) 5.36 Scrub Timer Threshold Register (STTR) 5.37 Scrub Timer Value Register (STVR) 2.0 ARCHITECTURE DESCRIPTION 2.1 Block Overview 2.2 Interfaces 3.0 FUNCTIONAL DESCRIPTION 3.1 Clock Recovery Module 3.2 Receiver Block 3.3 Transmitter Block 3.4 Configuration Switch 3.5 Clock Generation Module 3.6 Station Management Support 3.7 PHY-MAC Interface 3.8 PMD Interface 4.0 MODES OF OPERATION 5.38 Trigger Definition Register (TDR) 5.39 Trigger Transition Configuration Register (TTCR) 5.40 Reserved Registers 28H-3AH (RR28H-RR3AH) 5.41 Clock Generation Module Register (CGMREG) 5.42 Alternate PMD Register (APMDREG) 5.43 Gain Register (GAINREG) 5.44 Reserved Registers 3EH-3FH (RR3EH-RR3FH) 4.1 Run Mode 4.2 Stop Mode 4.3 Loopback Mode 4.4 Device Reset 4.5 Cascade Mode 5.0 REGISTERS 5.1 Mode Register (MR) 5.2 Configuration Register (CR) 5.3 Interrupt Condition Register (ICR) 5.4 Interrupt Condition Mask Register (ICMR) 5.5 Current Transmit State Register (CTSR) 5.6 Injection Threshold Register (IJTR) 5.7 Injection Symbol Register A (ISRA) 5.8 Injection Symbol Register B (ISRB) 5.9 Current Receive State Register (CRSR) 5.10 Receive Condition Register A (RCRA) 5.11 Receive Condition Register B (RCRB) 5.12 Receive Condition Mask Register A (RCMRA) 5.13 Receive Condition Mask Register B (RCMRB) 5.14 Noise Threshold Register (NTR) 5.15 Noise Prescale Threshold Register (NPTR) 5.16 Current Noise Count Register (CNCR) 5.17 Current Noise Prescale Count Register (CNPCR) 5.18 State Threshold Register (STR) 5.19 State Prescale Threshold Register (SPTR) 5.20 Current State Count Register (CSCR) 6.0 SIGNAL DESCRIPTIONS 6.1 DP83256VF Signal Descriptions 6.2 DP83256VF-AP Signal Descriptions 6.3 DP83257VF Signal Descriptions 7.0 ELECTRICAL CHARACTERISTICS 7.1 Absolute Maximum Ratings 7.2 Recommended Operating Conditions 7.3 DC Electrical Characteristics 7.4 AC Electrical Characteristics 8.0 CONNECTION DIAGRAMS 8.1 DP83256VF Connection Diagram/Pin Descriptions 8.2 DP83256VF-AP Connection Diagram/Pin Descriptions 8.3 DP83257VF Connection Diagram/Pin Descriptions 9.0 PACKAGE INFORMATION 9.1 Land Patterns 9.2 Mechanical Drawings 2 1.0 FDDI Chip Set Overview DP83266 MACSI TM Device Media Access Controller and System Interface National Semiconductor’s next generation FDDI 2-chip set consists of two components as shown in Figure 1-1 . The PLAYER a device integrates the features of the DP83231 CRDTM Clock Recovery Device, DP83241 CDDTM Clock Distribution Device, and DP83251/55 PLAYERTM Physical Layer Controller. In addition, the PLAYER a device contains enhanced SMT support. National Semiconductor’s FDDI TP-PMD Solutions consist of two componentsÐthe DP83222 CYCLONETM Twisted Pair FDDI Stream Cipher Device and the DP83223A TWISTERTM Twisted Pair FDDI Transceiver Device. For more information on the other devices of the chip set, consult the appropriate datasheets and application notes. The DP83266 Media Access Controller and System Interface (MACSI) implements the ANSI X3T9.5 Standard Media Access Control (MAC) protocol for operation in an FDDI token ring and provides a comprehensive System Interface. The MACSI device transmits, receives, repeats, and strips tokens and frames. It produces and consumes optimized data structures for efficient data transfer. Full duplex architecture with through parity allows diagnostic transmission and self testing for error isolation in point-to-point connections. The MACSI device includes the functionality of both the DP83261 BMAC device and the DP83265 BSI-2 device with additional enhancements for higher performance and reliability. 1.1 FDDI 2-CHIP SET DP83256/56-AP/57 PLAYER a Device Physical Layer Controller Features The PLAYER a device implements the Physical Layer (PHY) protocol as defined by the ANSI FDDI PHY X3T9.5 standard. Y Y Y Features Y Single chip FDDI Physical Layer (PHY) solution Y Integrated Digital Clock Recovery Module provides enhanced tracking and greater lock acquisition range Y Integrated Clock Generation Module provides all necessary clock signals for an FDDI system from an external 12.5 MHz reference Y Alternate PMD Interface (DP83256-AP/57) supports UTP twisted pair FDDI PMDs with no external clock recovery or clock generation functions required Y No External Filter Components Y Connection Management (CMT) Support (LEM, TNE, PCÐReact, CFÐReact, Auto Scrubbing) Y Full on-chip configuration switch Y Low Power CMOS-BIPOLAR design using a single 5V supply Y Full duplex operation with through parity Y Separate management interface (Control Bus) Y Selectable Parity on PHY-MAC Interface and Control Bus Interface Y Two levels of on-chip loopback Y 4B/5B encoder/decoder Y Framing logic Y Elasticity Buffer, Repeat Filter, and Smoother Y Line state detector/generator Y Supports single attach stations, dual attach stations and concentrators with no external logic Y DP83256/56-AP for SAS/DAS single path stations Y P83257 for SAS/DAS single/dual path stations In addition, the DP83257 contains the additional PHYÐData.request and PHYÐData.indicate ports required for concentrators and dual attach, dual path stations. Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y 3 Over 9 Kbytes of on-chip FIFO 5 DMA Channels (2 Output and 3 Input) 12.5 MHz to 33 MHz operation Full duplex operation with through parity Real-time VOID frame stripping indicator for bridges On-chip Address bit swapping capability 32-bit wide Address/Data path with byte parity Programmable transfer burst sizes of 4 or 8 32-bit words Receive frame filtering services Frame-per-Page mode controllable on each DMA channel Demultiplexed Addresses supported on ABus New multicast address matching ANSI X3T9.5 MAC standard defined ring service options Supports all FDDI Ring Scheduling Classes (Synchronous, Asynchronous, etc.) Supports Individual, Group, Short, Long, and External Addressing. Generates Beacon, Claim, and Void frames Extensive ring and station statistics gathering Extension for MAC level bridging Enhanced SBus compatibility Interfaces to DRAMs or directly to system bus Supports frame Header/Info splitting Programmable Big or Little Endian alignment DP83222 CYCLONE Twisted Pair FDDI Stream Cipher Device DP83223A TWISTER High Speed Networking Transceiver Device General Description General Description The DP83222 CYCLONE Stream Cipher Scrambler/Descrambler Device is an integrated circuit designed to interface directly with the serial bit streams of a Twisted Pair FDDI PMD. The DP83222 is designed to be fully compatible with the National Semiconductor FDDI Chip Sets, including twisted pair FDDI Transceivers, such as the DP83223A Twisted Pair Transceiver (TWISTER). The DP83222 requires a 125 MHz Transmit Clock and corresponding Receive Clock for synchronous data scrambling and descrambling. The DP83222 is compliant with the ANSI X3T9.5 TP-PMD standard and is required for the reduction of EMI emission over unshielded media. The DP83222 is specified to work in conjunction with existing twisted pair transceiver signalling schemes and enables high bandwidth transmission over Twisted Pair copper media. The DP83223A Twisted Pair Transceiver is an integrated circuit capable of driving and receiving either binary or (MLT-3) encoded datastreams. The DP83223A Transceiver is designed to interface directly with standards compliant FDDI, 100BASE-TX or STS-3c ATM chip sets, allowing low cost data links over copper based media. The DP83223A allows links of up to 100 meters over both Shielded Twisted Pair (STP) and datagrade Unshielded Twisted Pair (UTP) or equivalent. The electrical performance of the DP83223A meets or exceeds all performance parameters specified in the ANSI X3T9.5 TP-PMD standard, the IEEE 802.3 100BASE-TX Fast Ethernet Specification and the ATM Forum 155 Mbps Twisted Pair PMD Interface Specification. The DP83223A also provides important features such as baseline restoration, TRI-STATEÉ capable transmit outputs, and controlled transmit output edge rates (to reduce EMI radiation) for both binary and MLT-3 modes of operation. Features Y Y Y Y Y Y Y Y Y Enables 100 Mbps FDDI signalling over Category 5 Unshielded Twisted Pair (UTP) cable and Type 1 Shielded Twisted Pair (STP) Reduces EMI emissions over Twisted Pair media Compatible with ANSI X3T9.5 TP-PMD standard Requires a single a 5V supply Transparent mode of operation Flexible NRZ and NRZI format options Advanced BiCMOS process Signal Detect and Clock Detect inputs provided for enhanced functionality Suitable for Fiber Optic PMD replacement applications Features Y Y Y Y Y Y Y Y Y Y Y 4 Compliant with ANSI X3T9.5 TP-PMD standard Compliant with IEEE 802.3 100BASE-TX Ethernet draft standard Compliant with ATM Forum 155 Mbps Twisted Pair Specification Integrated baseline restoration circuit Integrated transmitter and receiver with adaptive equalization circuit Programmable binary or MLT-3 operation Isolated TX and RX power supplies for minimum noise coupling Controlled transmit output edge rates for reduced EMI TRI-STATE capable current transmit outputs Loopback feature for board diagnostics Programmable transmit voltage amplitude 2.0 Architecture Description The Receiver Block performs the following operations: 2.1 BLOCK OVERVIEW The PLAYER a device is comprised of six blocks: Clock # Optionally converts the incoming data stream from NRZI Recovery, Receiver, Configuration Switch, Transmitter, Station Management (SMT) Support, and Clock Generation Module as shown in Figure 2-1 . # Decodes the data from 5B to 4B coding. # Converts the serial bit stream into 10-bit bytes composed to NRZ. of 8 bits data, 1 bit parity, and 1 bit control information. Clock Recovery The Clock Recovery Module accepts a 125 Mbps NRZI data stream from the external PMD receiver. It then provides the extracted and synchronized data and clock to the Receiver block. The Clock Recovery Module performs the following operations: # Compensates for the differences between the upstream station clock and the local clocks. # Decodes Line States. # Detects link errors. # Presents data symbol pairs (bytes) to the Configuration Switch Block. # Locks to and tracks the incoming NRZI data stream # Extracts data stream and synchronized 125 MHz clock Configuration Switch An FDDI station may be in one of three configurations: Isolate, Wrap or Thru. The Configuration Switch supports these configurations by switching the transmitted and received data paths between PLAYER a devices and one or more MACSI devices. The configuration switch is integrated into the PLAYER a device, therefore no external logic is required for this function. Setting the Configuration switch can be done explicitly via the Control Bus Interface or it can be set automatically with the CFÐReact SMT Support feature. Receiver During normal operation, the Receiver Block accepts serial data as inputs at the rate of 125 Mbps from the Clock Recovery Module. During the Internal Loopback mode of operation, the Receiver Block accepts data directly from the Transmitter Block. TL/F/11708 – 2 FIGURE 2-1. PLAYER a Device Block Diagram 5 2.0 Architecture Description (Continued) Transmitter PMD Interface The Transmitter Block accepts 10-bit bytes composed of 8 bits data, 1 bit parity, and 1 bit control information from the Configuration Switch. The Transmitter Block performs the following operations: The PMD Interface connects the PLAYER a device to a standard FDDI Physical Media Connection such as a fiber optic transceiver or a copper twisted pair transceiver. It is a 125 MHz full duplex serial connection. The DP83256-AP and DP83257 PLAYER a devices contain two PMD interfaces. The Primary PMD Interface should be used for all PMD implementations that do not require an external scrambler/descrambler function, clock recovery function, or clock generation function, such as a Fiber Optic or Shielded Twisted Pair (SDDI) PMD. The second, Alternate PMD Interface can be used to support Unshielded Twisted Pair (UTP) PMDs that require external scrambling, and allows implementation with no external clock recovery or clock generation functions required. # Encodes the data from 4B to 5B coding. # Filters out code violations from the data stream. # Generates Idle, Master, Halt, Quiet, or other user defined symbol pairs upon request. # Converts the data stream from NRZ to NRZI format for transmission. # Provides smoothing function when necessary. During normal operation, the Transmitter Block presents serial data to the PMD transmitter. While in Internal Loopback mode, the Transmitter Block presents serial data to the Receiver Block. While in the External Loopback mode, the Transmitter Block presents serial data to the Clock Recovery Module. PHY Port Interface The PHY Port Interface connects the PLAYER a device to one or more MAC devices and/or PLAYER a devices. Each PHY Port Interface consists of two byte-wide interfaces, one for PHY Request data input to the PLAYER a device and one for the PHY Indicate data output of the PLAYER a device. Each byte-wide interface consists of a parity bit (odd parity), a control bit, and two 4-bit symbols. The DP83257 PLAYER a device has two PHY Port Interfaces while the DP83256 has one PHY Port Interface. Clock Generation Module The Clock Generation Module is an integrated phase locked loop that generates all of the required clock signals for the PLAYER a device and an FDDI system from a single 12.5 MHz reference. The Clock Generation Module features: Control Bus Interface The Control Bus Interface connects the PLAYER a device to a wide variety of microprocessors and microcontrollers. The Control Bus is an asynchronous interface which provides access to 64 8-bit registers which monitor and control the behavior of the PLAYER a device. The Control Bus Interface allows a user to: # Configure SMT features. # Program the Configuration Switch. # Enable/disable functions within the Transmitter and Receiver Blocks (i.e., NRZ/NRZI Encoder, Smoother, PHY Request Data Parity, Line State Generation, Symbol pair Injection, NRZ/NRZI Decoder, Cascade Mode, etc.). The Control Bus Interface also can be used to perform the following functions: # Monitor Line States received. # Monitor link errors detected by the Receiver Block. # Monitor other error conditions. # High precision clock timing generated from a single 12.5 MHz reference. # Multiple precision phased (8 ns/16 ns) 12.5 MHz Local Byte Clocks to eliminate timing skew in large multi-board concentrator configurations. # LBC timing which is insensitive to loading variations over a wide range (20 pF to 70 pF) of LBC loads. # A selectable dual frequency system clock. # Low clock edge jitter, due to high VCO stability. Station Management (SMT) Support The Station Management Support Block provides a number of useful features to simplify the implementation of the Connection Management (CMT) portion of SMT. These features eliminate the time critical CMT response time constraints imposed by PCÐReact and CFÐReact times. Integrated counters and timers eliminate the need for additional external devices. The following are the CMT features supported: # # # # # # Clock Interface The Clock Interface is used to configure the Clock Generation Module and to provide the required clock signals for an FDDI system. The following clock signals are generated: # 5 phase offset 12.5 MHz Local Byte Clocks # 25 MHz Local Symbol Clock # 15.625 or 31.25 MHz System Clock PCÐReact CFÐReact Auto Scrubbing (TCF Timer) Timer, Idle Detection (TID Timer) Noise Event Counter (TNE Timer) Link Error Monitor (LEM Counter) Miscellaneous Interface The Miscellaneous Interface consists of: # A reset signal. # User definable sense signals. # User definable enable signals. # Synchronization for cascading PLAYER a devices (a high-performance non-FDDI mode). # Device Power and Ground pins. 2.2 INTERFACES The PLAYER a device connects to other devices via five functional interfaces: PMD Interface, PHY Port Interface, Control Bus Interface, Clock Interface, and the Miscellaneous Interface. 6 3.0 Functional Description The PLAYER a device is comprised of six blocks: Clock Recovery, Receiver, Transmitter, Configuration Switch, Clock Generation, and Station Management Support. DIGITAL PHASE DETECTOR The Digital Phase Detector has two main functions: phase error detection and data recovery. Phase error detection is accomplished by a digital circuit that compares the input data (PMID) to an internal phaselocked 125 MHz reference clock and generates a pair of error signals. The first signal is a pulse whose width is equal to the phase error between the input data and a reference clock and the second signal is a 4 ns reference pulse. These signals are fed into the Digital Phase Error Processor block. The data recovery function converts the incoming encoded data stream (PMID) into synchronized data and clock signals. When the circuit is in lock the rising edge of the recovered clock is exactly centered in the recovered data bit cell. The digital phase detector uses a common path for phase error detection and data recovery so as to minimize clock Static Alignment Error (SAE). Phase error averaging is also included so that phase errors generated by positive and negative PMID edges equally affect the clock recovery circuit. This greatly improves the immunity to Duty Cycle Distortion (DCD) in the data recovery circuit. 3.1 CLOCK RECOVERY MODULE The Clock Recovery Module accepts a 125 Mbps NRZI data stream from the external PMD receiver. It then provides the extracted and synchronized data and clock to the Receiver block. The Clock Recovery Module performs the following operations: # Locks onto and tracks the incoming NRZI data stream # Extracts the data stream and the synchronized 125 MHz clock The Clock Recovery Module is implemented using an advanced digital architecture that replaces sensitive analog blocks with digital circuitry. This allows the PLAYER a device to be manufactured to tighter tolerances since it is less sensitive to processing variations that can adversely affect analog circuits. The Clock Recovery Module is comprised of 5 main functional blocks: Digital Phase Detector Digital Phase Error Processor Digital Loop Filter Digital Phase to Frequency Converter Frequency Controlled Oscillator See Figure 3-1 , Clock Recovery Module Block Diagram. DIGITAL PHASE ERROR PROCESSOR The Digital Phase Error Processor is responsible for sampling the Phase Detector’s phase error outputs and producing two digital outputs that indicate to the digital loop filter how to adjust for a difference between the data phase and reference phases. The Phase Error Processor is designed to eliminate the effects of different clock edge densities between data symbols and the various line state symbols on the PLL’s loop gain. TL/F/11708 – 3 FIGURE 3-1. Clock Recovery Module Block Diagram 7 3.0 Functional Description (Continued) Each valid Up or Down signal causes a partial 7-bit counter (using only 96 counts) to increment or decrement at the O – F converter’s clock rate of 15.625 MHz (250 MHz/16). When the Data Valid signal is not asserted, the counter holds count. The counter value is used to produce 3 triangle waves that are offset in phase by 120 degrees. This is done with a special Pulse Density Modulator waveform synthesizer which takes the place of a traditional Digital-Analog converter. The frequency of the triangle waves tells the Frequency Controlled Oscillator how much to adjust oscillation. The phase relationships (leading or lagging) between the 3 signals indicates the direction of change. The minimum frequency of the triangle waves is 0 and corresponds to the case when the PLL is in perfect lock with the incoming signal. The maximum frequency that the O – F converter can produce determines the locking range of the PLL. In this case the maximum frequency of each triangle wave is 162.76 kHz, which is produced when the O – F converter gets a continuous count in one direction that is valid every O –F converter clock cycle of 15.625 MHz (250 MHz/16). The triangle waves have an amplitude resolution of 48 digital steps, so a full rising and falling period takes 96 counts which produces a maximum frequency of 162.76 kHz (1/(1/15.625 kHz * 96)). The 96 digital counts of the triangle waves also lead to a very fine PLL phase resolution of 42 ps (4 ns/96 counts). This high phase resolution is achieved using very low frequency signals, in contrast to a standard PLL which must operate at significantly higher frequencies than the data being tracked to achieve such high phase resolution. Since the loop gain is held constant regardless of the incoming signal edge density, PLL characteristics such as jitter, acquisition rate, locking range etc., are deterministic and show minimal spread under various operating environments. The phase error processor also automatically puts the loop in open-loop-mode when the incoming data stream contains abnormal low edge rates. When the PLL is in open-loopmode, no update is made to the PLL’s filter variables in the filter block. The PLL can then use the pretrained frequency and phase contents to perform data recovery. Since the loop is implemented digitally, these values (the frequency and phase variables) are retained. The resolution of the frequency variable is about 1.3 ppm of the incoming frequency. The resolution of the phase variable is about 40 ps. DIGITAL LOOP FILTER The digital loop filter emulates a 1-pole, 1-zero filter and uses an automatic acquisition speed control circuit to dynamically adjust loop parameters. The digital loop filter takes the phase error indicator signals Data Valid and Up/Down from the Phase Error processor and accumulates errors over a few cycles before passing on the Data Valid and Up/Down signals to the Phase Error to Frequency converter. The filter has 4 sets of bandwidth and damping parameters which are switched dynamically by an acquisition control circuit. The input Signal Detect (SD) starts the sequence and, thereafter, no user programming is required to finish the sequence. At the completion of the locking sequence, the loop has the narrowest bandwidth such that the loop produces minimal recovered clock jitter. The PLL can track an incoming frequency offset of approximately g 200 ppm. After the acquisition sequence, the equivalent natural frequency of the loop is reduced to about 7 kHz ( g 56 ppm) of frequency offset. The automatic tracking mechanism allows the loop to quickly lock onto the initial data stream for data recovery (typically less than 10 ms) and yet produce very little recovered clock jitter. FREQUENCY CONTROLLED OSCILLATOR (FCO) The frequency controlled oscillator produces a 250 MHz clock that, when divided by 2, is phase locked to the incoming data’s clock. The FCO uses three 250 MHz reference clock signals from the Clock Generation Module and three 0 Hz to 162.76 kHz error clock signals from the Phase Error to Frequency Converter as inputs. Each signal in a triplet is 120 degrees phase shifted from the next. Each corresponding pair (one 250 MHz and one error signal) of signals is mixed together using an amplitude switching modulator, with the error signal modulating the reference. All of the outputs are then summed together to produce the final 250 MHz a fm phase locked clock signal, where fm is the error frequency. PHASE ERROR TO FREQUENCY CONVERTER (O – F) The Phase Error to Frequency Converter takes the Data Valid and Up/Down signals modified by the Digital Loop Filter and converts them to triangle waves. The frequency of the triangle waves is then used to control the Frequency Controlled Oscillator’s (FCO) 250 MHz oscillations. 8 3.0 Functional Description (Continued) 3.2 RECEIVER BLOCK During normal operation, the Receiver Block accepts serial data input at the rate of 125 Mbps from the Clock Recovery Module. During the Internal Loopback mode of operation, the Receiver Block accepts input data from the Transmitter Block. The Receiver Block performs the following operations: NRZI TO NRZ DECODER The NRZI to NRZ Decoder converts Non-Return-To-ZeroInvert-On-Ones data to Non-Return-To-Zero format. NRZ format data is the natural data format that the receiver block utilizes internally, so this function is required when the standard NRZI format data is fed into the device. The receiver block can bypass this conversion function in the case where an alternate data source outputs NRZ format data. This function can be enabled and disabled through bit 7 (RNRZ) of the Mode Register (MR). When the bit is cleared, it converts the incoming bit stream from NRZI to NRZ. This is the normal configuration required. When the bit is set, the incoming NRZ bit stream is passed unchanged. # Optionally converts the incoming data stream from NRZI to NRZ. # Decodes the data from 5B to 4B coding. # Converts the serial bit stream into the National byte-wide code. # Compensates for the differences between the upstream SHIFT REGISTER The Shift Register converts the serial bit stream into symbol-wide data for the 5B/4B Decoder. The Shift Register also provides byte-wide data for the Framing Logic. station clock and the local clock. # Decodes Line States. # Detects link errors. # Presents data symbol pairs to the Configuration Switch Block. The Receiver Block consists of the following functional blocks: NRZI to NRZ Decoder Shift Register Framing Logic Symbol Decoder Line State Detector Elasticity Buffer Link Error Detector See Figure 3-2. FRAMING LOGIC The Framing Logic performs the Framing function by detecting the beginning of a frame or the Halt-Halt or Halt-Quiet symbol pair. The J-K symbol pair (11000 10001) indicates the beginning of a frame during normal operation. The Halt-Halt (00100 00100) and Halt-Quiet (00100 00000) symbol pairs are detected for Connection Management (CMT). TL/F/11708 – 4 FIGURE 3-2. Receiver Block Diagram 9 3.0 Functional Description (Continued) TABLE 3-1. 5B/4B Symbol Decoding Framing may be temporarily suspended (i.e. framing hold), in order to maintain data integrity. Symbol Detecting JK The JK symbol pair can be used to detect the beginning of a frame during Active Line State (ALS) and Idle Line State (ILS) conditions. While the Line State Detector indicates Idle Line State the receiver ‘‘reframes’’ upon detecting a JK symbol pair and enters the Active Line State. During Active Line State, acceptance of a JK symbol (reframing) is allowed for any on-boundary JK which is detected at least 1.5 byte times after the previous JK. During Active Line State, once reframed on a JK, a subsequent off-boundary JK is ignored, even if it is detected beyond 1.5 byte times after the previous JK. During Active Line State, an Idle or Ending Delimiter (T) symbol will allow reframing on any subsequent JK, if a JK is detected at least 1.5 byte times after the previous JK. 0 1 2 3 4 5 6 7 8 9 A B C D E F Detecting HALT-HALT AND HALT-QUIET During Idle Line State, the detection of a Halt-Halt, or HaltQuiet symbol pair will still allow the reframing of any subsequent on-boundary JK. Once a JK is detected during Active Line State, off-boundary Halt-Halt, or Halt-Quiet symbol pairs are ignored until the Elasticity Buffer (EB) has an opportunity to recenter. They are treated as violations. After recentering on a Halt-Halt, or Halt-Quiet symbol pair, all off boundary Halt-Halt or Halt-Quiet symbol pairs are ignored until the EB has a chance to recenter during a line state other than Active Line State (which may be as long as 2.8 byte times). I (Idle) H (Halt) JK (Starting Delimiter) T (Ending Delimiter) R (Reset) S (Set) Q (Quiet) V (Violation) V V V V V V V SYMBOL DECODER The Symbol Decoder is a two level system. The first level is a 5-bit to 4-bit converter, and the second level is a 4-bit symbol pair to byte-wide code converter. The first level latches the received 5-bit symbols and decodes them into 4-bit symbols. Symbols are decoded into two types: data and control. The 4-bit symbols are sent to the Line State Detector and the second level of the Symbol Decoder. See Table 3-1 for the 5B/4B Symbol Decoding list. The second level translates two symbols from the 5B/4B converter and the line state information from the Line State Detector into the National byte-wide code. Incoming 5B Decoded 4B 11110 01001 10100 10101 01010 01011 01110 01111 10010 10011 10110 10111 11010 11011 11100 11101 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 11111 00100 11000 and 10001 01101 1010 0001 1101 00111 11001 00000 00001 00010 00011 00101 00110 01000 01100 10000 0110 0111 0010 0010 0010 0010 0010 0010 0010 0010 0010 0101 Note: VÊ denotes PHY Invalid or an Elasticity Buffer stuff byte IÊ denotes Idle symbol in ILS or an Elasticity Buffer stuff byte LINE STATES DESCRIPTION Active Line State The Line State Detector recognizes the incoming data to be in the Active Line State upon the reception of the Starting Delimiter (JK symbol pair). The Line State Detector continues to indicate Active Line State while receiving data symbols, Ending Delimiter (T symbols), and Frame Status symbols (R and S) after the JK symbol pair. Idle Line State The Line State Detector recognizes the incoming data to be in the Idle Line State upon the reception of 2 Idle symbol pairs nominally (plus up to 9 bits of 1 in start up cases). Idle Line State indicates the preamble of a frame or the lack of frame transmission during normal operation. Idle Line State is also used in the handshake sequence of the PHY Connection Management process. LINE STATE DETECTOR The ANSI X3T9.5 FDDI Physical Layer (PHY) standard specifies eight Line States that the Physical Layer can transmit. These Line States are used in the Connection Management process. They are also used to indicate data within a frame during normal operation. The Line States are reported through the Current Receive State Register (CRSR), Receive Condition Register A (RCRA), and Receive Condition Register B (RCRB). 10 3.0 Functional Description (Continued) The Elasticity Buffer will support a maximum clock skew of 50 ppm with a maximum packet length of 4500 bytes. Super Idle Line State The Line State Detector recognizes the incoming data to be in the Super Idle Line State upon the reception of 8 consecutive Idle symbol pairs nominally (plus 1 symbol pair). The Super Idle Line State is used to insure synchronization of PCM signalling. No Signal Detect The Line State Detector recognizes the incoming data to be in the No Signal Detect state upon the deassertion of the Signal Detect signal or lack of internal clock detect from the Clock Recovery Module, and reception of 8 Quiet symbol pairs nominally. No Signal Detect indicates that the incoming link is inactive. This is the same as receiving Quiet Line State (QLS). Master Line State The Line State Detector recognizes the incoming data to be in the Master Line State upon the reception of eight consecutive Halt-Quiet symbol pairs nominally (plus up to 2 symbol pairs in start up cases). The Master Line State is used in the handshaking sequence of the PHY Connection Management process. Halt Line State The Line State Detector recognizes the incoming data to be in the Halt Line State upon the reception of eight consecutive Halt symbol pairs nominally (plus up to 2 symbol pairs in start up cases). The Halt Line State is used in the handshaking sequence of the PHY Connection Management process. Quiet Line State The Line State Detector recognizes the incoming data to be in the Quiet Line State upon the reception of eight consecutive Quiet symbol pairs nominally (plus up to 9 bits of 0 in start up cases). The Quiet Line State is used in the handshaking sequence of the PHY Connection Management process. Noise Line State The Line State Detector recognizes the incoming data to be in the Noise Line State upon the reception of 16 noise symbol pairs without entering any known line state. The Noise Line State indicates that data is not being received correctly. Line State Unknown The Line State Detector recognizes the incoming data to be in the Line State Unknown state upon the reception of 1 inconsistent symbol pair (i.e. data that is not expected). This may signify the beginning of a new line state. Line State Unknown indicates that data is not being received correctly. If the condition persists the Noise Line State (NLS) may be entered. To make up for the accumulation of frequency disparity between the two clocks, the Elasticity Buffer will insert or delete Idle symbol pairs in the preamble. Data is written into the byte-wide registers of the Elasticity Buffer with the Receive Clock, while data is read from the registers with the Local Byte Clock. The Elasticity Buffer will recenter (i.e. set the read and write pointers to a predetermined distance from each other) upon the detection of a JK or every four byte times during PHY Invalid (i.e. MLS, HLS, QLS, NLS, NSD) and Idle Line State. The Elasticity Buffer is designed such that a given register cannot be written and read simultaneously under normal operating conditions. To avoid metastability problems, the EB overflow event is flagged and the data is tagged before the over/under run actually occurs. LINK ERROR DETECTOR The Link Error Detector provides continuous monitoring of an active link (i.e. during Active and Idle Line States) to insure that it does not exceed the maximum Bit Error Rate requirement as set by the ANSI standard for a station to remain on the ring. Upon detecting a link error, the internal 8-bit Link Error Monitor Counter is decremented. The start value for the Link Error Monitor Counter is programmed through the Link Error Threshold Register (LETR). When the Link Error Monitor Counter reaches zero, bit 4 (LEMT) of the Interrupt Condition Register (ICR) is set to 1. The current value of the Link Error Monitor Counter can be read through the Current Link Error Count Register (CLECR). For higher error rates the current value is an approximate count because the counter rolls over. There are two ways to monitor Link Error Rate: polling and interrupt. Polling The Link Error Monitor Counter can be set to a large value, like FF. This will allow for the greatest time between polling the register. This start value is programmed through the Link Error Threshold Register (LETR). Upon detecting a link error, the Line Error Monitor Counter is decremented. The Host System reads the current value of the Link Error Monitor Counter via the Current Link Error Count Register (CLECR). The Counter is then reset to FF. Interrupt The Link Error Monitor Counter can be set to a small value, like 5 to 10. This start value is programmed through the Link Error Threshold Register (LETR). Upon detecting a link error, the Line Error Monitor Counter is decremented. When the counter reaches zero, bit 4 (LEMT) of the Interrupt Condition Register (ICR) is set to 1, and the interrupt signal goes low, interrupting the Host System. Miscellaneous Items When bit 0 (RUN) of the Mode Register (MR) is set to zero, or when the PLAYER a device is reset through the Reset pin ( E RST), the internal signal detect line is internally forced to zero and the Line State Detector is set to Line State Unknown and No Signal Detect. ELASTICITY BUFFER The Elasticity Buffer performs the function of a ‘‘variable depth’’ FIFO to compensate for phase and frequency clock skews between the Receive Clock (RXC g ) and the Local Byte Clock (LBC). Bit 5 (EBOU) of the Receive Condition Register B (RCRB) is set to 1 to indicate an error condition when the Elasticity Buffer cannot compensate for the clock skew. 11 3.0 Functional Description (Continued) While in Internal Loopback mode, the Transmitter Block presents serial data to the Receiver Block. While in the External Loopback mode, the Transmitter Block presents serial data to the Clock Recovery Module. The Transmitter Block consists of the following functional blocks: Data Registers Parity Checker 4B/5B Encoder Repeat Filter Smoother Line State Generator Injection Control Logic Shift Register NRZ to NRZI Encoder See Figure 3-3 , Transmitter Block Diagram. 3.3 TRANSMITTER BLOCK The Transmitter Block accepts 10-bit bytes consisting of 8 bits data, 1 bit parity, and 1 bit control information, from the Configuration Switch. The Transmitter Block performs the following operations: # Encodes the data from 4B to 5B coding. # Filters out code violations from the data stream. # Is capable of generating Idle, Master, Halt, Quiet, or other user defined symbol pairs. # Converts the data stream from NRZ to NRZI for transmission. # Serializes data. During normal operation, the Transmitter Block presents serial data to a PMD transmitter. TL/F/11708 – 5 FIGURE 3-3. Transmitter Block Diagram 12 3.0 Functional Description (Continued) TABLE 3-2. 4B/5B Symbol Encoding DATA REGISTERS Data from the Configuration Switch is stored in the Data Registers. The 10-bit byte-wide data consists of a parity bit, a control bit, and two 4-bit data symbols as shown below. b9 b8 Parity Bit Control Bit b7 b0 Data Bits FIGURE 3-4. Byte-Wide Data The parity is odd parity. The control bit determines whether the Data bits represent Data or Control information. When the control bit is 0 the Data field is interpreted as data and when it is 1 the field is interpreted as control information according to the National Semiconductor control codes. PARITY CHECKER The Parity Checker verifies that the parity bit in the Data Register represents odd parity (i.e. odd number of 1s). The parity is enabled and disabled through bit 6 (PRDPE) of the Current Transmit State Register (CTSR). If a parity error occurs, the Parity Checker will set bit 0 (DPE) in the Interrupt Condition Register (ICR) and report the error to the Repeat Filter. 4B/5B ENCODER The 4B/5B Encoder converts the two 4-bit data symbols from the Configuration Switch into their respective 5-bit codes. See Table 3-2 for the Symbol Encoding list. Symbol 4B Code 5B Code 0 1 2 3 4 5 6 7 8 9 A B C D E F 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 11110 01001 10100 10101 01010 01011 01110 01111 10010 10011 10110 10111 11010 11011 11100 11101 N 0000 JK (Starting Delimiter) T (Ending Delimiter) R (Reset) 1101 11110 or 11111 11000 and 10001 01101 0100 or 0101 0110 00111 Note: The upper group of symbols are sent with the Control/Data pin set to Data, while the bottom grouping of symbols are sent with the Control/Data pin set to Control. REPEAT FILTER The Repeat Filter is used to prevent the propagation of code violations to the downstream station. Upon receiving violations in data frames, the Repeat Filter replaces them with two Halt symbol pairs followed by Idle symbols. Thus the code violations are isolated and recovered at each link and will not be propagated throughout the entire ring. 13 3.0 Functional Description (Continued) TL/F/11708 – 6 FIGURE 3-5. Repeat Filter State Diagram Note: Inputs to the Repeat Filter state machine are shown above the transition lines, while outputs from the state machine are shown below the transition lines. Note: Abbreviations used in the Repeat Filter State Diagram are shown in Table 3-3. 14 3.0 Functional Description (Continued) 1. In Repeat State, violations cause transitions to Halt State and two Halt symbol pairs are transmitted (unless JK or Ix occurs) followed by transition to Idle State. TABLE 3-3. Abbreviations used in the Repeat Filter State Diagram 2. When Ix is encountered, the Repeat Filter goes to the Idle State, during which Idle symbol pairs are transmitted until a JK is encountered. 3. The Repeat Filter goes to the Repeat State following a JK from any state. The END State, which is not part of the FDDI PHY standard, allows an R or S prior to a T within a frame to be recognized as a violation. It also allows NT to end a frame as opposed to being treated as a violation. FÐIDLE: Force IdleÐtrue when not in Active Transmit Mode. W: Represents the symbols R, or S, or T E TPARITY: Parity error nn : Data symbols (for C e 0 in the PHY-MAC interface) N: X: VÊ : IÊ : Data portion of a control and data symbol mixture Any symbol (i.e. don’t care) SMOOTHER The Smoother is used to keep the preamble length of a frame to a minimum of 6 Idle symbol pairs. Idle symbols in the preamble of a frame may have been added or deleted by each station to compensate for the difference between the Receive Clock and its Local Clock. The preamble needs to be maintained at a minimum length to allow stations enough time to complete processing of one frame and prepare to receive another. Without the Smoother function, the minimum preamble length (6 Idle symbol pairs) cannot be maintained as several stations may consecutively delete Idle symbols. The Smoother attempts to keep the number of Idle symbol pairs in the preamble at 7 by: Violation symbols or symbols inserted by the Receiver Block Idle symbols or symbols inserted by the Receiver Block ALSZILSZ: Active Line State or Idle Line State (i.e. PHY Invalid) E ALSZILSZ: Not in Active Line State nor in Idle Line State (i.e. PHY Valid) H: Halt Symbol R: Reset Symbol S: Set Symbol T: Frame ending delimiter JK: I: V: # Deleting an Idle symbol pair in preambles which have Frame start delimiter Idle symbol (Preamble) Code violations more than 7 Idle symbol pairs and/or # Inserting an idle symbol pair in preambles which have The Repeat Filter complies with the FDDI standard by observing the following (see Figure 3-5 ): less than 7 idle symbol pairs (i.e. Extend State). The Smoother Counter starts counting upon detecting an Idle symbol pair. It stops counting upon detecting a JK symbol pair. Figure 3-6 describes the Smoother state diagram. 15 3.0 Functional Description (Continued) TABLE 3-4. Transmit Modes LINE STATE GENERATOR The Line State Generator allows the transmission of the PHY Request data and can also generate and transmit Idle, Master, Halt, or Quiet symbol pairs which can be used to implement the Connection Management procedures as specified in the FDDI Station Management (SMT) standard document. The Line State Generator is programmed through Transmit bits 0 to 2 (TMk2:0l) of the Current Transmit State Register (CTSR). Based on the setting of these bits, the Transmitter Block operates in a Transmit Mode where the Line State Generator overwrites the Repeat Filter and Smoother outputs. See INJECTION CONTROL LOGIC section for a listing of the injection Transmit Modes. Table 3-4 describes the Transmit Modes. Transit Mode Behavior Active Transmit Mode Transmit data that comes from Configuration Switch Off Transmit Mode Transmit Quiet symbol pairs and disable the PMD Transmitter Idle Transmit Mode Transmit Idle symbol pairs Master Transmit Mode Transmit Halt-Quiet symbol pairs Quiet Transmit Mode Transmit Quiet symbol pairs Reserved Transmit Mode Reserved for future use. If Mode selected, Quiet symbol pairs will be transmitted. Halt Transmit Mode Transmit Halt Symbol pairs Notes: TL/F/11708 – 7 SE: Smoother Enable C: Preamble Counter FÐIDLE: ForceÐIdle (Stop or ATM) Xn: Current Byte Xn–1: Previous Byte W: RST FIGURE 3-6. Smoother State Diagram 16 3.0 Functional Description (Continued) In the One Shot mode, ISRA and ISRB are injected once on the nth byte after a JK, where n is the programmed value specified in the Injection Threshold Register. INJECTION CONTROL LOGIC The Injection Control Logic replaces the data stream with a programmable symbol pair. This function is used to transmit data other than the normal data frame or Line States. The injection modes can be used for station diagnostic software. The Injection Symbols overwrite the Line State Generator (Transmit Modes) and the Repeat Filter and Smoother outputs. These programmable symbol pairs are stored in the Injection Symbol Register A (ISRA) and Injection Symbol Register B (ISRB). The Injection Threshold Register (IJTR) determines where the Injection Symbol pair will replace the data symbols. The Injection Control Logic is programmed through the bits 0 and 1 (ICk1:0l) of the Current Transmit State Register (CTSR) to one of the following Injection Modes (see Figure 3-7 ): 1. No Injection (i.e. normal operation) 2. One Shot 3. Periodic 4. Continuous In the No Injection mode, the data stream is transmitted unchanged. In the Periodic mode, ISRA and ISRB are injected every nth symbol. In the Continuous mode, all data symbols are replaced with the content of ISRA and ISRB. This is the same as periodic mode with IJTR e 0. SHIFT REGISTER The Shift Register converts encoded parallel data to serial data. The parallel data is clocked into the Shift Register by the Local Byte Clock (LBC1), and clocked out by the Transmit Bit Clock (TXC g ) (externally available on the DP83257.) NRZ TO NRZI ENCODER The NRZ to NRZI Encoder converts the serial Non-ReturnTo-Zero data to Non-Return-To-Zero-Invert-On-One format. This function can be enabled and disabled through bit 6 (TNRZ) of the Mode Register (MR). When programmed to ‘‘0’’, it converts the bit stream from NRZ to NRZI. When programmed to ‘‘1’’, the bit stream is transmitted NRZ. One Shot (Notes 1,3) TL/F/11708 – 8 Periodic (Notes 2,3) TL/F/11708 – 9 Continuous (Note 3) TL/F/11708 – 10 Note 1: In one shot, when n e 0, the JK is replaced Note 2: In periodic, when n e 0, all symbols are replaced. Note 3: Max value on n e 255. FIGURE 3-7. Injection Modes 17 3.0 Functional Description (Continued) respective data path. The first two are PHY Port interface output data paths, AÐIndicate and BÐIndicate, that can drive output data paths of the external PHY Port interface. The third output data path is connected internally to the Transmit Block. The Configuration Switch is the same on the DP83256 device, the DP83256-AP device, and the DP83257 device. However, the DP83257 has two PHY Port interfaces connected to the Configuration Switch, whereas the DP83256 and DP83256-AP have one set of PHY port interfaces. The DP83257 uses the AÐRequest and AÐIndicate paths as one PHY Port interface and the BÐRequest and BÐIndicate paths as the other PHY Port interface (See Figure 3-8 ). The DP83256 and DP83256-AP, having one port interface, use the BÐRequest and AÐIndicate paths as its external port. The AÐRequest and BÐIndicate paths of the DP83256 and DP83256-AP are null connections and are not used by the device (See Figure 3-9 ). 3.4 CONFIGURATION SWITCH The Configuration Switch consists of a set of multiplexers and latches which allow the PLAYER a device to configure the data paths without any external logic. The Configuration Switch is controlled through the Configuration Register (CR). The Configuration Switch has four internal buses: the AÐRequest bus, the BÐRequest bus, the Receive bus, and the PHYÐInvalid bus. The two Request buses can be driven by external input data connected to the external PHY Port interface. The Receive bus is internally connected to the Receive Block of the PLAYER a device, while the PHYÐInvalid bus has a fixed 10-bit SMT PHY Invalid connection (LSU) pattern (1 0011 1010), which is useful during the connection process. The configuration switch also has three internal multiplexers, each can select any of the four buses to connect to its TL/F/11708 – 12 FIGURE 3-9. Configuration Switch Block Diagram for DP83256 and DP83256-AP TL/F/11708–11 FIGURE 3-8. Configuration Switch Block Diagram for DP83257 18 3.0 Functional Description (Continued) Dual Attach Station(DAS) STATION CONFIGURATIONS Single Attach Station (SAS) A Dual Attach Station can be connected directly to the dual ring, or, optionally to a concentrator. There are two types of Dual Attach Stations: DAS with a single MAC and DAS with two MAC layers. See Figure 3-12 and Figure 3-13 . Two DP83256 or DP83256-AP parts can be connected together to build a Dual Attach Station, however this configuration does not support the optional ThruÐB configuration. When the optional ThruÐB configuration is desired, it is recommended that the DP83257 be used. A DAS with a single MAC and two paths can be configured as follows (see Figure 3-12 ): The Single Attach Station can be connected to either the Primary or Secondary ring via a Concentrator. Only 1 MAC is needed in a SAS. The DP83256, DP83256-AP, and DP83257 can be used in a Single Attach Station. The DP83256 and DP83256-AP can be connected to the MAC via its only PHY Port interface. The DP83257 can be connected to the MAC via either one of its 2 PHY Port Interfaces. See Figure 3-10 and Figure 3-11 . # B Indicate data of PHYÐA is connected to A Request input of PHYÐB. BÐRequest input of PHYÐA is connected to A Indicate output of PHYÐB. # The MAC can be connected to either the A Request input and the A Indicate output of PHYÐA or the B Request input and the B Indicate output of PHYÐB. A DAS with a single MAC and one path using the DP83256 or DP83256-AP can be configured as follows (see Figure 313 ): # BÐRequest input of PHYÐA is connected to A Indicate output of PHYÐB. # The MAC is connected to the B Request input of PHYÐB and the AÐIndicate output of PHYÐA. A DAS with dual MACs can be configured as follows (see Figure 3-14 ): # B Indicate data of PHYÐA is connected to A Request input of PHYÐB. BÐRequest input of PHYÐA is connected to A Indicate output of PHYÐB. TL/F/11708 – 13 FIGURE 3-10. Single Attach Station Using the DP83256 or DP83256-AP # MACÐ1 is connected to the BÐIndicate output and the BÐRequest Input of PHYÐB. # MACÐ2 is connected to the AÐIndicate output and the AÐRequest Input of PHYÐA. TL/F/11708 – 14 FIGURE 3-11. Single Attachment Station (SAS) Using the DP83257 19 3.0 Functional Description (Continued) TL/F/11708 – 15 FIGURE 3-12. Dual Attachment Station (DAS), Single MAC (DP83257) TL/F/11708 – 16 FIGURE 3-13. Dual Attachment Station (DAS), Single MAC (DP83256/56-AP) TL/F/11708 – 17 FIGURE 3-14. Dual Attachment Station (DAS), Dual MACs 20 3.0 Functional Description (Continued) This may require external multiplexers, if used in conjunction with two other MAC layers. CONCENTRATOR CONFIGURATIONS There are 2 types of concentrators: Single Attach and Dual Attach. These concentrators can be designed with or without MAC(s). The configuration is determined based upon its type and the number of active MACs in the concentrator. Using the PLAYER a device, a concentrator can be built with many different configurations without any external logic. The DP83256, DP83256-AP, and DP83257 can be used to build a Single Attach concentrator. See Application Note AN-675, Designing FDDI concentrators and Application Note AN-741, Differentiating FDDI concentrators for further information. Concepts A concentrator is comprised of 2 parts: the Dual Ring Connect portion and the Master Ports. The Dual Ring Connection portion connects the concentrator to the dual ring directly or to another concentrator. If the concentrator is connected directly to the dual ring, it is a part of the ‘‘Dual Ring of Trees’’. If the concentrator is connected to another concentrator, it is a ‘‘Branch’’ of the ‘‘Dual Ring of Trees’’. The Master Ports connect the concentrator to its ‘‘Slaves’’, or S-class, Single Attach connections. A slave could be a Single Attach Station or another concentrator (thus forming another Branch of the Dual Ring Tree). When a MAC in a concentrator is connected to the primary or secondary ring, it is required to be situated at the exit port of that ring (i.e. its PHÐIND is connected to the IND Interface of the last Master Port in the concentrator (PHYÐM n) that is connected to that ring). A concentrator can have two MACs, one connected to the primary ring and one to the secondary ring. In addition, roving MACs can be included in the concentrator configuration. A roving MAC can be used to test the stations connected to the concentrator before allowing them to join the dual ring. Single Attach Concentrator A Single Attach concentrator is a concentrator that has only one PHY at the dual ring connect side. It cannot, therefore, be connected directly to the dual ring. A Single Attach concentrator is a branch to the dual ring tree. It is connected to the ring as a slave of another concentrator. Multiple Single Attach concentrators can be connected together hierarchically to build a multiple levels of branches in a dual ring. The Single Attach concentrator can be connected to either the primary or secondary ring depending on the connection with its concentrator (the concentrator that it is connected to as a slave). Figure 3-15 shows a Single Attach concentrator with a single MAC. Dual Attach Concentrator A Dual Attach concentrator is a concentrator that has two PHYs on the dual ring connect side. It is connected directly to the dual ring and is a part of the dual ring tree. The Dual Attach concentrator is connected to both the primary and secondary rings. Dual Attach Concentrator with Single MAC Figure 3-16 shows a Dual Attach concentrator with a single MAC. Because the concentrator has one MAC, it can only transmit and receive frames on the ring to which the MAC is connected. The concentrator can only repeat frames on the other ring. Dual Attach Concentrator with Dual MACs Figure 3-17 shows a Dual Attach concentrator with dual MACs. Because the concentrator has two MACs, it can transmit and receive frames on both the primary and secondary rings. 21 3.0 Functional Description (Continued) TL/F/11708 – 18 FIGURE 3-15. Single Attach Concentrator (SAC), Single MAC TL/F/11708 – 19 FIGURE 3-16. Dual Attach Concentrator (DAC), Single MAC TL/F/11708 – 20 FIGURE 3-17. Dual Attach Concentrator (DAC), Dual MACs 22 3.0 Functional Description (Continued) Another reference clock source option is a local 12.5 MHz crystal circuit. An example crystal circuit with component values is shown in Figure 3-19. This circuit is designed to operate with a crystal that has a CL of 15 pF. The capacitor values may need to be slightly adjusted for an individual application to accomodate differences in parasitic loading. The REFÐSEL signal selects between the two references. 3.5 CLOCK GENERATION MODULE The Clock Generation Module is an integrated phase locked loop that generates all of the required clock signals for the PLAYER a device and the rest of an FDDI system from a single 12.5 MHz reference. The Clock Generation Module features: # High precision clock timing generated from a single 12.5 MHz reference. # Multiple precision phased (8 ns/16 ns) 12.5 MHz Local Component Values Byte Clocks to eliminate timing skew in large multi-board concentrator configurations. Crystal: R: CISO: CIN: COUT: # LBC timing which is insensitive to loading variations over a wide range (20 pF to 70 pF) of LBC loads. 12.50000 MHz 270X 5% 56 pF (1%) 54 pF (1%) 54 pF (1%) # A selectable dual frequency system clock. # Low clock edge jitter, due to high VCO stability. The Clock Generation Module is comprised of 6 main functional blocks: Reference Selector Phase Comparator Loop Filter 250 MHz Voltage Controlled Oscillator Output Phasing and Divide by 10 See Figure 3-18 , Clock Generation Module Block Diagram. TL/F/11708 – 22 FIGURE 3-19. Crystal Circuit PHASE COMPARATOR The Phase Comparator uses two signal inputs: the selected 12.5 MHz reference from the Reference Select Block and a Local Byte Clock that has been selected for the feedback input, FBKÐIN. Typically, LBC1 is used as the feedback clock. The Phase Comparator generates a pulse of current that is proportional to the phase difference between the two signals. The current pulses are used to charge and discharge a control voltage on the internal Loop Filter. This control voltage is used to minimize the phase difference between the two signals. REFERENCE SELECTOR The Reference Selector block allows the user to choose between 2 sources for the Clock Generation Module’s 12.5 MHz reference clock. The simplest reference clock source option is to use an external 12.5 MHz reference signal fed into the REFÐIN input. This input can come from a crystal oscillator module or from a Local Byte Clock generated by another PLAYER a device. Using the appropriate crystal oscillator ensures correct operating frequency without having to adjust any discrete components. Using an LBC clock from another PLAYER a device allows one PLAYER a device to create a master clock to which other PLAYER a devices in a system can be synchronized. LOOP FILTER The Loop Filter is a simple internal filter made up of one capacitor in parallel with a serial capacitor and resistor combination. One end of the filter is connected to Ground and the other node is driven by the Phase Comparator and controls the internal 250 MHz Voltage Controlled Oscillator. This node can be examined for diagnostic purposes on the LPFLTR pin when the FLTREN bit of the CGMREG register is enabled. The LPFLTR pin is provided for diagnostic purposes only and should not be connected in any application. TL/F/11708 – 21 FIGURE 3-18. Clock Generation Module Block Diagram 23 3.0 Functional Description (Continued) The voltage on the Loop Filter is set by the current pulses generated by the Phase Comparator. The voltage on the Loop Filter node controls the frequency of the 250 MHz VCO. 3.6 STATION MANAGEMENT SUPPORT The Station Management Support Block provides a number of useful features to simplify the implementation of the Connection Management (CMT) portion of SMT. These features eliminate the most severe CMT response time constraints imposed by the PCÐReact and CFÐReact times. The many integrated counters and timers also eliminate the need for additional external devices. The following CMT features are supported: 250 MHZ VOLTAGE CONTROLLED OSCILLATOR (VCO) The internal Voltage Controlled Oscillator is a low gain VCO whose primary frequency of oscillation centers around 250 MHz. The VCO produces little clock jitter due to its exceptional stability under all circumstances. The VCO’s output frequency is proportional to the voltage on the Loop Filter node. # # # # # # OUTPUT PHASING The Output Phasing block is a precision clock division circuit that produces clock signals of 4 distinct frequencies. Within the 12.5 MHz frequency, 5 clock signals with selectable 8 ns or 16 ns phase difference are produced. The following clock signals are produced: System Clock (CLK16/CLK32) Local Symbol Clock (LSC) Local Byte Clocks 1–5 (LBCn) (Divide by 10) System Clock (CLK16/CLK32) The System Clock is provided as an extra set of clock frequencies that may be used as a clock for non-FDDI chipset portions of a system or as a higher frequency System Interface clock for the MACSI device. This clock is derived by dividing the 125 MHz clock by 8 or 4 times. The frequency is selectable through the CLKSEL bit of the MODE2 register. The output has built-in glitch suppression so that changing the CLKSEL bit will not result in glitches appearing at the output. Local Symbol Clock (LSC) The Local Symbol Clock is a 40% HIGH/60% LOW duty cycle clock provided for use by the MACSI device and any external logic that needs to be synchronized to the Symbol timing. This clock is derived by dividing the 125 MHz clock by 5. Local Byte Clocks 1–5 (LBCn) The Local Byte Clocks are provided for use by the MACSI device, by any external logic that needs to be synchronized to the Byte timing, and for use in concentrators to synchronize the timing between multiple PLAYER a devices. These clocks are derived by dividing the 125 MHz clock by 10. The different phase relationships between the LBCs are achieved by tapping off of different outputs of a Johnson counter inside the Output Phasing block. The phase relationship (separation by 8 ns or 16 ns) of the LBCs is selected using the PHÐSEL pin. One of the LBCs must be used as the source of the feedback input, FBKÐIN, which requires a 12.5 MHz frequency. When the PLAYER a device is using a crystal as a reference it does not matter which LBC is used as the feedback input. Typically the least loaded LBC is used. However, when using an external reference that is supplied by another PLAYER a device, it is important to select the LBC that keeps your system properly synchronized. Typically, all devices will use LBC1 as the feedback input. PCÐReact CFÐReact Auto Scrubbing (TCF Timer) Timer, Idle Detection (TID Timer) Noise Event Counter (TNE Timer) Link Error Monitor (LEM Counter) PCÐREACT PCÐReact is one of the timing restrictions imposed by Connection Management (CMT). It is one of the two most critical timing restrictions imposed (the other being CFÐReact.) The ANSI SMT standard states that ‘‘PCÐReact is the maximum time for PCM [Physical Connection Management] to make a state transition to PCÐBreak when QLS, a fault condition, or PCÐStart signal is present. This maximum time also places a limit on the time to react to a PCÐStop signal. This limitation does not apply to any other PCM transitions.’’ PCÐReact puts a sharp time limit on how long it takes to transition to the PCÐBreak state and transmit the correct line state when a PCÐBreak transition is required. The range for the timer is PCÐReact s 3.0 ms and has a default value equal to 3.0 ms. The PLAYER a device contains a Trigger Definition Register and a set of CMT Condition Registers that can be used to satisfy the PCÐReact timing. The Trigger Definition Register (TDR) controls two functions. First, it allows the selection of the line state(s) on which to trigger (SILS, MLS, HLS . . . ). For PCÐReact, the line states used would be the ones that caused a transition to the PCÐBreak state from the current PCM state. Second, it allows specification of a line state to be transmitted when the trigger condition is met. For PCÐReact, this is the line state that needs to be transmitted when a transition to the PCÐBreak state occurs, which is Quiet Line State (QLS). The set of CMT Condition registers controls interrupt generation when a trigger condition occurs. The CMT Condition Register set includes a CMT Condition Register (CMTCR), a CMT Condition Comparison Register (CMTCCR), and a CMT Condition Mask Register (CMTCMR). Line state triggering for PCÐReact is enabled by selecting line states to trigger on from the Trigger Definition Register (TDR) bits 3-7. The Trigger Condition Occurred (TCO) bit of the CMTCR is automatically set when the trigger condition specified by the TDR register is met. The line state specified by the Trigger Definition Register (TDR) bits 0 – 2 is then loaded into the Current Transmit Mode Register (CTSR), causing the line state to be transmitted. 24 3.0 Functional Description (Continued) If the TCO Mask (TCOM) bit of the CMTCMR is set, then whenever the CMTCR.TCO bit becomes set the Receive Condition Register B’s Connection Service Event (RCRB.CSE) bit will be set. This allows an interrupt to be generated for the trigger event. As an example, suppose the PCM state machine is in the ACTIVE state. From this state, if a Halt Line State (HLS) or Quiet Line State (QLS) is detected, or the Noise Threshold is reached, the state machine must move to the PCÐBreak state and begin transmitting QLS. To implement this behavior when the PCÐACTIVE state is entered, set TDR.TTM2–0 to 110 (Quiet Transmit), set TDR.TOHLS, TDR.TOQLS, and TDR.TONT and reset all other bits (TOSILS and TOMLS). Also set CMTCMR.TCOM if an interrupt is desired. AUTO SCRUBBING Auto Scrubbing is an additional CMT feature that further enhances the automatic configuration switch setting in order to meet the CFÐReact timing. When enabled, Auto Scrubbing causes 2 PHYÐInvalid symbols followed by Scrub Symbol pairs (Idles) to be sourced for a user selectable duration (the scrubbing time) after a trigger condition (the same one used for PCÐReact and CFÐReact) occurs and prior to a change in the configuration switch setting on all indicate ports that will be changed. Auto Scrubbing is enabled by setting the Enable Scrubbing on Trigger Conditions (ESTC) bit of Mode Register 2 (MODE2). The Scrub Timer Threshold Register (STTR) defines the duration of the scrubbing, which can last up to approximately 10ms. The Scrub Timer Value Register (STVR) can be used to examine a snapshot of the upper 8 bits of the STTR register. CFÐREACT CFÐReact is one of the timing restrictions imposed by Connection Management (CMT). It is one of the two most critical timing restrictions imposed (the other being PCÐReact). The ANSI SMT standard states that ‘‘CFÐReact is the maximum time for CFM [Configuration Management] to reconfigure to remove a non-Active connection from the token path.’’ The range for the timer is CFÐReact s 3.0 ms and has a default value equal to 3.0 ms. The PLAYER a device contains a Trigger Transition Configuration Register and a set of CMT Condition Registers that can be used to satisfy the CFÐReact timing. he Trigger Transition Configuration Register (TTCR) holds the new configuration switch settings to be loaded into the Configuration Register (CR) when a trigger condition occurs. Enabling line state triggering with the Trigger Definition Register (TDR) bits 3–7 also enables the CFÐReact response. This means that whenever trigger conditions are actively used for PCÐReact, the value of the TTCR register will be used also. This implies that it either must always then be loaded with the current configuration setting, causing no change to the CR, or it must be loaded with the appropriate value to accommodate the CFÐReact function. The Trigger Transition Configuration Register (TTCR) must be set the configuration desired when the trigger condition occurs. When the trigger condition occurs the value of this register is loaded into the Configuration Register (CR). During this time writes to the CR are inhibited. To continue the example from the PCÐReact description, suppose that when in the ACTIVE state for the PCM state machine, the CFM state machine is also in the THRUÐA state. If trigger conditions are enabled via the CMTCMR.TCOM bit and it is desired to not implement CFÐ React, TTCR must be set to the present value of CR. If it is desired to not implement CFÐReact then TTCR should be set to the value which would change the configuration to the WRAP state. The wrap conditions WRAPÐA or WRAPÐB depend on which PHY gets reconfigured. TIMER, IDLE DETECTION The Idle Detection Timer is required to flag the continued presence of the Idle Line State for a duration of 8 Idle Symbol pairs plus 1 symbol pair. This feature is implemented in the Receiver Block by the Super Idle Line State (SILS). NOISE EVENT COUNTER The Noise Event Counter can be used to time the duration between Noise Events (which are described in detail below) and to count frame sizes. The first feature is the most often recognized, but the second is often overlooked and can lead to potential difficulty if not properly set. The Noise Event Counter is implemented as a pair of down counters: one the actual Noise Counter and the other a Noise Counter Prescaling value. The Noise Threshold Register (NTR) and the Noise Prescale Threshold Register (NPTR) can be programmed to the counter’s initial value while the Current Noise Count Register (CNCR) and the Current Noise Prescale Count Register (CNPCR) provide a snapshot of the actual counter. The Noise Event Counter decrements whenever a Noise Line State (NLS), Line State Unknown (LSU), or Active Line State (ALS) is received and has its start value reloaded whenever it receives Halt Line State (HLS), Idle Line State (ILS), Master Line State (MLS), Quiet Line State (QLS), or No Signal Detect (NSD). The Noise Event Counter is also reset for a Start or End Delimiter. This means the Noise counter increments for bad events as well as for every data symbol in a frame. Should the Noise Counter expire, it indicates that a new line state (including ALS) has not been entered for NTÐMAX time. This indicates that either a frame is too long or that noise is being received. For this reason it is important to choose a value for the counter that is larger than the longest frame of 4500 bytes. The ANSI SMT specification recommends a value for NTÐMAX of 1.3ms for the noise threshold. A Noise Event is defined as follows: A noise event is a noisebyte, or a byte of data which is not in line with the current line state, indicating error or corruption. 25 3.0 Functional Description (Continued) TABLE 3-5. Noise Event Description Noise Event e LINK ERROR MONITOR Link Error Monitoring is accomplished in the PLAYER a device through the Link Error Monitor Counter. The initial value of this down counter is set using the Link Error Threshold Register (LETR). A snapshot of the counter can be taken with the Current Link Error Count Register (CLECR). A Link Error is defined as follows: [SD # E CD] a [SD # CD # PI # E (II a JK a AB)] a [SD # CD # E PI # (PB e II) # AB] Where: # a E SD CD PB PLS PI e Logical AND e Logical OR e Logical NOT TABLE 3-6. Link Error Event Description Link Error Event e Signal Detect Clock Detect Previous Byte Previous Line State PHY Invalid e HLS a QLS MLS a NLS a ÀULS # [PLS (ALS a ILS)] Ó Idle Line State Active Line State Unknown Line State Halt Line State Quiet Line State Master Line State Noise Line State Unknown Line State ILS ALS ULS HLS QLS MLS NLS ULS e e e e e a e e e e e e e e e I J K e Idle symbol e First symbol of start delimiter e Second symbol of start R S T A B n delimiter e Reset symbol e Set symbol e End Delimiter enaRaSaT enaRaSaTaI e any data symbol [ALS # (I E I a xV a Vx a H E H)] a [ALS # E SD] a [ILS # E (II a JK)] a [ILS # E SD)] a [ULS # (PLS e ALS) # LinkÐErrorÐFlag # E SB # E (HH a HI a II a JK)] Set LinkÐErrorÐFlag e [ALS # (HH a NH a RH a SH a TH)] Clear LinkÐErrorÐFlag e [ALS # JK] a [ILS # JK] a [ULS # (PLS e ALS # LinkÐ ErrorÐFlag # E SB # E (HH a HI a II a JK)] Where: E a # ILS ALS ULS x I H J K V R S T N PLS SD SB 26 Logical NOT Logical OR Logical AND Idle Line State Active Line State Unknown Line State Any symbol Idle symbol Halt symbol First symbol of start delimiter Second symbol of start delimiter e Violation symbol e Reset symbol e Set symbol e End delimiter symbol e Data symbol converted to 0000 by the PLAYER a device Receiver Block in symbol pairs that contain a data and a control symbol e Previous Line State e Signal Detect e Stuff Byte: Byte inserted by EB before a JK symbol pair for recentering or due to off-axis JK e e e e e e e e e e e 3.0 Functional Description (Continued) 3.7 PHY-MAC INTERFACE to be in the Active Line State upon reception of the Starting Delimiter (JK symbol pair). NATIONAL BYTE-WIDE CODE During Idle Line State any non Idle symbols will be reflected as the code IÊ uILS. If both symbols received during Idle Line State are Idle symbols, then the Symbol Decoder generates IÊ kILS as its output. Note the coded Known/Unknown Bit (b3) and the Last Known Line State (b2 – 0). The Receive State is 4 bits long and it represents either the PHY Invalid (0011) or the Idle Line State (1011) condition. The Known/ Unknown Bit shows if the symbols received match the line state information in the last 3 bits. During any line state other than Idle Line State or Active Line State, the Symbol Decoder generates the code VÊ kLS if the incoming symbols match the current line state. The symbol decoder generates VÊ uLS if the incoming symbols do not match the current line state. The PLAYER a device outputs the National byte-wide code from its PHY Port Indicate Output to the MAC device. Each National byte-wide code may contain data or control codes or the line state information of the connection. Table 3-7 lists all the possible outputs. During Active Line State all data and control symbols are being repeated to the PHY Port Indicate Output with the exception of data in data-control mixture bytes. That data symbol is replaced by zero. If only one symbol in a byte is a control symbol, the data symbol will be replaced by 0000 and the whole byte will be presented as control code. Note that the Line State Detector recognizes the incoming data TABLE 3-7. National Byte Wide Code Symbol 1 Current Line State ALS ALS ALS ALS ILS ILS ILS ILS Stuff Byte during ILS Not ALS and Not ILS Not ALS and Not ILS Not ALS and Not ILS Not ALS and Not ILS Stuff Byte during Not ALS Symbol 2 Data Control Bit Data Control Bit Data 0 0 1 1 1 1 x x x 1 1 x x x n n C C I I Not I Not I x M M Not M Not M x 0 1 0 1 1 x 1 x x 1 x 1 x x n C n C I Not I I Not I x M Not M M Not M x 0 1 1 1 1 1 1 1 1 1 1 1 1 1 n-n N-C C-N C-C IÊ -k-LS IÊ -u-LS IÊ -u-LS IÊ -u-LS IÊ -k-ILS VÊ -k-LS VÊ -u-LS VÊ -u-LS VÊ -u-LS VÊ -k-LS, VÊ -u-LS or LÊ -u-ILS 0011 1011 0011 1010 1011 1000 EB Overflow/Underflow SMTÐPI Connection (LSU) Scrub Symbol Pair 1 1 1 Where: n e Any data symbol in À0, 1, 2 . . . F Ó C N I M IÊ VÊ LS u k x National Code Control Bit e Any control symbol in À V, R, S, T, I, H Ó e 0000 e Code for data symbol in a data control mixture byte e Idle Symbol e Any symbol that matches the current line state e 1011 e First symbols of the byte in Idle Line State e 0011 e PHY Invalid e Line State ALS e 000 ILS e 001 NSD e 010 MLS e 100 HLS e 101 QLS e 110 NLS e 111 e1 e Indicates symbol received does not match current line state e0 e Indicate symbol received matches current line state e Don’t care 27 3.0 Functional Description (Continued) National Byte-Wide Code Example Incoming 5B Code 98765 43210 11111 11111 11111 11111 11111 Decoded 4B Code C 3210 C 3210 (II) 1 1010 1 1010 (II) 1 1010 1 1010 11111 (II) 1 1010 1 11000 10001 (JK) 1 1101 –––- –––- (xx) 0 –––- –––- (xx) 0 –––- –––- (xx) National Byte-Wide Code (w/o parity) C 7654 3210 (II) 1 1011 0001 (IÊ -k-ILS)* (II) 1 1011 0001 (IÊ -k-ILS) 1010 (II) 1 1011 0001 (IÊ -k-ILS) 1 1102 (JK) 1 1101 1101 (JK Symbols) ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) 0 ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) (More data Ð) –––- –––- (xx) 0 ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) –––- –––- (xx) 0 ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) –––- –––- (xx) 0 ––– 0 ––– (xx) 0 –– – –– – (Data Symbols) 01101 00111 (TR) 1 0101 1 0110 (TR) 1 0101 0110 (T and R Symbols) 00111 00111 (RR) 1 0110 1 0110 (RR) 1 0110 0110 (Two R Symbols) 11111 11111 (II) 1 1010 1 1010 (II) 1 1010 1010 (Idle Symbols) 11111 11111 (II) 1 1010 1 1010 (II) 1 1010 1010 (Idle Symbols) 11111 11111 (II) 1 1010 1 1010 (II) 1 1011 0001 (IÊ -k-ILS) 11111 11111 (II) 1 1010 1 1010 (II) 1 1011 0001 (IÊ -k-ILS) 11111 11111 (II) 1 1010 1 1010 (II) 1 1011 0001 (IÊ -k-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 1011 1001 (IÊ -u-ILS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 0011 0101 (VÊ -k-HLS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 0011 0101 (VÊ -k-HLS) 00100 00100 (HH) 1 0001 1 0001 (HH) 1 0011 0101 (VÊ -k-HLS) 11111 11111 (II) 1 1010 1 1010 (II) 1 0011 1101 (VÊ -u-HLS) 11111 11111 (II) 1 1010 1 1010 (II) 1 1011 0001 (IÊ -k-ILS) 11111 11111 (II) 1 1010 1 1010 (II) 1 1011 0001 (IÊ -k-ILS) *Assume the receiver is in the Idle Line State. 28 3.0 Functional Description (Continued) or clock generation function, such as a Fiber Optic or Shielded Twisted Pair (SDDI) PMDs. The second, Alternate PMD Interface can be used to support Unshielded Twisted Pair (UTP) PMDs that require external scrambling, and allows implementation with no external clock recovery or clock generation functions required. See Figure 3-21. PLAYER a TO PMD CONNECTIONS The following figures illustrate how the PLAYER a device can be connected to various types of PMDs. 3.8 PMD INTERFACE The PMD Interface connects the PLAYER a device to a standard FDDI Physical Media Connection such as a fiber optic transceiver or a copper twisted pair transceiver. It is a 125 MHz full duplex serial connection. The DP83256 PLAYER a device contains one PMD interface. This PMD Interface should be used for all PMD implementations that do not require an external scrambler/ descrambler function, clock recovery function, or clock generation function, such as a Fiber Optic or Shielded Twisted Pair (SDDI) PMDs. The DP83256-AP and DP83257 PLAYER a devices contain two PMD interfaces. The PMD Interface should be used for all PMD implementations that do not require an external scrambler/descrambler function, clock recovery function, Figure 3-20 shows how the DP83256, DP83256-AP, or DP83257 PLAYER a device is connected to a Fiber Optic or Shielded Twisted Pair (SDDI) PMD using the Primary PMD Interface. Figure 3-21 shows how the DP83256-AP or DP83257 PLAYER a device is connected to an Unshielded Twisted Pair (UTP) PMD using the Alternate PMD Interface. TL/F/11708 – 47 FIGURE 3-20. Fiber Optic or STP PMD Connection TL/F/11708 – 48 FIGURE 3-21. UTP PMD Connections 29 3.0 Functional Description (Continued) in the CGMREG register. The transmit clocks are disabled by default and should be left that way unless it is being used. INTERFACE ACTIVATION The Primary PMD Interface is always enabled. The Alternate PMD Interface is enabled by programming a PLAYER a register bit. To enable the interface, write a 1 to the APMDEN bit in the APMDREG register. The interface is off by default and should be left that way unless it is being used. It will also probably be necessary to enable the Transmit Clocks when using the Alternate PMD Interface. The Transmit Clocks (TXC) are enabled by writing a 1 to the TXCE bit Note that when the Alternate PMD Interface is active, the Primary PMD Interface can not be used without the Alternate PMD Interface connections. Also note that the Long Internal Loopback (LILB) can not be used when the Alternate PMD Interface is activated. 30 4.0 Modes of Operation The PLAYER a device can operate in 4 basic modes: RUN, STOP, LOOPBACK, and CASCADE. 4.1 RUN MODE RUN is the normal mode of operation. In this mode, the PLAYER a device is configured to be connected to the media via the PMD transmitter and PMD receiver at the PMD Interface. It is also connected to any other PLAYER a device(s) and/or MACSI device(s) via the Port A and Port B Interfaces. While operating in the RUN mode, the PLAYER a device receives and transmits Line States (Quiet, Halt, Master, Idle) and frames (Active LIne State). 4.2 STOP MODE The PLAYER a device operates in the STOP mode while it is being initialized or configured. The PLAYER a device is also reset to the STOP mode automatically when the E RST pin is set to ground. When in STOP mode, the PLAYER a device performs the following functions: # # # # # # # Resets the Repeat Filter. Resets the Smoother. Resets the Receiver Block Line State Counters. Resets the Clock Recovery Module Flushes the Elasticity Buffer. Forces Line State Unknown in the Receiver Block. Outputs PHY Invalid condition symbol pairs through the PHY Data Indicate pins (AIP, AIC, AIDk7:0l, BIP, BIC, BIDk7:0l), when port is enabled. TL/F/11708 – 23 FIGURE 4-1. Configuration Switch Loopback for DP83257 # Outputs Quiet symbol pairs through the PMD Data Request pins (PMRD g ). 4.3 LOOPBACK MODE The PLAYER a device provides 3 types of loopback tests: Configuration Switch Loopback, Short Internal Loopback, and Long Internal Loopback. These Loopback modes can be used to test different portions of the device. Configuration Switch Loopback The Configuration Switch Loopback can be used to test the data paths of the MACSI device(s) that are connected to the PLAYER a device before transmitting and receiving data through the network. In the Configuration Switch Loopback mode, the PLAYER a device Configuration Register (CR) can be programmed to perform the following functions: # Select Port A PHY Request Data, Port B PHY Request Data, or PHY Invalid to connect to Port A PHY Indicate Data via the AÐIND Mux. # Select Port A PHY Request Data, Port B PHY Request Data, or PHY Invalid to connect to Port B PHY Indicate Data via the BÐIND Mux. # Connect data from the Receiver Block to the Transmitter Block via the TransmitterÐMux. (The PLAYER a device is repeating incoming data from the media in the Configuration Switch Loopback mode.) See Figure 4-1 and Figure 4-2. TL/F/11708 – 24 FIGURE 4-2. Configuration Switch Loopback for DP83256 and DP 83256-AP 31 4.0 Modes of Operation (Continued) # Ignores the PMD Data Indicate pins (PMID g ), # Outputs Quiet symbols through the PMD Data Request Short Internal Loopback The Short Internal Loopback mode can be used to test the functionality of the PLAYER a device, not including the Clock Recovery function, and to test the data paths between the PLAYER a device and MACSI devices before ring insertion. When in the Short Internal Loopback mode, the PLAYER a device performs the following functions: # Directs the output data of the Transmitter Block to the input of the Receiver Block through an internal path. pins (PMRD g ). The level of the Quiet symbols transmitted through the PMRD g pins during loopback is automatically set to the transmitter off level. If both Short Internal Loopback and Long Internal Loopback modes are selected, Long Internal Loopback mode will have priority over Short Internal Loopback mode. This is the longest loopback path within the PLAYER a device. See Figure 4-3 , Short Internal Loopback. TL/F/11708 – 25 FIGURE 4-3. Short Internal Loopback 32 4.0 Modes of Operation (Continued) # Ignores the PMD Data Indicate pins (PMID g ), # Outputs Quiet symbols through the PMD Data Request Long Internal Loopback The Long Internal Loopback mode implements the longest loopback path that is completely within the PLAYER a device. The Long Internal Loopback mode can be used to test the functionality of the PLAYER a device, including the Clock Recovery function, and to test the data paths between the PLAYER a device and MACSI devices before ring insertion. When in the Long Internal Loopback mode, the PLAYER a device performs the following functions: # Directs the output data of the Transmitter Block to the input of the Clock Recovery Module through an internal path. pins (PMRD g ). The level of the Quiet symbols transmitted through the PMRD g pins during loopback is automatically set to the transmitter off level. If both Short Internal Loopback and Long Internal Loopback modes are selected, Long Internal Loopback mode will have priority over Short Internal Loopback mode. This is the longest loopback path within the PLAYER a device. Note that the LILB path is disconnected and should not be used when the Alternate PMD Interface is active. See Figure 4-4 , Long Internal Loopback. TL/F/11708 – 26 FIGURE 4-4. Long Internal Loopback 33 4.0 Modes of Operation (Continued) Reference Select Reset occurs when the PLAYER a device’s REFÐSEL pin is switched from using the REFÐIN input to using a crystal with the XTALÐIN and XTALÐOUT pins. This is the same as a Power Up Reset and is done because the crystal is going from a dead stop to an active state when REFÐSEL is switched. This reset, like the Power Up Reset, takes about 10 ms from the falling edge of REFÐSEL. Stop Mode is activated by writing a 0 to the RUN bit in the Mode Register. Stop Mode is a selective reset that resets the Clock Recovery Module and portions of the Player Module. Changes from Revision A to Revision B: The previous descriptions describe the reset logic in the revision B PLAYER a device. Two changes were made to the original revision A PLAYER a device reset logic. First, the Hardware Reset was shortened by eliminating the requirement of having to wait for the crystal to settle before letting the Clock Generation Module try to lock to the crystal. This behavior is correct because the PLAYER a device has already waited for the crystal to settle once during the Power Up Reset. The revision A PLAYER a follows a Power Up Reset cycle when Hardware Reset is activated. Second, a full Power Up Reset is now done when the clock reference is switched to the crystal. This is necessary to allow the crystal time to start up when it is switched to from the REFÐIN input. This reset is not performed on the revision A PLAYER a . Recommendations: The following are some recommendations for using the reset mechanisms of the PLAYER a most effectively: 1. Always wait a minimum of 10 ms after power-up before doing anything to the PLAYER a device. 10 ms is a minimum, it may be desirable to wait longer if the system power supply or clock reference has not stabilized by this time. 2. Always use the Hardware Reset to reset the PLAYER a device after Power Up. This should be done after the initial Power Up waiting period of at least 10 ms. 4.4 DEVICE RESET The revision B PLAYER a device has five different levels of device ResetÐPower Up Reset, Hardware Reset, Player Reset, Reference Select Reset, and Stop Mode. The Resets can be used to return the whole device or a portion of the device to its default configuration. Power Up Reset begins automatically when power is first applied to the PLAYER a device and reaches a certain voltage level. Power Up Reset affects all of the modules in the PLAYER a device, specifically the Clock Generation Module (CGM), Clock Recovery Module (CRM), and the Player Module, returning each module to its default configuration. This reset begins by waiting for the crystal to stabilize, then the CGM PLL proceeds to lock to the crystal and the rest of the PLAYER a device is reset. This reset takes the longest amount of time at approximately 10 ms from the time the PLAYER a device’s power supply reaches 4.4V. Even though the Power Up Reset is usually effective, due to the variation in the start-up conditions of a systems power supply, the Power Up Reset trigger can not be guaranteed to operate correctly. Therefore, a Hardware Reset should always be performed on the PLAYER a after waiting a minimum of 10 ms for the Power Up Reset to complete its reset attempt. Hardware Reset occurs at the rising edge of PLAYER a device’s E RST pin. Hardware Reset affects all of the modules in the PLAYER a device, specifically the CGM, CRM and the Player Module, returning each module to its default configuration. During Hardware Reset it is not necessary to force the Clock Generation Module to wait for the crystal to settle again at this time because it has settled in the time since the initial reset at power up. This reset takes the second longest amount of time at approximately 1 ms from the rising edge of E RST. Player Reset is activated by writing a 1 to the PHYRST bit in Mode Register 2. Player Reset only affects the Player Module. This reset is the shortest and only takes about 3 ms from the completion of the register write. The device should not be accessed by the Control Bus during this reset. 34 4.0 Modes of Operation (Continued) # Data frames must be a minimum of three bytes long 4.5 CASCADE MODE The PLAYER a device can operate in the Cascade (parallel) mode (Figure 4-5) which is used in high bandwidth, point-to-point data transfer applications. This is a non-FDDI mode of operation. This is only available on the DP83257 device. Concepts In the Cascade mode, multiple PLAYER a devices are connected together to provide data transfer at multiples of the FDDI data rate. Two cascaded PLAYER a devices provide a data rate twice the FDDI data rate; three cascaded PLAYER a devices provide a data rate three times the FDDI data rate, etc. Multiple data streams are transmitted in parallel over each pair of cascaded PLAYER a devices. All data streams start simultaneously and begin with the JK symbol pair on each PLAYER a device. Data is synchronized at the receiver of each PLAYER a device by the JK symbol pair. Upon receiving a JK symbol pair, a PLAYER a device asserts the Cascade Ready signal to indicate the beginning of data reception. The Cascade Ready signals of all PLAYER a devices are open drain ANDed together to create the Cascade Start signal. The Cascade Start signal is used as the input to indicate that all PLAYER a devices have received the JK symbol pair. Data is now being received at every PLAYER a device and can be transferred from the cascaded PLAYER a devices to the host system. See Figure 4-6 for more information. Operating Rules When the PLAYER a device is operating in Cascade mode, the following rules apply: 1. Data integrity can be guaranteed if the worst case PMD transmission skew between parallel media is less than 40 ns. For example, this amounts to about 785 meters of fiber optic cable, assuming a 1% worst case variance. 2. Even though this is a non-FDDI application, the general rules for FDDI frames must be obeyed. (including the JK symbol pair). Smaller frames will cause Elasticity Buffer errors. # Data frames must have a maximum size of 4500 bytes, with a JK starting delimiter and a T or R or S ending delimiter. 3. Due to the different clock rates, the JK symbol pair may arrive at different times at each PLAYER a device. The total skew between the fastest and slowest cascaded PLAYER a devices receiving the JK starting delimiter must not exceed 80 ns. 4. The first PLAYER a device to receive a JK symbol pair will present it to the host system and release the Cascade Ready signal. The PLAYER a device will present one more JK as it waits for the other PLAYER a devices to recognize their JK. The maximum number of consecutive JKs that can be presented to the host is 2. 5. The Cascade Start signal is set to 1 when all the cascaded PLAYER a devices release their Cascade Ready signals. 6. Bit 4 (CSE) of the Receive Condition Register B (RCRB) is set to 1 if the Cascade Start signal (CS) is not set before the second falling edge of clock signal LBC from when Cascade Ready (CR) was released. CS has to be set approximately within 80 ns of CR release. This condition signifies that not all cascaded PLAYER a devices have received their respective JK symbol pair with the allowed skew range. 7. PLAYER a devices may not report a Cascaded Synchronization Error if the JK symbols are corrupted in the pointto-point links. 8. To guarantee integrity of the interframe information, the user must put at least 8 Idle symbol pairs between frames. The PLAYER a device will function properly with only 4 Idle symbol pairs, however the interframe symbols may be corrupted with random non-JK symbols. The MACSI device could be used to provide the required framing and optional FCS support. 35 4.0 Modes of Operation (Continued) TL/F/11708 – 27 FIGURE 4-5. Parallel Transmission TL/F/11708 – 28 FIGURE 4-6. Cascade Mode of Operation 36 5.0 Registers The PLAYER a device can be initialized, configured, and monitored using 64 8-bit registers. These registers are accessible through the Control Bus Interface. The following tables summarize each register’s attributes. Note: RESERVED Registers may be read at any time, although the values read are not specified. The results of RESERVED Register writes are not specified, and may have adverse implications. The user should not write to RESERVED Register locations. TABLE 5-1. Register Summary Access Rules Register Address Register Symbol 00h MR Mode Register Always Always 01h CR Configuration Register Always Conditional 02h ICR Interrupt Condition Register Always Conditional 03h ICMR Interrupt Condition Mask Register Always Always 04h CTSR Current Transmit State Register Always Conditional 05h IJTR Injection Threshold Register Always Always 06h ISRA Injection Symbol Register A Always Always 07h ISRB Injection Symbol Register B Always Always 08h CRSR Current Receive State Register Always Write Reject 09h RCRA Receive Condition Register A Always Conditional 0Ah RCRB Receive Condition Register B Always Conditional 0Bh RCMRA Receive Condition Mask Register A Always Always 0Ch RCMRB Receive Condition Mask Register B Always Always 0Dh NTR Noise Threshold Register Always Always 0Eh NPTR Noise Prescale Threshold Register Always Always 0Fh CNCR Current Noise Count Register Always Write Reject 10h CNPCR Current Noise Prescale Count Register Always Write Reject 11h STR State Threshold Register Always Always 12h SPTR State Prescale Threshold Register Always Always 13h CSCR Current State Count Register Always Write Reject 14h CSPCR Current State Prescale Count Register Always Write Reject 15h LETR Link Error Threshold Register Always Always 16h CLECR Current Link Error Count Register Always Write Reject 17h UDR User Definable Register Always Always 18h IDR Device ID Register Always Write Reject 19h CIJCR Current Injection Count Register Always Write Reject 1Ah ICCR Interrupt Condition Comparison Register Always Always 1Bh CTSCR Current Transmit State Comparison Register Always Always 1Ch RCCRA Receive Condition Comparison Register A Always Always Register Name Read 37 Write 5.0 Registers (Continued) TABLE 5-1. Register Summary (Continued) Register Address Register Symbol Access Rules Register Name Read Write 1Dh RCCRB Receive Condition Comparison Register B Always Always 1Eh MODE2 Mode Register 2 Always Conditional 1Fh CMTCCR CMT Condition Comparison Register Always Always 20h CMTCR CMT Condition Register Always Conditional 21h CMTMR CMT Condition Mask Register Always Always 22h RR22 Reserved Register 22 Always DO NOT WRITE 23h RR23 Reserved Register 23 Always DO NOT WRITE 24h STTR Scrub Timer Threshold Register Always Always 25h STVR Scrub Timer Value Register Always Write Reject 26h TDR Trigger Definition Register Always Always 27h TTCR Trigger Transition Configuration Register Always Always 28h RR28 Reserved Register 28 Always DO NOT WRITE 29h RR29 Reserved Register 29 Always DO NOT WRITE 2Ah RR2A Reserved Register 2A Always DO NOT WRITE 2Bh RR2B Reserved Register 2B Always DO NOT WRITE 2Ch RR2C Reserved Register 2C Always DO NOT WRITE 2Dh RR2D Reserved Register 2D Always DO NOT WRITE 2Eh RR2E Reserved Register 2E Always DO NOT WRITE 2Fh RR2F Reserved Register 2F Always DO NOT WRITE 30h RR30 Reserved Register 30 Always DO NOT WRITE 31h RR31 Reserved Register 31 Always DO NOT WRITE 32h RR32 Reserved Register 32 Always DO NOT WRITE 33h RR33 Reserved Register 33 Always DO NOT WRITE 34h RR34 Reserved Register 34 Always DO NOT WRITE 35h RR35 Reserved Register 35 Always DO NOT WRITE 36h RR36 Reserved Register 36 Always DO NOT WRITE 37h RR37 Reserved Register 37 Always DO NOT WRITE 38h RR38 Reserved Register 38 Always DO NOT WRITE 39h RR39 Reserved Register 39 Always DO NOT WRITE 3Ah RR3A Reserved Register 3A Always DO NOT WRITE 3Bh CGMREG Clock Generation Module Register Always Always 3Ch APMDREG Alternate PMD Register Always Always 3Dh GAINREG Gain Register Always Always 3Eh RR3E Reserved Register 3E Always DO NOT WRITE 3Fh RR3F Reserved Register 3F Always DO NOT WRITE 38 5.0 Registers (Continued) TABLE 5-2. Register Bit Summary Register Address Register Symbol 00h 01h Bit Symbols D7 D6 D5 D4 MR RNRZ TNRZ TE TQL CM EXLB ILB RUN CR BIE AIE TRS1 TRS0 BIS1 BIS0 AIS1 AIS0 02h ICR UDI RCB RCA LEMT CWI CCR CPE DPE 03h ICMR UDIM RCBM RCAM LEMTM CWIM CCRM CPEM DPEM 04h CTSR RES PRDPE SE IC1 IC0 TM2 TM1 TM0 05h IJTR IJT7 IJT6 IIJ5 IJT4 IJT3 IJT2 IJT1 IJT0 06h ISRA RES RES RES IJS4 IJS3 IJS2 IJS1 IJS0 07h ISRB RES RES RES IJS9 IJS8 IJS7 IJS6 IJS5 08h CRSR RES RES RES RES LSU LS2 LS1 LS0 09h RCRA LSUPI LSC NT NLS MLS HLS QLS NSD 0Ah RCRB RES SILS EBOU CSE LSUPV ALS ST ILS 0Bh RCMRA LSUPIM LSCM NTM NLSM MLSM HLSM QLSM NSDM 0Ch RCMRB RES SILSM EBOUM CSEM LSUPVM ALSM STM ILSM 0Dh NTR RES NT6 NT5 NT4 NT3 NT2 NT1 NT0 0Eh NPTR NPT7 NPT6 NPT5 NPT4 NPT3 NPT2 NPT1 NPT0 0Fh CNCR NCLSCD CNC6 CNC5 CNC4 CNC3 CNC2 CNC1 CNC0 10h CNPCR CNPC7 CNPC6 CNPC5 CNPC4 CNPC3 CNPC2 CNPC1 CNPC0 11h STR RES ST6 ST5 ST4 ST3 ST2 ST1 ST0 12h SPTR SPT7 SPT6 SPT5 SPT4 SPT3 SPT2 SPT1 SPT0 13h CSCR SCLSCD CSC6 CSC5 CSC4 CSC3 CSC2 CSC1 CSC0 14h CSPCR CSPC7 CSPC6 CSPC5 CSPC4 CSPC3 CSPC2 CSPC1 CSPC0 15h LETR LET7 LET6 LET5 LET4 LET3 LET2 LET1 LET0 16h CLECR LEC7 LEC6 LEC5 LEC4 LEC3 LEC2 LEC1 LEC0 17h UDR RES RES RES RES EB1 EB0 SB1 SB0 18h IDR DID7 DID6 DID5 DID4 DID3 DID2 DID1 DID0 19h CIJCR IJC7 IJC6 IJC5 IJC4 IJC3 IJC2 IJC1 IJC0 1Ah ICCR UDIC RCBC RCAC LEMTC CWIC CCRC CPEC DPEC 1Bh CTSCR RESC PRDPEC SEC IC1C IC0C TM2C TM1C TM0C 1Ch RCCRA LSUPIC LSCC NTC NLSC MLSC HLSC QLSC NSDC 1Dh RCCRB RESC SILSC EBOUC CSEC LSUPVC ALSC STC ILSC 1Eh MODE2 ESTC RES CLKSEL RES RES RES CBPE PHYRST 1Fh CMTCCR TCOC STEC RES RES RES RES RES RES 20h CMTCR TCO STE RES RES RES RES RES RES 21h CMTMR TCOM STEM RES RES RES RES RES RES 22h RR22 RES RES RES RES RES RES RES RES 39 D3 D2 D1 D0 5.0 Registers (Continued) TABLE 5-2. Register Bit Summary (Continued) Register Address Register Symbol Bit Symbols D7 D6 D5 D4 D3 D2 D1 D0 RES 23h RR23 RES RES RES RES RES RES RES 24h STTR STT7 STT6 STT5 STT4 STT3 STT2 STT1 STT0 25h STVR STV7 STV6 STV5 STV4 STV3 STV2 STV1 STV0 26h TDR TONT TOQLS TOHLS TOMLS TOSILS TTM2 TTM1 TTM0 27h TTCR BIE AIE TRS1 TRS0 BIS1 BIS0 AIS1 AIS0 28h RR28 RES RES RES RES RES RES RES RES 29h RR29 RES RES RES RES RES RES RES RES 2Ah RR2A RES RES RES RES RES RES RES RES 2Bh RR2B RES RES RES RES RES RES RES RES 2Ch RR2C RES RES RES RES RES RES RES RES 2Dh RR2D RES RES RES RES RES RES RES RES 2Eh RR2E RES RES RES RES RES RES RES RES 2Fh RR2F RES RES RES RES RES RES RES RES 30h RR30 RES RES RES RES RES RES RES RES 31h RR31 RES RES RES RES RES RES RES RES 32h RR32 RES RES RES RES RES RES RES RES 33h RR33 RES RES RES RES RES RES RES RES 34h RR34 RES RES RES RES RES RES RES RES 35h RR35 RES RES RES RES RES RES RES RES 36h RR36 RES RES RES RES RES RES RES RES 37h RR37 RES RES RES RES RES RES RES RES 38h RR38 RES RES RES RES RES RES RES RES 39h RR39 RES RES RES RES RES RES RES RES 3Ah RR3A RES RES RES RES RES RES RES RES 3Bh CGMREG RES RES FLTREN RES TXCE RES RES RES RES 3Ch APMDREG RES RES RES RES APMDEN RES RES 3Dh GAINREG FILT2 FILT1 FILT0 RES RES RES RES RES 3Eh RR3E RES RES RES RES RES RES RES RES 3Fh RR3F RES RES RES RES RES RES RES RES 40 5.0 Registers (Continued) TABLE 5-3. Register Reset Value Summary Reset Contents Register Address Register Symbol 00h MR 00 h 01h CR 00 h 02h ICR X001 0000 B 03h ICMR 00 h 04h CTSR A2 h 05h IJTR 00 h 06h ISRA 00 h 07h ISRB 00 h 08h CRSR 0A h 09h RCRA 20 h 0Ah RCRB 00X0 0010 B 0Bh RCMRA 00 h 0Ch RCMRB 00 h 0Dh NTR 00 h 0Eh NPTR 00 h 0Fh CNCR 00 h 10h CNPCR 00 h 11h STR 00 h 12h SPTR 00 h 13h CSCR 00 h 14h CSPCR 00 h 15h LETR 00 h 16h CLECR 00 h 17h UDR 000X 00XX B depends on sense pins 18h IDR XX h depends on chip version MSB-LSB Comments depends on sense pins depends on EB state 19h CIJCR 00 h 1Ah ICCR 00 h same as reg 02 h if reg 02 h is read first 1Bh CTSCR 00 h same as reg 04 h if reg 04 h is read first 1Ch RCCRA 00 h same as reg 09 h if reg 09 h is read first 1Dh RCCRB 00 h same as reg 0A h if reg 0A h is read first 41 5.0 Registers (Continued) TABLE 5-3. Register Reset Value Summary (Continued) Register Address Reset Contents Register Symbol MSB-LSB 1Eh MODE2 00 h 1Fh CMTCCR 00 h 20h CMTCR 00 h 21h CMTMR 00 h 22h RR22 XX h 23h RR23 XX h 24h STTR 00 h 25h STVR 00 h 26h TDR 00 h 27h TTCR 00 h 28h RR28 XX h 29h RR29 XX h 2Ah RR2A XX h 2Bh RR2B XX h 2Ch RR2C XX h 2Dh RR2D XX h 2Eh RR2E XX h 2Fh RR2F XX h 30h RR30 XX h 31h RR31 XX h 32h RR32 XX h 33h RR33 XX h 34h RR34 XX h 35h RR35 XX h 36h RR36 XX h 37h RR37 XX h 38h RR38 XX h 39h RR39 XX h 3Ah RR3A XX h 3Bh CGMREG 05 h 3Ch APMDREG 00 h 3Dh GAINREG 00 h 3Eh RR3E XX h 3Fh RR3F XX h 42 Comments 5.0 Registers (Continued) 5.1 MODE REGISTER (MR) The Mode Register is used to initialize and configure the PLAYER a device. ACCESS RULES ADDRESS READ WRITE 00h Always Always D7 D6 D5 D4 D3 D2 D1 D0 RNRZ TNRZ TE TQL CM LILB SILB RUN Bit Symbol D0 RUN Description RUN/ E STOP: 0: Enables the STOP mode. Refer to section 4.2, STOP MODE, for more information. 1: Normal operation (i.e. RUN mode). Note: The RUN bit is automatically set to 0 when the E RST pin is asserted (i.e. set to ground). D1 SILB SHORT INTERNAL LOOPBACK: 0: Disables Internal Loopback mode (i.e. normal operation). 1: Enables Internal Loopback mode. Refer to section 4.3, LOOPBACK MODE, for more information. D2 LILB LONG INTERNAL LOOPBACK: 0: Disables Long Internal Loopback mode (i.e. normal operation). 1: Enables Long Internal Loopback mode. Note: Long Internal Loopback should not be used when the Alternate PMD Interface is enabled. Refer to section 4.3, LOOPBACK MODE, for more information. D3 CM CASCADE MODE: 0: Disables synchronization of cascaded PLAYER a devices. 1: Enables the synchronization of cascaded PLAYER a devices. Refer to section 4.4, CASCADE MODE, for more information. Note: Cascade Mode is only available on the DP83257 device. The other devices do not have the required CS and CR pins. Do not set this bit for any device but the DP83257. D4 TQL TRANSMIT QUIET LEVEL: This bit is used to program the transmission level of the Quiet symbols during Off Transmit mode (OTM) only. 0: Low (PMD OFF) level Quiet symbols are transmitted through the PMD Data Request pins (i.e. PMRD a e low, PMRD b e high). 1: High (PMD ON) level Quiet symbols are transmitted through the PMD Data Request pins (i.e. PMRD a e high, PMRD b e low). D5 TE TRANSMIT ENABLE: The TE bit controls the action of the PMD transmitter Enable (TXE) pin. When TE is 0, the TXE output disables the PMD transmitter; when TE is 1, the PMD transmitter is disabled during the Off Transmit Mode (OTM) and enabled otherwise. The On and Off level of the TXE is depended on the PMD transmitter Enable Level (TEL) pin to the PLAYER a device. The following rules summaries the output of TXE. 1. If TE e 0, then TXE e Off 2. If TE e 1 and OTM, then TXE e Off 3. If TE e 1 and not OTM, then TXE e On. D6 TNRZ TRANSMIT NRZ DATA: 0: Transmits data in Non-Return-To-Zero-Invert-On-Ones (NRZI) format (normal format). 1: Transmits data in Non-Return-To-Zero format (NRZ). D7 RNRZ RECEIVE NRZ DATA: 0: Receives data in Non-Return-To-Zero-Invert-On-Ones format (NRZI) (normal format). 1: Receives data in Non-Return-To-Zero format (NRZ). 43 5.0 Registers (Continued) 5.2 CONFIGURATION REGISTER (CR) The Configuration Register controls the Configuration Switch Block and enables/disables both the A and B ports. The CR can be used to create a number of Configuration Loopback paths. The CR is conditionally writable because the TTCR can be writing a new value into the register if this feature is enabled. Note that the AÐRequest and BÐIndicate port are offered only on the DP83257, and not in the DP83256. For further information, refer to section 3.4, CONFIGURATION SWITCH. ACCESS RULES ADDRESS READ WRITE 01h Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 BIE AIE TRS1 TRS0 BIS1 BIS0 AIS1 AIS0 Bit D0, D1 Symbol AIS0, AIS1 Description AÐINDICATE SELECTOR k0, 1l: The AÐIndicate Selector k0, 1l bits selects one of the four Configuration Switch data buses for the A Indicate output port (AIP, AIC, AIDk7:0l). Ð AIS1 0 0 1 1 D2, D3 BIS0, BIS1 AIS0 0 1 0 1 PHY Invalid Bus Receiver Bus AÐRequest Bus BÐRequest Bus BÐINDICATE SELECTOR k0, 1l: The BÐIndicate Selector k0, 1l bits selects one of the four Configuration Switch data buses for the BÐIndicate output port (BIP, BIC, BIDk7:0l) BIS1 0 0 1 1 BIS0 0 1 0 1 PHY Invalid Bus Receiver Bus AÐRequest Bus BÐRequest Bus Note: Even though this bit can be set and/or cleared in the DP83256, it will not affect any I/Os since the DP83256 does not offer a BÐIndicate port. D4, D5 TRS0, TRS1 TRANSMIT REQUEST SELECTOR k0, 1l: The Transmit Request Selector k0, 1l bits select one of the four Configuration Switch data buses for the input to the Transmitter Block. TRS1 0 0 1 1 TRS0 0 1 0 1 PHY Invalid Bus Receiver Bus AÐRequest Bus BÐRequest Bus Note: If the PLAYER a device is in Active Transmit Mode (i.e. the Transmit Mode bits (TM k 2:0 l ) of the Current Transmit State Register (CTSR) are set to 00) and the PHY Invalid Bus is selected, then the PLAYER a device will transmit a maximum of four Halt symbol pairs and then continuous Idle symbols due to the Repeat Filter when in the Repeat state. D6 AIE AÐINDICATE ENABLE: 0: Disables the AÐIndicate output port. The AÐIndicate port pins will be tri-stated when the port is disabled. 1: Enables the AÐIndicate output port (AIP, AIC, AIDk7:0l). D7 BIE BÐINDICATE ENABLE: 0: Disables the BÐIndicate output port. The BÐIndicate port pins will be tri-stated when the port is disabled. 1: Enables the BÐIndicate output port (BIP, BIC, BIDk7:0l). Note: Even though this bit can be set and/or cleared in the DP83256, it will not affect any I/Os since the DP83256 does not offer a BÐIndicate port. 44 5.0 Registers (Continued) 5.3 INTERRUPT CONDITION REGISTER (ICR) The Interrupt Condition Register records the occurrence of an internal error event, the detection of Line State, an unsuccessful write by the Control Bus Interface, the expiration of an internal counter, or the assertion of one or more of the User Definable Sense pins. The Interrupt Condition Register will assert the Interrupt pin ( E INT) when one or more bits within the register are set to 1 and the corresponding mask bits in the Interrupt Condition Mask Register (ICMR) are also set to 1. ACCESS RULES ADDRESS READ WRITE 02h Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 UDI RCB RCA LEMT CWI CCR CPE DPE Bit Symbol D0 DPE Description PHYÐREQUESTÐDATA PARITY ERROR: This bit will be set to 1 when: 1. The PHY Request Data Parity Enable bit (PRDPE) of the Current Transmit State Register (CTSR) is set to 1 and 2. The Transmitter Block detects a parity error in the incoming PHY Request Data. The source of the data can be from the PHY Invalid Bus, the Receive Bus, the AÐBus, or the BÐBus of the Configuration Switch. Note: Parity is only checked on data that goes into the transmitter block. This means that any data that is just routed through the configuration switch without going into the transmit block is not checked. D1 CPE Control Bus DATA PARITY ERROR: This bit will be set to 1 when the Control Bus Interface detects a parity error in the incoming Control Bus Data (CBDk7:0l), CBP during a write cycle. D2 CCR Control Bus WRITE COMMAND REJECT: This bit will be set to 1 when an attempt to write into one of the following read-only registers is made: Current Receive State Register (Register 08, CRSR) Current Noise Count Register (Register 0F, CNCR) Current Noise Prescale Count Register (Register 10, CNPCR) Current State Count Register (Register 13, CSCR) Current State Prescale Count Register (Register 14, CSPCR) Current Link Error Count Register (Register 16, CLECR) Device ID Register (Register 18, IDR) Current Injection Count Register (Register 19, CIJCR) Scrub Timer Value Register (Register 25, STVR) 45 5.0 Registers (Continued) Bit Symbol D3 CWI Description CONDITIONAL WRITE INHIBIT: Set to 1 when bits within mentioned registers do not match bits in the corresponding compare register. This bit ensures that new (i.e. unread) data is not inadvertently cleared while old data is being cleared through the Control Bus Interface. This bit is set to 1 to indicate that a bit in a condition write register was not written because it had changed since the previous read. The following registers are affected: Interrupt Condition Register (Register 02, ICR) Current Transmit State Register (Register 04, CTSR) Receive Condition Register A (Register 09, RCRA) Receive Condition Register B (Register 0A, RCRB) CMT Condition Register (Register 20, CMTCR) The previous registers are affected when they differ from the value of the corresponding bit in the following registers respectively: Interrupt Condition Compare Register (Register 1A, ICCR) Current Transmit State Compare Register (Register 1B, CTSCR) Receive Condition Compare Register A (Register 1C, RCCRA) Receive Condition Compare Register B (Register 1D, RCCRB) CMT Condition Compare Register (Register 1F, CMTCCR) This bit must be cleared by software. Note that this differs from the MACSI, BMAC and BSI device bits of the same name. The Configuration Register (Register 01, CR) can not be written to during scrubbing. D4 LEMT LINK ERROR MONITOR THRESHOLD: This bit is set to 1 when the internal 8-bit Link Error Monitor Counter reaches zero. It will remain set and is cleared by software. During the reset process (i.e. E RST e GND), the Link Error Monitor Threshold bit is set to 1 because the Link Error Monitor Counter is initialized to zero. D5 RCA RECEIVE CONDITION A: This bit is set to 1 when: 1. One or more bits in the Receive Condition Register A (RCRA) is set to 1 and 2. The corresponding mask bits in the Receive Condition Mask Register A (RCMRA) are also set to 1. In order to clear (i.e. set to 0) the Receive Condition A bit, the bits within the Receive Condition Register A that are set to 1 must first be either cleared or masked. D6 RCB RECEIVE CONDITION B: This bit is set to 1 when: 1. One or more bits in the Receive Condition Register B (RCRB) is set to 1 and 2. The corresponding mask bits in the Receive Condition Mask Register A (RCMRB) are also set to 1. In order to clear (i.e. set to 0) the Receive Condition B bit, the bits within the Receive Condition Register B that are set to 1 must first be either cleared or masked. D7 UDI USER DEFINABLE INTERRUPT: This bit is set to 1 when one or any combination of the Sense Bits (SB0, SB1, or SB2) in the User Definable Register (UDR) are set to 1. In order to clear (i.e. set to 0) the User Definable Interrupt Bit, all Sense Bits must be set to 0. 46 5.0 Registers (Continued) 5.4 INTERRUPT CONDITION MASK REGISTER (ICMR) The Interrupt Condition Mask Register allows the user to dynamically select which events will generate an interrupt. The Interrupt pin will be asserted (i.e. E INT e GND) when one or more bits within the Interrupt Condition Register (ICR) are set to 1 and the corresponding mask bits in this register are also set to 1. This register is cleared (i.e. set to 0) and all interrupts are initially masked during the reset process. ACCESS RULES ADDRESS READ WRITE 03h Always Always D7 D6 D5 D4 D3 D2 D1 D0 UDIM RCBM RCAM LEMTM CWIM CCRM CPEM DPEM Bit Symbol Description D0 DPEM PHYÐREQUESTÐDATA PARITY ERROR MASK: The mask bit for the PHYÐRequest Data Parity Error bit (DPE) of the Interrupt Condition Register (ICR). D1 CPEM Control Bus DATA PARITY ERROR MASK: The mask bit for the Control Bus Data Parity Error bit (CPE) of the Interrupt Condition Register (ICR). D2 CCRM Control Bus WRITE COMMAND REJECT MASK: The mask bit for the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR). D3 CWIM CONDITIONAL WRITE INHIBIT MASK: The mask bit for the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR). D4 LEMTM LINK ERROR MONITOR THRESHOLD MASK: The mask bit for the Link Error Monitor Threshold bit (LEMT) of the Interrupt Condition Register (ICR). D5 RCAM RECEIVE CONDITION A MASK: The mask bit for the Receive Condition A bit (RCA) of the Interrupt Condition Register (ICR). D6 RCBM RECEIVE CONDITION B MASK: The mask bit for the Receive Condition B bit (RCB) of the Interrupt Condition Register (ICR). D7 UDIM USER DEFINABLE INTERRUPT MASK: The mask bit for the User Definable Interrupt bit (UDI) of the Interrupt Condition Register (ICR). 47 5.0 Registers (Continued) 5.5 CURRENT TRANSMIT STATE REGISTER (CTSR) The Current Transmit State Register can program the Transmitter Block to internally generate and transmit Idle, Master, Halt, Quiet, or user programmable symbol pairs, in addition to the normal transmission of incoming PHY Request data. The Smoother and PHY Request Data Parity are also enabled and disabled through this register. When the Trigger Definition register (TDR) is used, the CTSR can automatically be set to a preprogrammed line state when a trigger condition occurs. This capability can be used to implement both PCÐReact and CFÐReact. The Transmit Modes have priority over the Repeat Filter and Smoother outputs. The Injection Symbols have priority over the Transmit Modes. During the reset process (i.e. E RST e GND) the Transmit Mode is set to Off (TMk2:0l e 010), the Smoother is enabled (i.e. SE is set to 1), and the Reserved bit (b7) is set to 1. All other bits of this register are cleared (i.e. set to 0) during the reset process. When the TDR register is used to respond to trigger conditions the CTSR will be blocked when the TDR register transmit mode is copied into the CTSR. The Write Reject bit of the ICR will be set if any writes are attempted at this time. Note: This register has no effect while the device is in Stop Mode. ACCESS RULES ADDRESS READ WRITE 04h Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 RES PRDPE SE IC1 IC0 TM2 TM1 TM0 Bit D0, D1, D2 Symbol TM0, TM1, TM2 Description Transmit Mode k0, 1, 2l: These bits select one of the 6 transmission modes for the PMD Request Data output port (TXD g ). TM2 0 0 0 TM1 0 0 1 TM0 0 1 0 0 1 1 1 0 0 1 1 1 0 1 1 1 0 1 Active Transmit Mode (ATM): Normal transmission of incoming PHY Request data. Idle Transmit Mode (ITM): Transmission of Idle symbol pairs (11111 11111). Off Transmit Mode (OTM): Transmission of Quiet symbol pairs (00000 00000) and deassertion of the PMD transmitter Enable pin (TXE). Note: This is the default transmit mode after reset. Reserved: Reserved for future use. Users are discouraged from using this transmit mode. If selected, however, the transmitter will generate Quiet symbol pairs (00000 00000). Master Transmit Mode (MTM): Transmission of Halt and Quiet symbol pairs (00100 00000). Halt Transmit Mode (HTM): Transmission of Halt symbol pairs (00100 00100). Quiet Transmit Mode (QTM): Transmission of Quiet symbol pairs (00000 00000). Reserved: Reserved for future use. Users are discouraged from using this transmit mode. If selected, however, the transmitter will generate Quiet symbol pairs (00000 00000). 48 5.0 Registers (Continued) Bit Symbol D3, D4 IC0, IC1 Description Injection Control k0, 1l: These bits select one of the 4 injection modes. The injection modes have priority over data from the Smoother, Repeat Filter, Encoder, and Transmit Modes. IC0 is the only bit of the register that is automatically cleared by the PLAYER a device after the One Shot Injection is executed. The automatic clear of IC0 during the One Shot mode can be interpreted as a acknowledgment that the One Shot has been completed. IC1 0 IC0 0 0 1 One Shot: In one shot mode, the contents of Injection Symbol Register A (ISRA) and Injection Symbol Register B (ISRB) are injected n symbol pairs after a JK, where n is the programmed value of the Injection Count Register (IJCR). If IJCR is set to 0, the JK symbol pair is replaced by ISRA and ISRB. Once the One Shot is executed, the PLAYER a device automatically sets IC0 to 0, thereby returning to normal transmission of data. 1 0 Periodic: In Periodic mode, the contents of Injection Symbol Register A (ISRA) and Injection Symbol Register B (ISRB) are injected every n-th symbol pair, where n is the programmed value of the Injection Count Register (IJCR). If IJCR is set to 0, all data symbols are replaced with ISRA and ISRB. No Injection: The normal transmission of incoming PHY Request data (i.e. symbols are not injected). Note: The inserted symbol is not automatically aligned to a JK boundary. 1 D5 SE 1 Continuous: In Continuous mode, all data symbols are replaced with the contents of Injection Symbol Register A (ISRA) and Injection Symbol Register B (ISRB). SMOOTHER ENABLE: 0: 1: Disables the Smoother. Enables the Smoother. When enabled, the Smoother can redistribute Idle symbol pairs which were added or deleted by the local or upstream receivers. Note: Once the counter has started, it will continue to count irrespective of the incoming symbols with the exception of a JK symbol pair. D6 PRDPE PHYÐREQUEST DATA PARITY ENABLE: 0: 1: D7 RES Disables PHYÐRequest Data parity. Enables PHYÐRequest Data parity. RESERVED: Reserved for future use. Note: Users are discouraged from using this bit. The reserved bit is set to 1 during the reset process. It may be set or cleared without any effects to the functionality of the PLAYER a device. 49 5.0 Registers (Continued) 5.6 INJECTION THRESHOLD REGISTER (IJTR) The Injection Threshold Register, in conjunction with the Injection Control bits (IC k1:0l) in the Current Transmit State Register (CTSR), set the frequency at which the contents of the Injection Symbol Register A (ISRA) and Injection Symbol Register B (ISRB) are inserted into the data stream. It contains the start value for the Injection Counter. The Injection Threshold Register value is loaded into the Injection Counter when the counter reaches zero or during every Control Bus Interface write-cycle of this register. The Injection Counter is an 8-bit down-counter which decrements every 80 ns. It’s current value is read for CIJCR. The counter is active only during One Shot or Periodic Injection Modes (i.e. Injection Controlk1:0l bits (ICk1:0l) of the Current Transmit State Register (CTSR) are set to either 01 or 10). The Transmitter Block will replace a data symbol pair with ISRA and ISRB when the counter reaches 0 and the Injection Mode is either One Shot or Periodic. If the Injection Threshold Register is set to 0 during the One Shot mode, the JK will be replaced with ISRA and ISRB. If the Injection Threshold Register is set to 0 during the Periodic mode, all data symbols are replaced with ISRA and ISRB. The counter is initialized to 0 during the reset process (i.e. E RST e GND). For further information, see the INJECTION CONTROL LOGIC section. ACCESS RULES ADDRESS READ WRITE 05h Always Always D7 D6 D5 D4 D3 D2 D1 D0 IJT7 IJT6 IJT5 IJT4 IJT3 IJT2 IJT1 IJT0 Bit D0-D7 Symbol IJT0 – IJT7 Description INJECTION THRESHOLD BITk0-7l: Start value for the Injection Counter. IJT0 is the Least Significant Bit (LSB). 50 5.0 Registers (Continued) 5.7 INJECTION SYMBOL REGISTER A (ISRA) The Injection Symbol Register A, along with Injection Symbol Register B, contains the programmable value (already in 5B code) that can be inserted to replace the data symbol pairs. In One Shot mode, ISRA and ISRB are injected n bytes after a JK, where n is the programmed value of the Injection Threshold Register. In the Periodic mode, ISRA and ISRB are injected every n-th symbol pair. In the Continuous mode, all data symbols are replaced with ISRA and ISRB. ACCESS RULES ADDRESS READ WRITE 06h Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES RES RES IJS4 IJS3 IJS2 IJS1 IJS0 Bit Symbol D0 – D4 IJS0–IJS4 INJECTION SYMBOL BITk0-4l: Symbol to be injected. Description D5 – D7 RES RESERVED: Reserved for future use. IJS0 is the Least Significant Bit (LSB) and goes out onto the media last. Note: Users are discouraged from using these bits. The reserved bits are set to 0 during the reset process. They may be set or cleared without any effects to the functionality of the PLAYER a device. 51 5.0 Registers (Continued) 5.8 INJECTION SYMBOL REGISTER B (ISRB) The Injection Symbol Register B, along with Injection Symbol Register A, contains the programmable value (already in 5B code) that will replace the data symbol pairs. In One Shot mode, ISRA and ISRB are injected n bytes after a JK, where n is the programmed value of the Injection Threshold Register. In the Periodic mode, ISRA and ISRB are injected every n-th symbol pair. In the Continuous mode, all data symbols are replaced with ISRA and ISRB. ACCESS RULES ADDRESS READ WRITE 07h Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES RES RES IJS9 IJS8 IJS7 IJS6 IJS5 Bit Symbol D0 – D4 IJS0 – IJS4 INJECTION SYMBOL BITk0-4l: Symbol to be injected. Description D5 – D7 RES RESERVED: Reserved for future use. IJS0 is the Least Significant Bit (LSB) and goes out onto the media last. Note: Users are discouraged from using these bits. The reserved bits are set to 0 during the reset process. They may be set or cleared without any effects to the functionality of the PLAYER a device. 52 5.0 Registers (Continued) 5.9 CURRENT RECEIVE STATE REGISTER (CRSR) The Current Receive State Register represents the current line state being detected by the Receiver Block. When the Receiver Block recognizes a new Line State, the bits corresponding to the previous line state are cleared, and the bits corresponding to the new line state are set. During the reset process ( E RST e GND), the Receiver Block is forced to Line State Unknown (i.e. the Line State Unknown bit (LSU) is set to 1). Note: Users are discouraged from writing to this register. An attempt to write into this register will cause the PLAYER a device to ignore the Control Bus write cycle and set the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) to 1. ACCESS RULES ADDRESS READ WRITE 08h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 RES RES RES RES LSU LS2 LS1 LS0 Bit Symbol D0, D1, D2 LS0, LS1, LS2 Description LINE STATEk0, 1, 2l: These bits represent the current Line State being detected by the Receiver Block. Once the Receiver Block recognizes a new line state, the bits corresponding to the previous line state are cleared, and the bits corresponding to the new line state are set. LS2 0 LS1 0 LS0 0 0 0 1 Idle Line State (ILS): Received a minimum of two consecutive Idle symbol pairs (11111 11111). 0 1 0 No Signal Detect (NSD): The Signal Detect (SD) has been deasserted, indicating that the PLAYER a device is not receiving data from the PMD receiver or that clock detect is not being received from the Clock Recovery Module. SD is ignored during internal loopback. Active Line State (ALS): Received a JK symbol pair (11000 10001), possibly followed by data symbols. Note: NSD is the default value when the device is in Stop mode. However, while in Stop mode certain data patterns entering the Receiver Block may cause the PLAYER a to set LS0. Therefore, the user may see either the NSD (010) or Reserved Value (011) during Stop mode. 0 1 1 Reserved: Reserved for future use. 1 0 0 Master Line State (MLS): Received a minimum of 8 consecutive Halt-Quiet symbol pairs (00100 00000). 1 0 1 Halt Line State (HLS): Received a minimum of 8 consecutive Halt symbol pairs (00100 00100). 1 1 0 Quiet Line State (QLS): Received a minimum of 8 consecutive Quiet symbol pairs (00000 00000). 1 1 1 Noise Line State (NLS): Detected a minimum of 16 noise events. Refer to the Receiver Block description for further information on noise events. D3 LSU LINE STATE UNKNOWN: The Receiver Block has not detected the minimum conditions to enter a known line state. When the Line State Unknown bit is set, LSk2:0l represent the most recently known line state. D4-D7 RES RESERVED: Reserved for future use. Note: Users are discouraged from using these bits. The reserved bits are reset to 0 during the reset process. They may be set or cleared without any effects to the functionality of the PLAYER a device. 53 5.0 Registers (Continued) 5.10 RECEIVE CONDITION REGISTER A (RCRA) The Receive Condition Register A maintains a historical record of the Line States recognized by the Receiver Block. When a new Line State is entered, the bit corresponding to that line state is set to 1. The bits corresponding to the previous Line States are not cleared by the PLAYER a device, thereby maintaining a record of the Line States detected. The Receive Condition A bit (RCA) of the Interrupt Condition Register (ICR) will be set to 1 when one or more bits within the Receive Condition Register A is set to 1 and the corresponding mask bit(s) in Receive Condition Mask Register A (RCMRA) is also set to 1. ACCESS RULES ADDRESS READ WRITE 09h Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 LSUPI LSC NT NLS MLS HLS QLS NSD Bit Symbol D0 NSD NO SIGNAL DETECT: Indicates that the Signal Detect pin (TTLSD) has been deasserted and that the Clock Recovery Module is not receiving data from the PMD receiver. Description D1 QLS QUIET LINE STATE: Received a minimum of eight consecutive Quiet symbol pairs (00000 00000). D2 HLS HALT LINE STATE: Received a minimum of eight consecutive Halt symbol pairs (00100 00100). D3 MLS MASTER LINE STATE: Received a minimum of eight consecutive Halt-Quiet symbol pairs (00100 00000). D4 NLS NOISE LINE STATE: Detected a minimum of sixteen noise events. D5 NT NOISE THRESHOLD: This bit is set to 1 when the internal Noise Counter reaches 0. It will remain set until a value equal to or greater than one is loaded into the Noise Threshold Register or Noise Prescale Threshold Register. During the reset process (i.e. E RST e GND), since the Noise Counter is initialized to 0, the Noise Threshold bit will be set to 1. D6 LSC LINE STATE CHANGE: A line state change has been detected. D7 LSUPI LINE STATE UNKNOWN AND PHY INVALID: The Receiver Block has not detected the minimum conditions to enter a known line state. In addition, the most recently known line state was one of the following line states: No Signal Detect, Quiet Line State, Halt Line State, Master Line State, or Noise Line State. 54 5.0 Registers (Continued) 5.11 RECEIVE CONDITION REGISTER B (RCRB) The Receive Condition Register B maintains a historical record of the Lines States recognized by the Receiver Block. When a new Line State is entered, the bit corresponding to that line state is set to 1. The bits corresponding to the previous Line States are not cleared, thereby maintaining a record of the Line States detected. The Receive Condition B bit (RCB) of the Interrupt Condition Register (ICR) will be set to 1 when one or more bits within the Receive Condition Register B is set to 1 and the corresponding mask bit(s) in Receive Condition Mask Register B (RCMRB) is also set to 1. ACCESS RULES ADDRESS READ WRITE 0Ah Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 RES SILS EBOU CSE LSUPV ALS ST ILS Bit Symbol D0 ILS IDLE LINE STATE: Received a minimum of two consecutive Idle symbol pairs (11111 11111). Description D1 ST STATE THRESHOLD: This bit will be set to 1 when the internal State Counter reaches zero. It will remain set until a value equal to or greater than one is loaded into the State Threshold Register or State Prescale Threshold Register, and this register is cleared. During the reset process (i.e. E RST e GND), since the State Counter is initialized to 0, the State Threshold bit is set to 1. D2 ALS ACTIVE LINE STATE: Received a JK symbol pair (11000 10001), and possibly data symbols following. D3 LSUPV LINE STATE UNKNOWN AND PHY VALID: The Receiver Block has not detected the minimum conditions to enter a known line state. D4 CSE In addition, the most recently known line state was either Active Line State or Idle Line State. CONNECTION SERVICE EVENT/CASCADE SYNCHRONIZATION ERROR: When one or more bits in the CMT Condition Register (CMTCR) are set and the corresponding bit(s) in the CMT Condition Mask Register (CMTCMR) are set, the Connection service event bit will be set to a 1. When a synchronization error occurs, the Cascade Synchronization Error bit is set to 1. A synchronization error occurs if the Cascade Start signal (CS) is not asserted within approximately 80 ns of Cascade Ready (CR) release. Note: Cascade mode and the CMT features can not be used at the same time. Note: Cascade mode is only supported on the DP83257 device. D5 EBOU ELASTICITY BUFFER UNDERFLOW / OVERFLOW: The Elasticity Buffer has either overflowed or underflowed. The Elasticity Buffer will automatically recover if the condition which caused the error is only transient, but the event bit will remain set until cleared by software. D6 SILS SUPER IDLE LINE STATE: Received a minimum of eight Idle symbol pairs (11111 11111). D7 RES RESERVED: Reserved for future use. Note: Users are discouraged from using these bits. The reserved bits are reset to 0 during the reset process. They may be set or cleared without any effects to the functionality of the PLAYER a device 55 5.0 Registers (Continued) 5.12 RECEIVE CONDITION MASK REGISTER A (RCMRA) The Receive Condition Mask Register A allows the user to dynamically select which events will generate an interrupt. The Receive Condition A bit (RCA) of the Interrupt Condition Register (ICR) will be set to 1 when one or more bits within the Receive Condition Register A (RCRA) is set to 1 and the corresponding mask bit(s) in this register is also set to 1. Since this register is cleared (i.e. set to 0) during the reset process, all interrupts are initially masked. ACCESS RULES ADDRESS READ WRITE 0Bh Always Always D7 D6 D5 D4 D3 D2 D1 D0 LSUPIM LSCM NTM NLSM MLSM HLSM QLSM NSDM Bit Symbol Description D0 NSDM NO SIGNAL DETECT MASK: The mask bit for the No Signal Detect bit (NSD) of the Receive Condition Register A (RCRA). D1 QLSM QUIET LINE STATE MASK: The mask bit for the Quiet Line State bit (QLS) of the Receive Condition Register A (RCRA). D2 HLSM HALT LINE STATE MASK: The mask bit for the Halt Line State bit (HLS) of the Receive Condition Register A (RCRA). D3 MLSM MASTER LINE STATE MASK: The mask bit for the Master Line State bit (MLS) of the Receive Condition Register A (RCRA). D4 NLSM NOISE LINE STATE MASK: The mask bit for the Noise Line State bit (NLS) of the Receive Condition Register A (RCRA). D5 NTM NOISE THRESHOLD MASK: The mask bit for the Noise Threshold bit (NT) of the Receive Condition Register A (RCRA). D6 LSCM LINE STATE CHANGE MASK: The mask bit for the Line State Change bit (LSC) of the Receive Condition Register A (RCRA). D7 LSUPIM LINE STATE UNKNOWN AND PHY INVALID MASK: The mask bit for the Line State Unknown and PHY Invalid bit (LSUPI) of the Receive Condition Register A (RCRA). 56 5.0 Registers (Continued) 5.13 RECEIVE CONDITION MASK REGISTER B (RCMRB) The Receive Condition Mask Register B allows the user to dynamically select which events will generate an interrupt. The Receive Condition B bit (RCB) of the Interrupt Condition Register (ICR) will be set to 1 when one or more bits within the Receive Condition Register B (RCRA) is set to 1 and the corresponding mask bits in this register is also set to 1. Since this register is cleared (i.e. set to 0) during the reset process, all interrupts are initially masked. ACCESS RULES ADDRESS READ WRITE 0Ch Always Always D7 D6 D5 D4 D3 D2 D1 D0 RESM SILSM EBOUM CSEM LSUPVM ALSM STM ILSM Bit Symbol Description D0 ILSM IDLE LINE STATE MASK: The mask bit for the Idle Line State bit (ILS) of the Receive Condition Register B (RCRB). D1 STM STATE THRESHOLD MASK: The mask bit for the State Threshold bit (ST) of the Receive Condition Register B (RCRB). D2 ALSM ACTIVE LINE STATE MASK: The mask bit for the Active Line State bit (ALS) of the Receive Condition Register B (RCRB). D3 LSUPVM LINE STATE UNKNOWN AND PHY VALID MASK: The mask bit for the Line State Unknown and PHY Valid bit (LSUPV) of the Receive Condition Register B (RCRB). D4 CSEM CASCADE SYNCHRONIZATION ERROR MASK/CONNECTION SERVICE EVENT MASK: The mask bit for the Cascade Synchronization Error/Connection service event bit (CSE) of the Receive Condition Register B (RCRB). D5 EBOUM ELASTICITY BUFFER OVERFLOW/UNDERFLOW MASK: The mask bit for the Elasticity Buffer Overflow/ Underflow bit (EBOU) of the Receive Condition Register B (RCRB). D6 SILSM SUPER IDLE LINE STATE MASK: The mask bit for the Super Idle Line State bit (SILS) of the Receive Condition Register B (RCRB). D7 RESM RESERVED MASK: The mask bit for the Reserved bit (RES) of the Receive Condition Register B (RCRB). 57 5.0 Registers (Continued) 5.14 NOISE THRESHOLD REGISTER (NTR) The Noise Threshold Register contains the start value for the Noise Timer. This threshold register is used in conjunction with the Noise Prescale Threshold register for setting the maximum allowable time between entry to ILS, HLS, MLS, ALS, or NSD line states. The Noise timer is used to implement the TNE timing requirement of PCM. The Noise timer decrements by one for every 80 x (NPTR a 1) ns in case of Noise events. As a result, the internal noise counter takes the following amount of time to reach zero: ((NPTR a 1) x NTR a NPTR) x 80 ns The threshold values for the Noise Counter and Noise Prescale Counter are simultaneously loaded into both counters if one of the following conditions is true: 1. Both the Noise Counter and Noise Prescale Counter reach zero and the current Line State is either Noise Line State, Active Line State, or Line State Unknown. or 2. The current Line State is either Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. or 3. The Noise Threshold Register or Noise Prescale Threshold Register goes through a Control Bus Interface write cycle. In addition, the value of the Noise Prescale Threshold register is loaded into the Noise Prescale Counter if the Noise Prescale Counter reaches zero. The Noise Counter and Noise Prescale Counter will continue to count, without resetting or reloading the threshold values, if a Line State change occurs and the new line state is either Noise Line State, Active Line State, or Line State Unknown. When both the Noise Threshold Counter and Noise Counter both reach zero, the Noise Threshold bit of the Receive Condition Register A will be set. The recommended default value for the NTR register is 40h and for the NPTR register is F9h which corresponds to 1.3 ms as specified in the ANSI standard. ACCESS RULES ADDRESS READ WRITE 0Dh Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES NT6 NT5 NT4 NT3 NT2 NT1 NT0 Bit Symbol D0-D6 NT0-NT6 Description NOISE THRESHOLD BITk0-6l: Start value for the Noise Counter. NT0 is the Least Significant Bit (LSB). D7 RES RESERVED: Reserved for future use. Note: Users are discouraged from using this bit. Write data is ignored since the reserved bit is permanently set to 0. 58 5.0 Registers (Continued) 5.15 NOISE PRESCALE THRESHOLD REGISTER (NPTR) The Noise Prescale Threshold Register contains the start value for the Noise Prescale Timer. This threshold register is used in conjunction with the Noise Threshold register for setting the maximum allowable time between entry to ILS, HLS, MLS, ALS, or NSD. The Noise timer is used to implement the TNE timing requirement of PCM. The Noise Prescale threshold controls how often the Noise timer is decremented. When the Noise Prescale Timer reaches zero, it reloads the count with the contents of the Noise Prescale Threshold Register and also causes the Noise Timer to decrement. The threshold values for the Noise Counter and Noise Prescale Counter are simultaneously loaded into both counters if one of the following conditions is true: 1. Both the Noise Counter and Noise Prescale Counter reach zero and the current Line State is either Noise Line State, Active Line State, or Line State Unknown. or 2. The Current Line State is either Halt Line State. Idle Line State, Master Line State, Quiet Line State, or No Signal Detect or 3. The Noise Threshold Register or Noise Prescale Threshold Register goes through a Control Bus Interface write cycle. In addition, the value of the Noise Prescale Threshold Register is loaded into the Noise Prescale Counter if the Noise Prescale Counter reaches zero. The Noise Counter and Noise Prescale Counter will continue to count, without resetting or reloading the threshold values, if a Line State change occurs and the new line state is either Noise Line State, Active Line State, or Line State Unknown. When both the Noise Threshold Counter and Noise Counter both reach zero, the Noise Threshold bit of the Receive Condition Register A will be set. See the NTR register description for default value recommendations. ACCESS RULES ADDRESS READ WRITE 0Eh Always Always D7 D6 D5 D4 D3 D2 D1 D0 NPT7 NPT6 NPT5 NPT4 NPT3 NPT2 NPT1 NPT0 Bit Symbol D0-D7 NPT0-NPT7 Description NOISE PRESCALE THRESHOLD BITk0-7l: Start value for the Noise Prescale Timer. NPT0 is the Least Significant Bit (LSB). 59 5.0 Registers (Continued) 5.16 CURRENT NOISE COUNT REGISTER (CNCR) The Current Noise Count Register takes a snap-shot of the Noise Timer during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 0Fh Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 NCLSCD CNC6 CNC5 CNC4 CNC3 CNC2 CNC1 CNC0 Bit Symbol D0 – D6 CNC0 – CNC6 CURRENT NOISE COUNT BIT k0–6l: Snapshot of the Noise Counter. Description D7 NCLSCD NOISE COUNTER LINE STATE CHANGE DETECTION 60 5.0 Registers (Continued) 5.17 CURRENT NOISE PRESCALE COUNT REGISTER (CNPCR) The Current Noise Prescale Count Register takes a snap-shot of the Noise Prescale Timer during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 10h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 CNPC7 CNPC6 CNPC5 CNPC4 CNPC3 CNPC2 CNPC1 CNPC0 Bit Symbol D0 – D7 CNPC0–7 Description CURRENT NOISE PRESCALE COUNT BIT k0 –7l: Snapshot of the Noise Prescale Timer. 61 5.0 Registers (Continued) 5.18 STATE THRESHOLD REGISTER (STR) The State Threshold Register contains the start value for the State Timer. This timer is used in conjunction with the State Prescale Timer to count the Line State duration. The State Timer will decrement every 80 ns if the State Prescale Timer is zero and the current Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. The State Timer takes ((SPTR a 1) x STR a SPTR) x 80 ns to reach zero during a continuous line state condition. The threshold values for the State Timer and State Prescale Timer are simultaneously loaded into both counters if one of the following conditions is true: 1. Both the State Timer and State Prescale Timer reach zero and the current Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. or 2. A line state change occurs and the new Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. or 3. The State Threshold Register or State Prescale Threshold Register goes through a Control Bus Interface write cycle. In addition, the value of the State Prescale Threshold Register is loaded into the State Prescale Counter if the State Prescale Timer reaches zero. The State Timer and State Prescale Timer will reset by reloading the threshold values, if a Line State change occurs and the new Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. On detection of ALS, NLS, or LSU the timer will not decrement. ACCESS RULES ADDRESS READ WRITE 11h Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES ST6 ST5 ST4 ST3 ST2 ST1 ST0 Bit Symbol D0-D6 ST0-ST6 STATE THRESHOLD BITk0-6l: Start value for the State Timer. Description D7 RES RESERVED: Reserved for future use. ST0 is the Least Significant Bit (LSB). Note: Users are discouraged from using this bit. Write data is ignored since the reserved bit is permanently set to 0. 62 5.0 Registers (Continued) 5.19 STATE PRESCALE THRESHOLD REGISTER (SPTR) The State Prescale Threshold Register contains the start value for the State Prescale Timer. The State Prescale Timer is a down counter. It is used in conjunction with the State Timer to count the Line State duration. The threshold values for the State Timer and State Prescale Timer are simultaneously loaded into both timers if one of the following conditions is true: 1. Both the State Timer and State Prescale Timer reach zero and the current Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. or 2. A Line State change occurs and the new Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. or 3. The State Threshold Register or State Prescale Threshold Register goes through a Control Bus Interface write cycle. The State Prescale Timer will decrement every 80 ns if the current Line State is Halt Line State, Idle Line State, Master Line State, Quiet Line State, or No Signal Detect. ACCESS RULES ADDRESS READ WRITE 12h Always Always D7 D6 D5 D4 D3 D2 D1 D0 SPT7 SPT6 SPT5 SPT4 SPT3 SPT2 SPT1 SPT0 Bit Symbol D0 – D7 SPT0–SPT7 Description STATE PRESCALE THRESHOLD BIT k0 –7l: Start value for the State Prescale Timer. SPT0 is the Least Significant Bit (LSB). 63 5.0 Registers (Continued) 5.20 CURRENT STATE COUNT REGISTER (CSCR) The Current State Count Register takes a snap-shot of the State Counter during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 13h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 SCLSCD CSC6 CSC5 CSC4 CSC3 CSC2 CSC1 CSC0 Bit Symbol D0 – D6 CSC0 – CSC6 CURRENT STATE COUNT BIT k0 –6l: Snapshot of the State Counter. Description D7 SCLSCD STATE COUNTER LINE STATE CHANGE DETECTION 64 5.0 Registers (Continued) 5.21 CURRENT STATE PRESCALE COUNT REGISTER (CSPCR) The Current State Prescale Count Register takes a snap-shot of the State Prescale Counter during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 14h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 CSPC7 CSPC6 CSPC5 CSPC4 CSPC3 CSPC2 CSPC1 CSPC0 Bit Symbol D0 – D7 CSPC0–7 Description CURRENT STATE PRESCALE COUNT k0 –7l: Snapshot of the State Prescale Counter. 65 5.0 Registers (Continued) 5.22 LINK ERROR THRESHOLD REGISTER (LETR) The Link Error Threshold Register contains the start value for the Link Error Monitor Counter. It is an 8-bit down-counter which decrements if link errors are detected. When the Counter reaches 0, the Link Error Monitor Threshold Register value is loaded into the Link Error Monitor Counter and the Link Error Monitor Threshold bit (LEMT) of the Interrupt Condition Register (ICR) is set to one. The Link Error Monitor Threshold Register value is also loaded into the Link Error Monitor Counter during every Control Bus Interface write cycle of LETR. The counter is initialized to 0 during the reset process (i.e. E RST e GND). ACCESS RULES ADDRESS READ WRITE 15h Always Always D7 D6 D5 D4 D3 D2 D1 D0 LET7 LET6 LET5 LET4 LET3 LET2 LET1 LET0 Bit Symbol D0 – D7 LET0 – LET7 Description LINK ERROR THRESHOLD BIT k0–7l: Start value for the Link Error Monitor Counter. LET0 is the Least Significant Bit (LSB). 66 5.0 Registers (Continued) 5.23 CURRENT LINK ERROR COUNT REGISTER (CLECR) The Current Link Error Count Register takes a snap-shot of the Link Error Monitor Counter during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 16h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 LEC7 LEC6 LEC5 LEC4 LEC3 LEC2 LEC1 LEC0 Bit Symbol D0 – D7 LEC0–LEC7 Description LINK ERROR COUNT BIT k0 –7l: Snapshot of the Link Error Monitor Counter. 67 5.0 Registers (Continued) 5.24 USER DEFINABLE REGISTER (UDR) The User Definable Register is used to monitor and control events which are external to the PLAYER a device. The value of the Sense Bits reflect the asserted/deasserted state of their corresponding Sense pins. On the other hand, the Enable bits assert/deassert the Enable pins. Note: SB2 and EB2 are only effective for the DP83257. ACCESS RULES ADDRESS READ WRITE 17h Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES EB2 RES SB2 EB1 EB0 SB1 SB0 Bit Symbol D0 SB0 SENSE BIT 0: This bit is set to 1 if the Sense Pin 0 (SP0) is asserted (i.e. SP0 e VCC) for a minimum amount of time. Once the asserted signal is latched, Sense Bit 0 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts in a traceable manner. Description D1 SB1 SENSE BIT 1: This bit is set to 1 if the Sense Pin 1 (SP1) is asserted (i.e. SP1 e VCC) for a minimum amount of time. Once the asserted signal is latched, Sense Bit 1 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts in a traceable manner. D2 EB0 ENABLE BIT 0: The Enable Bit 0 allows control of external logic through the Control Bus Interface. The User Definable Enable Pin 0 (EP0) is asserted/deasserted by this bit. 0: 1: D3 EB1 ENABLE BIT 1: This bit allows control of external logic through the Control Bus Interface. The User Definable Enable Pin 0 (EP0) is asserted/deasserted by this bit. 0: 1: D4 SB2 D5 RES D6 EB2 EP0 is deasserted (i.e. EP0 e GND). EP0 is asserted (i.e. EP0 e VCC). EP1 is deasserted (i.e. EP1 e GND). EP1 is asserted (i.e. EP1 e VCC). SENSE BIT 2: This bit is set to 1 if the Sense Pin 2 (SP2) is asserted (i.e. SP2 e VCC) for a minimum amount of time. Once the asserted signal is latched, Sense Bit 2 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts in a traceable manner. Note: SB2 and EB2 are only effective for the DP83257. RESERVED: Reserved for future use. The reserved bit is set to 0 during the initialization process (i.e. E RST e GND). Note: Users are discouraged from using this bit. It may be set or cleared without any effects to the functionality of the PLAYER a device. ENABLE BIT2: The Enable Bit 2 allows control of external logic through the Control Bus Interface. The User Definable Enable Pin 2 (EP2) is asserted/deasserted by this bit. Note: SB2 and EB2 are only effective for the DP83257. 0: 1: D7 RES EP2 is deasserted (i.e. EP2 e GND). EP2 is asserted (i.e. EP2 e VCC). RESERVED: Reserved for future use. The reserved bit is set to 0 during the initialization process (i.e. E RST e GND). Note: Users are discouraged from using this bit. It may be set or cleared without any effects to the functionality of the PLAYER a device. 68 5.0 Registers (Continued) 5.25 DEVICE ID REGISTER (IDR) The Device ID Register contains the binary equivalent of the revision number for this device. It can be used to ensure proper software and hardware versions are matched. During a Control Bus Interface write cycle, the Control Bus Write Command Register bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1, and will ignore write cycle. REVISION TABLE IDR (hex) DEVICE DESCRIPTION 10 11 PLAYER a Revision A PLAYER a Revision B ACCESS RULES ADDRESS READ WRITE 18h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 DID7 DID6 DID5 DID4 DID3 DID2 DID1 DID0 Bit Symbol D0 – D3 DID0–DID3 DEVICE ID BIT k0-3l: Circuit enhancement revision number. Bit 3 is the MSB. The initial revision of the PLAYER a is equal to 0 and enhancements will increment this number. Description D4 – D7 DID4–DID7 DEVICE ID BIT k4-7l: Architecture level of the PHY device. Bit 7 is the MSB. The original PLAYER device was equal to 0 and the PLAYER a is equal to 1. This number will only be incremented after a significant architectural change. 69 5.0 Registers (Continued) 5.26 CURRENT INJECTION COUNT REGISTER (CIJCR) The Current Injection Count Register takes a snap-shot of the Injection Counter during every Control Bus Interface read cycle of this register. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. The Injection Counter is an 8-bit down-counter which decrements every 80 ns. The counter is active only during One Shot or Periodic Injection Modes (i.e. Injection Controlk1:0l bits (ICk1:0l) of the Current Transmit State Register (CTSR) are set to either 01 or 10). The Injection Threshold Register (IJTR) value is loaded into the Injection Counter when the counter reaches zero and during every Control Bus Interface write cycle of IJTR. The counter is initialized to 0 during the reset process (i.e. E RST e GND). ACCESS RULES ADDRESS READ WRITE 19h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 IJC7 IJC6 IJC5 IJC4 IJC3 IJC2 IJC1 IJC0 Bit D0 – D7 Symbol IJC0 – IJC7 Description INJECTION COUNT BITk0-7l: Current value of the Injection Counter. IJC0 is the Least Significant Bit (LSB). 70 5.0 Registers (Continued) 5.27 INTERRUPT CONDITION COMPARISON REGISTER (ICCR) The Interrupt Condition Comparison Register ensures that the Control Bus must first read a bit modified by the PLAYER a device before it can be written to by the Control Bus Interface. The current state of the Interrupt Condition Register (ICR) is automatically written into the Interrupt Condition Comparison Register (i.e. ICCR e ICR) during a Control Bus Interface read-cycle of ICR. During a Control Bus Interface write cycle, the PLAYER a device will set the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR) to 1 and disallow the setting or clearing of a bit within ICR when the value of a bit in ICR differs from the value of the corresponding bit in the interrupt Condition Comparison Register. ACCESS RULES ADDRESS READ WRITE 1Ah Always Always D7 D6 D5 D4 D3 D2 D1 D0 UDIC RCBC RCAC LEMTC CWIC CCRC CPEC DPEC Bit Symbol D0 DPEC PHYÐREQUEST DATA PARITY ERROR COMPARISON: The comparison bit for the PHYÐRequest Data Parity Error bit (DPE) of the Interrupt Condition Register (ICR). Description D1 CPEC CONTROL BUS DATA PARITY ERROR COMPARISON: The comparison bit for the Control Bus Data Parity Error bit (CPE) of the Interrupt Condition Register (ICR). D2 CCRC CONTROL BUS WRITE COMMAND REJECT COMPARISON: The comparison bit for the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR). D3 CWIC CONDITIONAL WRITE INHIBIT COMPARISON: The comparison bit for the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR). D4 LEMTC LINK ERROR MONITOR THRESHOLD COMPARISON: The comparison bit for the Link Error Monitor Threshold bit (LEMT) of the Interrupt Condition Register (ICR). D5 RCAC RECEIVE CONDITION A COMPARISON: The comparison bit for the Receive Condition A bit (RCA) of the Interrupt Condition Register (ICR). D6 RCBC RECEIVE CONDITION B COMPARISON: The comparison bit for the Receive Condition B bit (RCB) of the Interrupt Condition Register (ICR). D7 UDIC USER DEFINABLE INTERRUPT COMPARISON: The comparison bit for the User Definable Interrupt bit (UDIC) of the Interrupt Condition Register (ICR). 71 5.0 Registers (Continued) 5.28 CURRENT TRANSMIT STATE COMPARISON REGISTER (CTSCR) The Current Transmit State Comparison Register ensures that the Control Bus must first read a bit modified by the PLAYER a device before it can be written to by the Control Bus Interface. The current state of the Current Transmit State Register (CTSR) is automatically written into the Current Transmit State Comparison Register A (i.e. CTSCR e CTSR) during a Control Bus Interface read cycle of CTSR. During a Control Bus Interface write cycle, the PLAYER a device will set the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR) to 1 and disallow the setting or clearing of a bit within the CTSR when the value of a bit in the CTSR differs from the value of the corresponding bit in the Current Transmit State Comparison Register. ACCESS RULES ADDRESS READ WRITE 1Bh Always Always D7 D6 D5 D4 D3 D2 D1 D0 RESC PRDPEC SEC IC1C IC0C TM2C TM1C TM0C Bit Symbol D0 TM0C TRANSMIT MODE k0l COMPARISON: The comparison bit for the Transmit Mode k0l bit (TM0) of the Current Transmit State Register (CTSR). Description D1 TM1C TRANSMIT MODE k1l COMPARISON: The comparison bit for the Transmit Mode k1l bit (TM1) of the Current Transmit State Register (CTSR). D2 TM2C TRANSMIT MODE k2l COMPARISON: The comparison bit for the Transmit Mode k2l bit (TM2) of the Current Transmit State Register (CTSR). D3 IC0C INJECTION CONTROL k0l COMPARISON: The comparison bit for the Injection Control k0l bit (IC0) of the Current Transmit State Register (CTSR). D4 IC1C INJECTION CONTROL k1l COMPARISON: The comparison bit for the Injection Control k1l bit (IC1) of the Current Transmit State Register (CTSR). D5 SEC SMOOTHER ENABLE COMPARISON: The comparison bit for the Smoother Enable bit (SE) of the Current Transmit State Register (CTSR). D6 PRDPEC PHYÐREQUEST DATA PARITY ENABLE COMPARISON: The comparison bit for the PHYÐRequest Data Parity Enable bit (PRDPE) of the Current Transmit State Register (CTSR). D7 RESC RESERVED COMPARISON: The comparison bit for the Reserved bit (RES) of the Current Transmit State Register (CTSR). 72 5.0 Registers (Continued) 5.29 RECEIVE CONDITION COMPARISON REGISTER A (RCCRA) The Receive Condition Comparison Register A ensures that the Control Bus must first read a bit modified by the PLAYER a device before it can be written to by the Control Bus Interface. The current state of RCRA is automatically written into the Receive Condition Comparison Register A (i.e. RCCRA e RCRA) during a Control Bus Interface read cycle of RCRA. During a Control Bus Interface write cycle, the PLAYER a device will set the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR) to 1 and prevent the setting or clearing of a bit within RCRA when the value of a bit in RCRA differs from the value of the corresponding bit in the Receive Condition Comparison Register A. ACCESS RULES ADDRESS READ WRITE 1Ch Always Always D7 D6 D5 D4 D3 D2 D1 D0 LSUPIC LSCC NTC NLSC MLSC HLSC QLSC NSDC Bit Symbol D0 NSDC NO SIGNAL DETECT COMPARISON: The comparison bit for the No Signal Detect bit (NSD) of the Receive Condition Register A (RCRA). Description D1 QLSC QUIET LINE STATE COMPARISON: The comparison bit for the Quiet Line State bit (QLS) of the Receive Condition Register A (RCRA). D2 HLSC HALT LINE STATE COMPARISON: The comparison bit for the Halt Line State bit (HLS) of the Receive Condition Register A (RCRA). D3 MLSC MASTER LINE STATE COMPARISON: The comparison bit for the Master Line State bit (MLS) of the Receive Condition Register A (RCRA). D4 NLSC NOISE LINE STATE COMPARISON: The comparison bit for the Noise Line State bit (NLS) of the Receive Condition Register A (RCRA). D5 NTC NOISE THRESHOLD COMPARISON: The comparison bit for the Noise Threshold bit (NT) of the Receive Condition Register A (RCRA). D6 LSCC LINE STATE CHANGE COMPARISON: The comparison bit for the Line State Change bit (LSC) of the Receive Condition Register A (RCRA). D7 LSUPIC LINE STATE UNKNOWN AND PHY INVALID COMPARISON: The comparison bit for the Line State Unknown and PHY Invalid bit (LSUPI) of the Receive Condition Register A (RCRA). 73 5.0 Registers (Continued) 5.30 RECEIVE CONDITION COMPARISION REGISTER B (RCCRB) The Receive Condition Comparison Register B ensures that the Control Bus must first read a bit modified by the PLAYER a device before it can be written to by the Control Bus Interface. The current state of RCRB is automatically written into the Receive Condition Comparison Register B (i.e. RCCRB e RCRB) during a Control Bus Interface read cycle RCRB. During a Control Bus Interface write cycle, the PLAYER a device will set the Conditional Write Inhibit bit (CWI) of the Interrupt Condition Register (ICR) to 1 and prevent the setting or clearing of a bit within RCRB when the value of a bit in RCRB differs from the value of the corresponding bit in the Receive Condition Comparison Register B. ACCESS RULES ADDRESS READ WRITE 1Dh Always Always D7 D6 D5 D4 D3 D2 D1 D0 RESC SILSC EBOUC CSEC LSUPVC ALSC STC ILSC Bit Symbol D0 ILSC IDLE LINE STATE COMPARISON: The comparison bit for the Idle Line State bit (ILS) of the Receive Condition Register B (RCRB). Description D1 STC STATE THRESHOLD COMPARISON: The comparison bit for the State Threshold bit (ST) of the Receive Condition Register B (RCRB). D2 ALSC ACTIVE LINE STATE COMPARISON: The comparison bit for the Active Line State bit (ALS) of the Receive Condition Register B (RCRB). D3 LSUPVC LINE STATE UNKNOWN AND PHY VALID COMPARISON: The comparison bit for the Line State Unknown and PHY Valid bit (LSUPV) of the Receive Condition Register B (RCRB). D4 CSEC CONNECTION SERVICE EVENT COMPARISON / CASCADE SYNCHRONIZATION ERROR: The comparison bit for the Cascade Synchronization Error/Connection Service Event bit (CSE) of the Receive Condition Register B (RCRB). D5 EBOUC ELASTICITY BUFFER OVERFLOW / UNDERFLOW COMPARISON: The comparison bit for the Elasticity Buffer Overflow/Underflow bit (EBOU) of the Receive Condition Register B (RCRB). D6 SILSC SUPER IDLE LINE STATE COMPARISON: The comparison bit for the Super Idle Line State bit (SILS) of the Receive Condition Register B (RCRB). D7 RESC RESERVED COMPARISON: The comparison bit for the Reserved bit (RES) of the Receive Condition Register B (RCRB). 74 5.0 Registers (Continued) 5.31 MODE REGISTER 2 (MODE2) The Mode Register 2 (MODE2) is used to configure the PLAYER a device. The register is used to software reset the chip, setup data parity, and enable scrubbing functions. Note: This register can not be written to during reset. ACCESS RULES ADDRESS READ WRITE 1Eh Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 ESTC RES CLKSEL RES RES RES CBPE PHYRST Bit D0 Symbol PHYRST Description PLAYER RESET: This bit can be used as a master software reset of the PLAYER function within the PLAYER a device. The clock distribution and recovery sections of the chip are not affected by this reset. The PLAYER a automatically clears this bit 32 byte time after its assertion to indicate that the reset action has been completed. This bit can be set through a C-Bus write, but can only be cleared by the PLAYER a . D1 CBPE C-Bus Parity Enable: This bit disables or enables parity checking on C-Bus data. When this bit is set to 0, no parity checking is done. When the bit is set to 1, parity checking is enabled during a C-Bus write cycle. Should a mismatch occur, the C-Bus Data Parity Error (ICR.CPE) bit will be set and the corresponding C-Bus access is discarded. C-Bus data parity is always generated during a C-Bus read cycle. D2 – D4 RES RESERVED: Reserved for future use. D5 CLKSEL CLOCK SELECT: This bit controls the frequency of the CLK16 output. It resets to 0 which sets the CLK16 output to a 15.625 MHz frequency. When set to 1 a 31.25 MHz frequency is generated. Note: When the value of this bit is changed, no glitches appear on the CLK16 output due to the frequency change. D6 RES RESERVED: Reserved for future use. D7 ESTC ENABLE SCRUBBING on TRIGGER CONDITIONS: When ESTC is set to 1 and a Trigger Condition occurs (as set in the TDR register), the Trigger Transition Configuration Register (TTCR) is loaded into the Configuration Register (CR) and scrubbing is started on all indicate ports that have changed. Scrubbing is accomplished by sending out 2 PhyÐInvalid symbols followed by ‘‘scrub’’symbol pairs for a time defined by the Scrub Timer Threshold register. 75 5.0 Registers (Continued) 5.32 CMT CONDITION COMPARISON REGISTER (CMTCCR) The CMT Condition Comparison Register (CMTCR) ensures that the Control Bus must first read a bit modified by the PLAYER a device before it can be written to by the Control Bus Interface. The current state of the CMT Condition Register (CMTCR) is automatically written into the CMT Condition Comparison Register (CMTCR) (i.e. CMTCCR e CMTCR) during a Control Bus Interface read-cycle of CMTCR. During a Control Bus Interface write cycle, the PLAYER a device will set the Conditional Write Inhibit bit (CWI) of the Interrupt Control Register (ICR) to 1 and disallow the setting or clearing of a bit within the CMTCR when the value of a bit in the CMTCR differs from the value of the corresponding bit in the CMT Condition Comparison Register. ACCESS RULES ADDRESS READ WRITE 1Fh Always Always D7 D6 D5 D4 D3 D2 D1 D0 TCOC STEC RES RES RES RES RES RES Bit Symbol Description D0-D5 RES RESERVED: Reserved for future use. D6 STEC SCRUB TIMER EXPIRED COMPARISON: The comparison bit for the Scrub Timer Expire bit (STE) of the CMT Condition Register (CMTCR). D7 TCOC TRIGGER CONDITION OCCURRED COMPARISON: The comparison bit for the Trigger Condition Occurred (TCO) bit of the CMT Condition Register (CMTCR). 76 5.0 Registers (Continued) 5.33 CMT CONDITION REGISTER (CMTCR) The CMT Condition Register maintains a history of all CMT events and actions performed. The corresponding CMT Condition Mask Register (CMTCMR) can be used to generate an interrupt. When the bits in both the CMTCMR and CMTCR are set, the Receive Condition Register B’s Connection Service Event (RCRB.CSE) bit will be set. ACCESS RULES ADDRESS READ WRITE 20h Always Conditional D7 D6 D5 D4 D3 D2 D1 D0 TCO STE RES RES RES RES RES RES Bit Symbol D0-D5 RES D6 STE Description RESERVED: Reserved for future use. SCRUB TIMER EXPIRED: This bit is set to 1 when the Scrub Timer expires. Note: When STE is set, the Configuration Register (CR) is protected. D7 TCO TRIGGER CONDITION OCCURRED: This bit is set to 1 when a trigger condition is met. When a trigger occurs, the values in the Trigger Transmit Mode (TDR.TTM2-0) are loaded into the Current Transmit Mode Register (CTSR.TM2-0). Note: When TCO is set, the Current Transmit State Register (CTSR) is protected. 77 5.0 Registers (Continued) 5.34 CMT CONDITION MASK REGISTER (CMTCMR) This is the mask register for the CMT Condition Register (CMTCR). When the bits in both the CMTCMR and CMTCR are set, the Receive Condition Register B’s Connection Service Event (RCRB.CSE) bit will be set. ACCESS RULES ADDRESS READ WRITE 21h Always Always D7 D6 D5 D4 D3 D2 D1 D0 TCOM STEM RES RES RES RES RES RES Bit Symbol Description D0-D5 RES RESERVED: Reserved for future use. D6 STEM SCRUB TIMER EXPIRED MASK: The mask bit for the Scrub Timer Expired (STE) bit of the CMT Condition Register (CMTCR). D7 TCOM TRIGGER CONDITION OCCURRED MASK: The mask bit for the Trigger Condition Occurred (TCO) bit of the CMT Condition Register (CMTCR). 78 5.0 Registers (Continued) 5.35 RESERVED REGISTERS 22H–23H (RR22H– RR23H) This register is reserved for future use. DO NOT ACCESS THIS REGISTER ACCESS RULES ADDRESS READ WRITE 22h –23h Always DO NOT WRITE 79 5.0 Registers (Continued) 5.36 SCRUB TIMER THRESHOLD REGISTER (STTR) This is the threshold value of the internal scrub timer. It has a resolution of 40.96 ms and a maximum value of E 10 ms. When the scrub timer reaches zero, the Scrub Timer Expired (CMTCR.STE) bit is set. Scrubbing is initiated when MODE2.ESTC e 1 and a trigger condition occurs. Writing to STTR during scrubbing will not affect the scrubbing action. ACCESS RULES ADDRESS READ WRITE 24h Always Always D7 D6 D5 D4 D3 D2 D1 D0 STT7 STT6 STT5 STT4 STT3 STT2 STT1 STT0 Bit D0 – D7 Symbol STT0 – STT7 Description SCRUB TIMER THRESHOLD BITk0-7l: Scrub Timer threshold. STT0 is the Least Significant Bit (LSB). 80 5.0 Registers (Continued) 5.37 SCRUB TIMER VALUE REGISTER (STVR) This is a snap-shot of the current value of the upper 8 bits of the scrub timer. During a Control Bus Interface write cycle, the Control Bus Write Command Reject bit (CCR) of the Interrupt Condition Register (ICR) will be set to 1 and will ignore a write cycle. ACCESS RULES ADDRESS READ WRITE 25h Always Write Reject D7 D6 D5 D4 D3 D2 D1 D0 STV7 STV6 STV5 STV4 STV3 STV2 STV1 STV0 Bit Symbol D0 – D7 STV0–STV7 Description SCRUB TIMER VALUE BITk0-7l: Snap-shot of the scrub timer. STV0 is the Least Significant Bit (LSB). 81 5.0 Registers (Continued) 5.38 TRIGGER DEFINITION REGISTER (TDR) This register determines which events cause a trigger transition and which transmit mode is entered when a trigger transition is detected. The trigger transmit modes are the same as those found in the Current Transmit State Register (CTSR), and are loaded from the TDR into the CTSR when any of the selected trigger conditions occur. When a trigger condition occurs CMTCR.TCO is set. The Trigger Definition Register is useful to implement the strict PCÐReact time requirement. ACCESS RULES ADDRESS READ WRITE 26h Always Always D7 D6 D5 D4 D3 D2 D1 D0 TONT TOQLS TOHLS TOMLS TOSILS TTM2 TTM1 TTM0 Bit Symbol D0, D1, D2 TTM0, TTM1, TTM2 Description TRIGGER TRANSMIT MODE k0, 1, 2l: These bits select one of 6 transmission modes to be loaded into the Current Transmit State Register (CTSR) when a trigger condition is detected. The trigger condition is selected by the upper 5 bits of this register. TTM2 TTM1 0 0 TTM0 0 Active Transmit Mode (ATM): Normal transmission of incoming PHY Request data. 0 0 1 Idle Transmit Mode (ITM): Transmission of Idle symbol pairs (11111 11111). 0 1 0 Off Transmit Mode (OTM): Transmission of Quiet symbol pairs (00000 00000) and deassertion of the PMD transmitter Enable pin (TXE). 0 1 1 Reserved: Reserved for future use. Users are discouraged from using this transmit mode. If selected, however, the transmitter will generate Quiet symbol pairs (00000 00000). 1 0 0 Master Transmit Mode (MTM): Transmission of Halt and Quiet symbol pairs (00100 00000). 1 0 1 Halt Transmit Mode (HTM): Transmission of Halt symbol pairs (00100 00100). 1 1 0 Quiet Transmit Mode (QTM): Transmission of Quiet symbol pairs (00000 00000). 1 1 1 Reserved: Reserved for future use. Users are discouraged from using this transmit mode. If selected, however, the transmitter will generate Quiet symbol pairs (00000 00000). D3 TOSILS TRIGGER ON SILS: Trigger when SILS is received. D4 TOMLS TRIGGER ON MLS: Trigger when MLS is received. D5 TOHLS TRIGGER ON HLS: Trigger when HLS is received. D6 TOQLS TRIGGER ON QLS (or NSD): Trigger when QLS is received. D7 TONT TRIGGER ON Noise Threshold: Trigger when Noise Threshold is reached (Current Noise Register e 0). 82 5.0 Registers (Continued) 5.39 TRIGGER TRANSITION CONFIGURATION REGISTER (TTCR) The Trigger Transition Configuration Register holds the configuration switch setting to be loaded into the Configuration Register (CR) when a trigger transition takes place. When scrubbing is enabled, scrubbing is performed for a period of time indicated by the Scrub Timer Threshold Register (STTR).The register bit descriptions for the Configuration Register and, therefore, the Trigger Transition Configuration Register are reprinted below. ACCESS RULES ADDRESS READ WRITE 27h Always Always D7 D6 D5 D4 D3 D2 D1 D0 BIE AIE TRS1 TRS0 BIS1 BIS0 AIS1 AIS0 Bit D0, D1 Symbol AIS0, AIS1 Description AÐINDICATE SELECTOR k0, 1l: The AÐIndicate Selector k0, 1l bits selects one of the four Configuration Switch data buses for the A Indicate output port (AIP, AIC, AIDk7:0l). Ð AIS1 0 0 1 1 D2, D3 BIS0, BIS1 AIS0 0 1 0 1 PHY Invalid Bus Receiver Bus AÐRequest Bus BÐRequest Bus BÐINDICATE SELECTOR k0, 1l: The BÐIndicate Selector k0, 1l bits selects one of the four Configuration Switch data buses for the BÐIndicate output port (BIP, BIC, BIDk7:0l). BIS1 0 0 1 1 BIS0 0 1 0 1 PHY Invalid Bus Receiver AÐRequest Bus BÐRequest Bus Note: Even though this bit can be set and/or cleared in the DP83256 (for single path stations), it will not affect any I/Os since the DP83256 does not offer a BÐIndicate port. D4, D5 TRS0, TRS1 TRANSMIT REQUEST SELECTOR k0, 1l: The Transmit Request Selector k0, 1l bits selects one of the four Configuration Switch data buses for the input to the Transmitter Block. TRS1 0 0 1 1 TRS0 0 1 0 1 PHY Invalid Bus Receiver Bus AÐRequest Bus BÐRequest Bus Note: If the PLAYER a device is in Active Transmit Mode (i.e. the Transmit Mode bits (TM k 2:0 l ) of the Current Transmit State Register (CTSR) are set to 00) and the PHY Invalid Bus is selected, then the PLAYER a device will transmit continuous Idle symbols due to the Repeat Filter. D6 AIE AÐINDICATE ENABLE: 0: Disables the AÐIndicate output port. The AÐIndicate port pins will be tri-stated when the port is disabled. 1: Enables the AÐIndicate output port (AIP, AIC, AIDk7:0l). D7 BIE BÐINDICATE ENABLE: 0: Disables the BÐIndicate output port. The BÐIndicate port pins will be tri-stated when the port is disabled. 1: Enables the BÐIndicate output port (BIP, BIC, BIDk7:0l). Note: Even though this bit can be set and/or cleared in the DP83256 (for single path stations), it will not affect any I/Os since the DP83256 does not offer a BÐIndicate port. 83 5.0 Registers (Continued) 5.40 RESERVED REGISTERS 28H-3AH (RR28H-RR3AH) These registers are reserved for future use. DO NOT ACCESS THESE REGISTERS ACCESS RULES ADDRESS READ WRITE 28h – 3Ah Always DO NOT WRITE 84 5.0 Registers (Continued) 5.41 CLOCK GENERATION MODULE REGISTER (CGMREG) This register is used to enable or disable the 125 MHz ECL Transmit clock outputs. These outputs are not required for use in a standard FDDI board implementation and are disabled by default to reduce high frequency noise. These TXC outputs are included for support of alternate FDDI PMDs, such as unshielded twisted pair copper cable. DO NOT WRITE TO RESERVED REGISTER BITS. Writes to reserved register bits could prevent proper device operation. Therefore, read the register first, and then write it back with the non-reserved bits set to the desired value. ACCESS RULES ADDRESS READ WRITE 3Bh Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES RES FLTREN RES TXCE RES RES RES Bit Symbol Description D0-D2 RES RESERVED BITS: DO NOT CHANGE THE VALUE OF THESE BITS. Changes to reserved register bits could prevent proper device operation. D3 TXCE TRANSMIT CLOCK ENABLE: When bit is set to 1, 125 MHz ECL TXC outputs are enabled. When this bit is reset to 0, TXC outputs are disabled. TXC outputs are disabled on reset. Note: TXC clocks are only available on the 160-pin DP83257 PLAYER a device. D4 RES RESERVED BITS: DO NOT CHANGE THE VALUE OF THESE BITS. Changes to reserved register bits could prevent proper device operation. D5 FLTREN FILTER ENABLE: When bit is set to 1, the internal loop filter node is connected to the LPFLTR pin for diagnostic viewing. This bit is reset to 0 by default, which disconnects the filter node from the LPFLTR pin. Note: In normal operation this bit should be disabled ( e 0). D6-D7 RES RESERVED BITS: DO NOT CHANGE THE VALUE OF THESE BITS. Changes to reserved register bits could prevent proper device operation. 85 5.0 Registers (Continued) 5.42 ALTERNATE PMD REGISTER (APMDREG) This register is used to enable or disable the Alternate PMD inputs and ouputs. These signals are not required for use in FDDI board implementations that do not require a scrambler that is external to the PLAYER a device. The actual interface consists of the signal pairs RXCÐOUT, RXDÐOUT, RXCÐIN, and RXDÐIN. The interface is disabled by default and should only be enabled if it is being used. Note that Long Internal Loopback should not be used when the Alternate PMD Interface is enabled. DO NOT WRITE TO RESERVED REGISTER BITS. Writes to reserved register bits could prevent proper device operation. Therefore, read the register first, and then write it back with the non-reserved bits set to the desired value. Note: The Alternate PMD Interface pins are only available on the 100-pin DP83256-AP and 160-pin DP83257 PLAYER a devices. The Alternate PMD Interface is disabled on reset. ACCESS RULES ADDRESS READ WRITE 3Ch Always Always D7 D6 D5 D4 D3 D2 D1 D0 RES RES RES RES APMDEN RES RES RES Bit Symbol Description D0 – D2 RES RESERVED BITS: DO NOT CHANGE THE VALUE OF THESE BITS. Changes to reserved register bits could prevent proper device operation. D3 APMDEN ALTERNATE PMD ENABLE: When bit is set to 1, the Alternate PMD Interface is enabled. When this bit is reset to 0, the Alternate PMD Interface is disabled. The Alternate PMD Interface consists of the following extra ECL signal pairs RXCÐOUT, RXDÐOUT, RXCÐIN, and RXDÐIN. In some alternate PMD implementations it may also be necessary to use the 125 MHz Transmit Clock signals (TXC). The TXC outputs must be separately enabled by the TXCE bit in the CGMREG register. Note: The Alternate PMD Interface pins are only available on the 100-pin DP83256-AP and 160-pin DP83257 PLAYER a devices. The Alternate PMD Interface is disabled on reset. D4 – D7 RES RESERVED BITS: DO NOT CHANGE THE VALUE OF THESE BITS. Changes to reserved register bits could prevent proper device operation. 86 5.0 Registers (Continued) 5.43 GAIN REGISTER (GAINREG) The Gain Register contains the settings for the CGM’s on-chip programmable loop filter. For optimal jitter performance on the revision A and B PLAYER a device’s Filter Position 4 should be used. The user should check that the IDR register is equal to revision A or B (10h or 11h) before changing the filter setting as later revisions will default to the correct setting which may be a different filter position number. Pseudo Code Programming Example: Care must be taken when changing the settings of the on-chip programmable loop filter. The filter should only be set to the recommended value and the additional bits in the Gain Register must not be altered. Alteration of the reserved bits in the Gain Register may result in improper PLAYER a device operation. The following pseudo code outlines the proper procedure for setting the Gain Register loop filter settings to the correct value. // Register names and constants are all in UPPERCASE // // #define REV B 0x11 #define REV A 0x10 #define LOOP MASK 0x1F #define NEW LOOP 0x40 if (IDR k4 REV B) À temp 4 GAIN REG temp 4 temp & LOOP MASK temp 4 temp l NEW LOOP GAIN REG 4 temp Ó else ÀDo NothingÓ ACCESS RULES ADDRESS READ WRITE 3Dh Always Always D7 D6 D5 D4 D3 D2 D1 D0 FILT2 FILT1 FILT0 RES RES RES RES RES Bit Symbol Description D0 – D4 RES RESERVED: Do not alter these bits. The device may cease to operate properly if these bits are changed. D5 – D7 FILT0, FILT1, FILT2 FILTER SELECTION k0, 1, 2l: The Filter Selection k0, 1, 2l bits select one of five on-chip CGM loop filters. Note: Filter combinations that are not specified or recommended should not be used and may result in non-optimal device performance. FILT2 1 1 0 FILT1 1 1 0 FILT0 0 1 0 0 0 0 1 1 0 FP0: Filter Position 0. FP1: Filter Position 1. FP2: Filter Position 2. This is the filter selected after reset on the revision A and B PLAYER a devices. FP3: Filter Position 3. FP4: Filter Position 4. This is the recommended filter position for the revision A and B PLAYER a devices. 87 5.0 Registers (Continued) 5.44 RESERVED REGISTERS 3EH-3FH (RR3EH-RR3FH) These registers are reserved for future use. DO NOT ACCESS THESE REGISTERS ACCESS RULES ADDRESS READ WRITE 3Eh – 3Fh Always DO NOT WRITE 88 6.0 Signal Descriptions 6.1 DP83256VF PIN DESCRIPTIONS The pin descriptions for the DP83256VF are divided into 5 functional interfaces: PMD Interface, PHY Port Interface, Control Bus Interface, Clock Interface, and Miscellaneous Interface. For a Pinout Summary list, refer to Table 8-1 and Figure 8-1 , DP83256VF 100-Pin JEDEC Metric PQFP Pinout. PMD INTERFACE The PMD Interface consists of I/O signals used to connect the PLAYER a device to the Physical Medium Dependant (PMD) sublayer. Symbol Pin Ý I/O PMID a PMIDb 39 38 I PMD Indicate Data: Differential, 100k ECL, 125 Mbps serial data input signals from the PMD receiver. Description PMRD a PMRDb 33 32 O PMD Request Data: Differential, 100k ECL, 125 Mbps serial data output signals to the PMD transmitter. SD a SDb 37 36 I Signal Detect: Differential 100k ECL input signals from the PMD receiver indicating that a signal is being received by the PMD receiver. TEL 47 I PMD Transmitter Enable Level: A TTL input signal to select the PMD transmitter Enable (TXE) signal level. TXE 46 O PMD Transmitter Enable: A TTL output signal to enable/disable the PMD transmitter. The output level of the TXE pin is determined by three parameters: the Transmit Enable (TE) bit in the Mode Register, the TM2-TM0 bits in the Current Transmit State Register, and the input to the TEL pin. The following rules summarize the output of the TXE pin: 1. If TE e 0 and TEL e GND, then TXE e VCC 2. If TE e 0 and TEL e VCC, then TXE e GND 3. If TE e 1 and OTM and TEL e GND, then TXE e VCC 4. If TE e 1 and OTM and TEL e VCC, then TXE e GND 5. If TE e 1 and not OTM and TEL e GND, then TXE e GND 6. If TE e 1 and not OTM and TEL e VCC, then TXE e VCC 89 6.0 Signal Descriptions (Continued) PHY PORT INTERFACE The PHY Port Interface consists of I/O signals used to connect the PLAYER a device to the Media Access Control (MAC) sublayer or other PLAYER a device. The DP83256 Device has two PHY Port Interfaces. The AÐIndicate path from one PHY Port Interface and the BÐRequest path from the second PHY Port Interface. Each path consists of an odd parity bit, a control bit, and two 4-bit symbols. Refer to section 3.3, the Configuration Switch, for more information. Symbol Pin Ý I/O Description AIP 6 O PHY Port A Indicate Parity: A TTL output signal representing odd parity for the 10-bit wide Port A Indicate signals (AIP, AIC, and AIDk7:0l). AIC 7 O PHY Port A Indicate Control: TTL output signal indicating that the two 4-bit symbols (AIDk7:4l and AIDk3:0l) are either control symbols (AIC e 1) or data symbols (AIC e 0). AID7 AID6 AID5 AID4 8 9 10 13 O PHY Port A Indicate Data: TTL output signals representing the first 4-bit data/control symbol. AID3 AID2 AID1 AID0 14 15 16 17 O BRP 70 I PHY Port B Request Parity: A TTL input signal representing odd parity for the 10-bit wide Port A Request signals (BRP, BRC, and BRDk7:0l). BRC 69 I PHY Port B Request Control: A TTL input signal indicating that the two 4-bit symbols AID7 is the most significant bit and AID4 is the least significant bit of the first symbol. PHY Port A Indicate Data: TTL output signals representing the second 4-bit data/control symbol. AID3 is the most significant bit and AID0 is the least significant bit of the second symbol. (BRDk7:4l and BRDk3:0l) are either control symbols (BRC e 1) or data symbols (BRC e 0). BRD7 BRD6 BRD5 BRD4 68 67 66 63 I BRD3 BRD2 BRD1 BRD0 62 61 60 59 I PHY Port B Request Data: TTL input signals representing the first 4-bit data/control symbol. BRD7 is the most significant bit and BRD4 is the least significant bit of the first symbol. PHY Port B Request Data: TTL input signals representing the second 4-bit data/control symbol. BRD3 is the most significant bit and BRD0 is the least significant bit of the second symbol. 90 6.0 Signal Descriptions (Continued) CONTROL BUS INTERFACE The Control Bus Interface consists of I/O signals used to connect the PLAYER a device to Station Management (SMT). The Control Bus is an asynchronous interface between the PLAYER a device and a general purpose microprocessor or other controller. It provides access to 64 8-bit internal registers. In the PLAYER a device the Control Bus address range has been expanded by 1-bit to 6 bits of address space. Symbol Pin Ý I/O E CE 73 I Control Enable: An active-low, TTL, input signal which enables the Control Bus port for a read or write cycle. R/ E W, CBAk5:0l, CBP, and CBDk7:0l must be valid at the time E CE is low. Description R/ E W 72 I Read/ E Write: A TTL input signal which indicates a read Control Bus cycle(R/ E W e 1), or a write Control Bus cycle (R/ E W e 0). E ACK 75 O E Acknowledge: An active low, TTL, open drain output signal which indicates the completion of a read or write cycle. During a read cycle, CBDk7:0l are valid as long as E ACK is low ( E ACK e 0). During a write cycle, a microprocessor must hold CBDk7:0l valid until E ACK becomes low. Once E ACK is low, it will remain low as long as E CE remains low ( E CE e 0). E INT 74 O E Interrupt: An active low, open drain, TTL, output signal indicating that an interrupt condition has occurred. The Interrupt Condition Register (ICR) should be read in order to find out the source of the interrupt. Interrupts can be masked through the use of the Interrupt Condition Mask Register (ICMR). CBA5 CBA4 CBA3 CBA2 CBA1 CBA0 83 82 81 80 77 76 I Control Bus Address: TTL input signals used to select the address of the register to be read or written. CBP 96 I/O CBA5 is the most significant bit (MSB) and CBA0 is the least significant bit (LSB) of the address signals. Control Bus Parity: A bidirectional, TTL signal representing odd parity for the Control Bus data (CBDk7:0l). During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. If incorrect parity is used during a write cycle, the PLAYER a device will inhibit the write cycle and set the Control Bus Data Parity Error (CPE) bit in the Interrupt Condition Register (ICR). CBD7 CBD6 CBD5 CBD4 CBD3 CBD2 CBD1 CBD0 95 94 93 92 91 90 89 86 I/O Control Bus Data: Bidirectional, TTL signals containing the data to be read from or written to a register. During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. 91 6.0 Signal Descriptions (Continued) CLOCK INTERFACE The Clock Interface consists of 12.5 MHz and 25 MHz clocks supplied by the PLAYER a device as well as reference and feedback inputs. Symbol Pin Ý I/O Description LBC1 LBC2 LBC3 LBC4 LBC5 4 3 2 1 100 O Local Byte Clock: TTL compatible, 12.5 MHz, 50% duty cycle clock outputs which are phase locked to a crystal oscillator or reference signal. The PHÐSEL input determines whether the five phase outputs are phase offset by 8 ns or 16 ns. PHÐSEL 22 I Phase Select: TTL compatible input used to select either a 8 ns or 16 ns phase offset between the 5 local byte clocks (LBC’s). The LBC’s are phase offset 8ns apart when PHÐSEL is at a logic LOW level and 16 ns apart when at a logic HI level. FBKÐIN 25 I Feedback Input: TTL compatible input for use as the PLL’s phase comparator feedback input to close the Phase Locked Loop. This input is intended to be driven from one of the Local Byte Clocks (LBC’s) from the same PLAYER a device. LSC 99 O Local Symbol Clock: TTL compatible 25 MHz output for driving the MACSI or BMAC devices. This output’s negative phase transition is aligned with the LBC1 output transitions and has a 40% HI and 60% LOW duty cycle. CLK16 5 O Clock 16/32: TTL compatible clock with a selectable frequency of approximately 15.625 MHz or 31.25 MHz. The frequency can be selected using the Clock Select (CLKSEL) bit of the Mode 2 Register (MODE2). Note: No glitches appear at the output when switching frequencies. XTALÐIN 27 I External Crystal Oscillator Input: This input in conjunction with the XTALÐOUT output, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . This input is selected when the REFÐSEL input is at a logic LOW level. When not being used, this input should be tied to ground. XTALÐOUT 26 O External Crystal Oscillator Output: This output in conjunction with the XTALÐIN input, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . REFÐIN 24 I Reference Input: TTL compatible input for use as the PLL’s phase comparator reference frequency. This input is for use in dual attach station or concentrator configurations where there are multiple PLAYER a devices at a given site requiring synchronization. This input is selected when the REFÐSEL input is at a logic HI level. REFÐSEL 23 I Reference Select: TTL compatible input which selects either the crystal oscillator inputs XTALÐIN and XTALÐOUT or the REFÐIN inputs as the reference frequency inputs for the PLL. The crystal oscillator inputs are selected when REFÐSEL is at a logic LOW level and the REFÐIN input is selected as the reference when REFÐSEL is at a logic HI level. LPFLTR 30 O Loop Filter: This is a diagnostic output that allows monitoring of the clock generation module’s filter node. This output is disabled by default and does not need to be connected to any external device. It can be enabled using the FLTREN bit of the Clock generation module register (CGMREG). Note: In normal operation this pin should be disabled. 92 6.0 Signal Descriptions (Continued) MISCELLANEOUS INTERFACE The Miscellaneous Interface consist of a reset signal, user definable sense signals, and user definable enable signals. Symbol Pin Ý I/O E RST Description 71 I Reset: An active low, TTL, input signal which clears all registers. The signal must be kept asserted for a minimum amount of time. Once the E RST signal is asserted, the PLAYER a device should be allowed the specified amount of time to reset internal logic. Note that bit zero of the Mode Register will be set to zero (i.e. Stop Mode). See section 4.2, Stop Mode of Operation for more information SP0 40 I User Definable Sense Pin 0: A TTL input signal from a user defined source. Sense Bit 0 (SB0) of the User Definable Register (UDR) will be set to one if the signal is asserted for a minimum of 160 ns. Once the asserted signal is latched, Sense Bit 0 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts. SP1 42 I User Definable Sense Pin 1: A TTL input signal from a user defined source. Sense Bit 1 (SB1) of the User Definable Register (UDR) will be set to one if the signal is asserted for a minimum of 160 ns. Once the asserted signal is latched, Sense Bit 1 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts. EP0 41 O User Definable Enable Pin 0: A TTL output signal allowing control of external logic through the Control Bus Interface. EP0 is asserted/deasserted through Enable Bit 0 (EB0) of the User Definable Register (UDR). When Enable Bit 0 is set to zero, EP0 is deasserted. When Enable Bit 0 is set to one, EP0 is asserted. EP1 43 O User Definable Enable Pin 1: A TTL output signal allowing control of external logic through the Control Bus Interface. EP1 is asserted/deasserted through Enable Bit 1 (EB1) of the User Definable Register (UDR). When Enable Bit 1 is set to zero, EP1 is deasserted. When Enable Bit 1 is set to one, EP1 is asserted. 93 6.0 Signal Descriptions (Continued) POWER AND GROUND All power pins should be connected to a single a 5V power supply using the recommended filtering. All ground pins should be connected to a common 0V ground supply. Bypassing and filtering requirements are given in a separate User Information Document. Symbol Pin Ý VCCÐANALOG 20 I/O Power: Positive 5V power supply for the PLAYER a device’s CGM VCO. Description GNDÐANALOG 21 Ground: Power supply return for the PLAYER a device’s CGM VCO. VCCÐCORE 88 Power: Positive 5V power supply for the core PLAYER section logic gates. GNDÐCORE 87 Ground: Power supply return for the core PLAYER section logic gates. VCCÐECL 31, 34, 44, 56 Power: Positive 5V power supply for the PLAYER a device’s ECL logic gates. GNDÐECL 35, 45, 55 Ground: Power supply return for the PLAYER a device’s ECL logic gates. VCCÐESD 28 Power: Positive 5V power supply for the PLAYER a device’s ESD protection circuitry. GNDÐESD 29 Ground: Power supply return for the PLAYER a device’s ESD protection circuitry. VCCÐIO 11, 65, 79, 98 Power: Positive 5V power supply for the input/output buffers. GNDÐIO 12, 64, 78, 97 Ground: Power supply return for the input/output buffers. SPECIAL CONNECT PINS These are pins that have special connection requirements. No Connect (N/C) pins should not be connected to anything. This means not to power, not to ground, and not to each other. ReservedÐ0 (RESÐ0) pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. ReservedÐ1 (RESÐ1) pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. Symbol Pin Ý N/C 49, 54 I/O No Connect: Pins should not be connected to anything. This means not to power, not to ground, and not to each other. Description RESÐ0 18, 19, 48, 50, 51, 52, 53, 57, 58, 84 Reserved 0: Pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. RESÐ1 85 Reserved 1: Pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. 94 6.0 Signal Descriptions (Continued) 6.2 DP83256VF-AP SIGNAL DESCRIPTIONS The pin descriptions for the DP83256VF-AP are divided into five functional interfaces; PMD Interface, PHY Port Interface, Control Bus Interface, Clock Interface, and Miscellaneous Interface. For a Pinout Summary List, refer to Table 8-2 and Figure 8-2 , DP83256VF-AP 100-Pin JEDEC Metric PQFP Pinout. PMD INTERFACE The PMD Interface consists of I/O signals used to connect the PLAYER a device to the Physical Medium Dependant (PMD) sublayer. The DP83256VF-AP PLAYER a device actually has two PMD interfaces. The Primary PMD Interface and the Alternate PMD Interface. The Primary PMD Interface should be used for all PMD implementations that do not require an external scrambler/descrambler function, clock recovery function, or clock generation function, such as a Fiber Optic or Shielded Twisted Pair (SDDI) PMD. The second, Alternate PMD Interface can be used to support Unshielded Twisted Pair (UTP) PMDs that require external scrambling, with no external clock recovery or clock generation functions required. Section 3.8 describes how the PLAYER a can be connected to the PMD and how the Alternate PMD can be enabled. Note that when the Alternate PMD Interface is not being used, the pins that make up the interface must be connected in the specific way described in the following Alternate PMD Interface table. Primary PMD Interface Symbol Pin Ý I/O PMID a PMIDb 42 41 I PMD Indicate Data: Differential, 100k ECL, 125 Mbps serial data input signals from the PMD Receiver into the Clock Recovery Module (CRM) of the PLAYER a . Description PMRD a PMRDb 34 33 O PMD Request Data: Differential, 100k ECL, 125 Mbps serial data output signals to the PMD transmitter. SD a SDb 40 39 I Signal Detect: Differential 100k ECL input signals from the PMD receiver indicating that a signal is being received by the PMD receiver. 95 6.0 Signal Descriptions (Continued) Alternate PMD Interface Pin Ý I/O PMID a PMIDb Symbol 42 41 I PMD Indicate Data: Differential, 100k ECL, 125 Mbps serial data input signals from the PMD Receiver into the Clock Recovery Module (CRM) of the PLAYER a . Description RXCÐOUT a RXCÐOUTb 36 35 O Recovered Clock Out: 125 MHz clock recovered by the Clock Recovery Module (CRM) from the PMID data input. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used they should be left Not Connected (N/C). RXDÐOUT a RXDÐOUTb 52 51 O Recovered Data Out: 125 Mbps data recovered by the Clock Recovery Module (CRM) from the PMID data input. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used they should be left Not Connected (N/C). RXCÐIN a RXCÐINb 48 47 I Receive Clock In: Clock inputs to the Player section of the PLAYER a . These inputs must be synchronized with the RXDÐIN inputs. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used, pin 76 should be left Not Connected (N/C) and pin 75 should be connected directly to ground (ReservedÐ0). RXDÐIN a RXDÐINb 50 49 I Receive Data In: Data inputs to the Player section of the PLAYER a . These inputs must be synchronized with the RXCÐIN inputs. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used, pin 78 should be left Not Connected (N/C) and pin 77 should be connected directly to ground (ReservedÐ0). PMRD a PMRDb 34 33 O PMD Request Data: Differential, 100k ECL, 125 Mbps serial data output signals to the PMD transmitter. TXC a TXCb 31 30 O Transmit Clock: 125 MHz, 100k ECL compatible differential outputs synchronized to the outgoing PMRD data. These signals can be enabled using the Transmit Clock Enable (TXCE) bit in the Clock Generation Module Register (CGMREG). When these two pins are not used they should be left Not Connected (N/C). SD a SDb 40 39 I Signal Detect: Differential, 100k ECL, input signals from the PMD receiver indicating that a signal is being received by the PMD receiver. 96 6.0 Signal Descriptions (Continued) PHY PORT INTERFACE The PHY Port Interface consists of I/O signals used to connect the PLAYER a device to the Media Access Control (MAC) sublayer or other PLAYER a device. The DP83256 Device has two PHY Port Interfaces. The AÐIndicate path from one PHY Port Interface and the BÐRequest path from the second PHY Port Interface. Each path consists of an odd parity bit, a control bit, and two 4-bit symbols. Refer to section 3.3, the Configuration Switch, for more information. Symbol Pin Ý I/O Description AIP 6 O PHY Port A Indicate Parity: A TTL output signal representing odd parity for the 10-bit wide Port A Indicate signals (AIP, AIC, and AIDk7:0l). AIC 7 O PHY Port A Indicate Control: TTL output signal indicating that the two 4-bit symbols (AIDk7:4l and AIDk3:0l) are either control symbols (AIC e 1) or data symbols (AIC e 0). AID7 AID6 AID5 AID4 8 9 10 13 O PHY Port A Indicate Data: TTL output signals representing the first 4-bit data/control symbol. AID3 AID2 AID1 AID0 14 15 16 17 O BRP 70 I PHY Port B Request Parity: A TTL input signal representing odd parity for the 10-bit wide Port A Request signals (BRP, BRC, and BRDk7:0l). BRC 69 I PHY Port B Request Control: A TTL input signal indicating that the two 4-bit symbols (BRDk7:4l and BRDk3:0l) are either control symbols (BRC e 1) or data symbols (BRC e 0). BRD7 BRD6 BRD5 BRD4 68 67 66 63 I PHY Port B Request Data: TTL input signals representing the first 4-bit data/control symbol. BRD3 BRD2 BRD1 BRD0 62 61 60 59 I AID7 is the most significant bit and AID4 is the least significant bit of the first symbol. PHY Port A Indicate Data: TTL output signals representing the second 4-bit data/control symbol. AID3 is the most significant bit and AID0 is the least significant bit of the second symbol. BRD7 is the most significant bit and BRD4 is the least significant bit of the first symbol. PHY Port B Request Data: TTL input signals representing the second 4-bit data/control symbol. BRD3 is the most significant bit and BRD0 is the least significant bit of the second symbol. 97 6.0 Signal Descriptions (Continued) CONTROL BUS INTERFACE The Control Bus Interface consists of I/O signals used to connect the PLAYER a device to Station Management (SMT). The Control Bus is an asynchronous interface between the PLAYER a device and a general purpose microprocessor or other controller. It provides access to 64 8-bit internal registers. In the PLAYER a device the Control Bus address range has been expanded by 1-bit to 6 bits of address space. Symbol Pin Ý I/O E CE 73 I Control Enable: An active-low, TTL, input signal which enables the Control Bus port for a read or write cycle. R/ E W, CBAk5:0l, CBP, and CBDk7:0l must be valid at the time E CE is low. Description R/ E W 72 I Read/ E Write: A TTL input signal which indicates a read Control Bus cycle (R/ E W e 1), or a write Control Bus cycle (R/ E W e 0). E ACK 75 O E Acknowledge: An active low, TTL, open drain output signal which indicates the completion of a read or write cycle. During a read cycle, CBDk7:0l are valid as long as E ACK is low ( E ACK e 0). During a write cycle, a microprocessor must hold CBDk7:0l valid until E ACK becomes low. Once E ACK is low, it will remain low as long as E CE remains low ( E CE e 0). E INT 74 O E Interrupt: An active low, open drain, TTL, output signal indicating that an interrupt condition has occurred. The Interrupt Condition Register (ICR) should be read in order to find out the source of the interrupt. Interrupts can be masked through the use of the Interrupt Condition Mask Register (ICMR). CBA5 CBA4 CBA3 CBA2 CBA1 CBA0 83 82 81 80 77 76 I Control Bus Address: TTL input signals used to select the address of the register to be read or written. CBP 96 I/O CBA5 is the most significant bit (MSB) and CBA0 is the least significant bit (LSB) of the address signals. Control Bus Parity: A bidirectional, TTL signal representing odd parity for the Control Bus data (CBDk7:0l). During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. If incorrect parity is used during a write cycle, the PLAYER a device will inhibit the write cycle and set the Control Bus Data Parity Error (CPE) bit in the Interrupt Condition Register (ICR). CBD7 CBD6 CBD5 CBD4 CBD3 CBD2 CBD1 CBD0 95 94 93 92 91 90 89 86 I/O Control Bus Data: Bidirectional, TTL signals containing the data to be read from or written to a register. During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. 98 6.0 Signal Descriptions (Continued) CLOCK INTERFACE The Clock Interface consists of 12.5 MHz and 25 MHz clocks supplied by the PLAYER a device as well as reference and feedback inputs. Symbol Pin Ý I/O Description LBC1 LBC2 LBC3 LBC4 LBC5 4 3 2 1 100 O Local Byte Clock: TTL compatible, 12.5 MHz, 50% duty cycle clock outputs which are phase locked to a crystal oscillator or reference signal. The PHÐSEL input determines whether the five phase outputs are phase offset by 8 ns or 16 ns. PHÐSEL 22 I Phase Select: TTL compatible input used to select either a 8 ns or 16 ns phase offset between the 5 local byte clocks (LBC’s). The LBC’s are phase offset 8 ns apart when PHÐSEL is at a logic LOW level and 16 ns apart when at a logic HI level. FBKÐIN 25 I Feedback Input: TTL compatible input for use as the PLL’s phase comparator feedback input to close the Phase Locked Loop. This input is intended to be driven from one of the Local Byte Clocks (LBC’s) from the same PLAYER a device. LSC 99 O Local Symbol Clock: TTL compatible 25 MHz output for driving the MACSI or BMAC devices. This output’s negative phase transition is aligned with the LBC1 output transitions and has a 40% HI and 60% LOW duty cycle. CLK16 5 O Clock 16/32: TTL compatible clock with a selectable frequency of approximately 15.625 MHz or 31.25 MHz. The frequency can be selected using the Clock Select (CLKSEL) bit of the Mode 2 Register (MODE2). Note: No glitches appear at the output when switching frequencies. XTALÐIN 27 I External Crystal Oscillator Input: This input in conjunction with the XTALÐOUT output, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . This input is selected when the REFÐSEL input is at a logic LOW level. When not being used, this input should be tied to ground. XTALÐOUT 26 O External Crystal Oscillator Output: This output in conjunction with the XTALÐIN input, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . REFÐIN 24 I Reference Input: TTL compatible input for use as the PLL’s phase comparator reference frequency. This input is for use in dual attach station or concentrator configurations where there are multiple PLAYER a devices at a given site requiring synchronization. This input is selected when the REFÐSEL input is at a logic HI level. REFÐSEL 23 I Reference Select: TTL compatible input which selects either the crystal oscillator inputs XTALÐIN and XTALÐOUT or the REFÐIN inputs as the reference frequency inputs for the PLL. The crystal oscillator inputs are selected when REFÐSEL is at a logic LOW level and the REFÐIN input is selected as the reference when REFÐSEL is at a logic HI level. 99 6.0 Signal Descriptions (Continued) MISCELLANEOUS INTERFACE The Miscellaneous Interface consist of a reset signal and user definable enable signals. Symbol Pin Ý I/O E RST Description 71 I Reset: An active low, TTL, input signal which clears all registers. The signal must be kept asserted for a minimum amount of time. Once the E RST signal is asserted, the PLAYER a device should be allowed the specified amount of time to reset internal logic. Note that bit zero of the Mode Register will be set to zero (i.e. Stop Mode). See section 4.2, Stop Mode of Operation for more information EP0 41 O User Definable Enable Pin 0: A TTL output signal allowing control of external logic through the Control Bus Interface. EP0 is asserted/deasserted through Enable Bit 0 (EB0) of the User Definable Register (UDR). When Enable Bit 0 is set to zero, EP0 is deasserted. When Enable Bit 0 is set to one, EP0 is asserted. EP1 43 O User Definable Enable Pin 1: A TTL output signal allowing control of external logic through the Control Bus Interface. EP1 is asserted/deasserted through Enable Bit 1 (EB1) of the User Definable Register (UDR). When Enable Bit 1 is set to zero, EP1 is deasserted. When Enable Bit 1 is set to one, EP1 is asserted. 100 6.0 Signal Descriptions (Continued) POWER AND GROUND All power pins should be connected to a single a 5V power supply using the recommended filtering. All ground pins should be connected to a common 0V ground supply. Bypassing and filtering requirements are given in a separate User Information Document. Symbol Pin Ý VCCÐANALOG 20 I/O Power: Positive 5V power supply for the Clock Generation Module VCO. Description GNDÐANALOG 21 Ground: Power supply return for the Clock Generation Module VCO. VCCÐCORE 88 Power: Positive 5V power supply for the core PLAYER section logic gates. GNDÐCORE 87 Ground: Power supply return for the core PLAYER section logic gates. VCCÐECL 32, 37, 45, 56 Power: Positive 5V power supply for the PLAYER a device’s ECL logic gates. GNDÐECL 38, 46, 55 Ground: Power supply return for the PLAYER a device’s ECL logic gates. VCCÐESD 28 Power: Positive 5V power supply for the PLAYER a device’s ESD protection circuitry. GNDÐESD 29 Ground: Power supply return for the PLAYER a device’s ESD protection circuitry. VCCÐIO 11, 65, 79, 98 Power: Positive 5V power supply for the input/output buffers. GNDÐIO 12, 64, 78, 97 Ground: Power supply return for the input/output buffers. SPECIAL CONNECT PINS These are pins that have special connection requirements. No Connect (N/C) pins should not be connected to anything. This means not to power, not to ground, and not to each other. ReservedÐ0 (RESÐ0) pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. ReservedÐ1 (RESÐ1) pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. Symbol Pin Ý N/C 49, 53, 54 I/O No Connect: Pins should not be connected to anything. This means not to power, not to ground, and not to each other. Description RESÐ0 18, 19, 48, 50, 51, 52, 57, 58, 84 Reserved 0: Pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. RESÐ1 85 Reserved 1: Pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. 101 6.0 Signal Descriptions (Continued) 6.3 DP83257VF SIGNAL DESCRIPTIONS The pin descriptions for the DP83257VF are divided into five functional interfaces; PMD Interface, PHY Port Interface, Control Bus Interface, Clock Interface, and Miscellaneous Interface. For a Pinout Summary List, refer to Table 8-3 and Figure 8-3 , DP83257VF 160-Pin JEDEC Metric PQFP Pinout. PMD INTERFACE The PMD Interface consists of I/O signals used to connect the PLAYER a device to the Physical Medium Dependant (PMD) sublayer. The DP83257 PLAYER a device actually has two PMD interfaces. The Primary PMD Interface and the Alternate PMD Interface. The Primary PMD Interface should be used for all PMD implementations that do not require an external scrambler/descrambler function, clock recovery function, or clock generation function, such as a Fiber Optic or Shielded Twisted Pair (SDDI) PMD. The second, Alternate PMD Interface can be used to support Unshielded Twisted Pair (UTP) PMDs that require external scrambling, with no external clock recovery or clock generation functions required. Section 3.8 describes how the PLAYER a can be connected to the PMD and how the Alternate PMD can be enabled. Note that when the Alternate PMD Interface is not being used, the pins that make up the interface must be connected in the specific way described in the following Alternate PMD Interface table. Primary PMD Interface Symbol Pin Ý I/O PMID a PMIDb 62 61 I PMD Indicate Data: Differential, 100k ECL, 125 Mbps serial data input signals from the PMD Receiver into the Clock Recovery Module (CRM) of the PLAYER a . Description PMRD a PMRDb 54 53 O PMD Request Data: Differential, 100k ECL, 125 Mbps serial data output signals to the PMD transmitter. SD a SDb 60 59 I Signal Detect: Differential 100k ECL input signals from the PMD receiver indicating that a signal is being received by the PMD receiver. TEL 74 I PMD Transmitter Enable Level: A TTL input signal to select the PMD transmitter Enable (TXE) signal level. TXE 73 O PMD Transmitter Enable: A TTL output signal to enable/disable the PMD transmitter. The output level of the TXE pin is determined by three parameters: the Transmit Enable (TE) bit in the Mode Register, the TM2–TM0 bits in the Current Transmit State Register, and the input to the TEL pin. The following rules summarize the output of the TXE pin: 1. If TE e 0 and TEL e GND, then TXE e VCC 2. If TE e 0 and TEL e VCC, then TXE e GND 3. If TE e 1 and OTM and TEL e GND, then TXE e VCC 4. If TE e 1 and OTM and TEL e VCC, then TXE e GND 5. If TE e 1 and not OTM and TEL e GND, then TXE e GND 6. If TE e 1 and not OTM and TEL e VCC, then TXE e VCC 102 6.0 Signal Descriptions (Continued) Alternate PMD Interface Pin Ý I/O PMID a PMIDb Symbol 62 61 I PMD Indicate Data: Differential, 100k ECL, 125 Mbps serial data input signals from the PMD Receiver into the Clock Recovery Module (CRM) of the PLAYER a . Description RXCÐOUT a RXCÐOUTb 56 55 O Recovered Clock Out: 125 MHz clock recovered by the Clock Recovery Module (CRM) from the PMID data input. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used they should be left Not Connected (N/C). RXDÐOUT a RXDÐOUTb 83 82 O Recovered Data Out: 125 Mbps data recovered by the Clock Recovery Module (CRM) from the PMID data input. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used they should be left Not Connected (N/C). RXCÐIN a RXCÐINb 76 75 I Receive Clock In: Clock inputs to the Player section of the PLAYER a . These inputs must be synchronized with the RXDÐIN inputs. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used, pin 76 should be left Not Connected (N/C) and pin 75 should be connected directly to ground (ReservedÐ0). RXDÐIN a RXDÐINb 78 77 I Receive Data In: Data inputs to the Player section of the PLAYER a . These inputs must be synchronized with the RXCÐIN inputs. These signals are only active when the Alternate PMD Enable (APMDEN) bit of the Alternate PMD Register (APMDREG) is set to a 1 and are off by default after Reset. When these two pins are not used, pin 78 should be left Not Connected (N/C) and pin 77 should be connected directly to ground (ReservedÐ0). PMRD a PMRDb 54 53 O PMD Request Data: Differential, 100k ECL, 125 Mbps serial data output signals to the PMD transmitter. TXC a TXCb 51 50 O Transmit Clock: 125 MHz, 100k ECL compatible differential outputs synchronized to the outgoing PMRD data. These signals can be enabled using the Transmit Clock Enable (TXCE) bit in the Clock Generation Module Register (CGMREG). When these two pins are not used they should be left Not Connected (N/C). SD a SDb 60 59 I Signal Detect: Differential, 100k ECL, input signals from the PMD receiver indicating that a signal is being received by the PMD receiver. TEL 74 I PMD Transmitter Enable Level: A TTL input signal to select the PMD transmitter Enable (TXE) signal level. TXE 73 O PMD Transmitter Enable: A TTL output signal to enable/disable the PMD transmitter. The output level of the TXE pin is determined by three parameters: the Transmit Enable (TE) bit in the Mode Register, the TM2–TM0 bits in the Current Transmit State Register, and the input to the TEL pin. The following rules summarize the output of the TXE pin: 1. If TE e 0 and TEL e GND, then TXE e VCC 2. If TE e 0 and TEL e VCC, then TXE e GND 3. If TE e 1 and OTM and TEL e GND, then TXE e VCC 4. If TE e 1 and OTM and TEL e VCC, then TXE e GND 5. If TE e 1 and not OTM and TEL e GND, then TXE e GND 6. If TE e 1 and not OTM and TEL e VCC, then TXE e VCC 103 6.0 Signal Descriptions (Continued) PHY PORT INTERFACE The PHY Port Interface consists of I/O signals used to connect the PLAYER a device to the Media Access Control (MAC) sublayer or other PLAYER a device. The DP83257 Device has two PHY Port Interfaces. The AÐRequest and AÐIndicate paths from one PHY Port Interface and the BÐRequest and BÐIndicate paths from the second PHY Port Interface. Each path consists of an odd parity bit, a control bit, and two 4-bit symbols. Refer to section 3.3, the Configuration Switch, for more information. Symbol Pin Ý I/O Description AIP 6 O PHY Port A Indicate Parity: A TTL output signal representing odd parity for the 10-bit wide Port A Indicate signals (AIP, AIC, and AIDk7:0l). AIC 8 O PHY Port A Indicate Control: A TTL output signal indicating that the two 4-bit symbols (AIDk7:4l and AIDk3:0l) are either control symbols (AIC e 1) or data symbols (AIC e 0). AID7 AID6 AID5 AID4 10 12 14 18 O PHY Port A Indicate Data: TTL output signals representing the first 4-bit data/control symbol. AID3 AID2 AID1 AID0 20 22 24 26 O ARP 7 I PHY Port A Request Parity: A TTL input signal representing odd parity for the 10-bit wide Port A Request signals (ARP, ARC, and ARDk7:0l). ARC 9 I PHY Port A Request Control: A TTL input signal indicating that the two 4-bit symbols (ARDk7:4l and ARDk3:0l) are either control symbols (ARC e 1) or data symbols (ARC e 0). ARD7 ARD6 ARD5 ARD4 11 13 15 19 I PHY Port A Request Data: TTL input signals representing the first 4-bit data/control symbol. ARD3 ARD2 ARD1 ARD0 21 23 25 27 I BIP 114 O PHY Port B Indicate Parity: A TTL output signal representing odd parity for the 10-bit wide Port A Indicate signals (BIP, BIC, and BIDk7:0l). BIC 112 O PHY Port B Indicate Control: A TTL output signal indicating that the two 4-bit symbols (BIDk7:4l and BIDk3:0l) are either control symbols (BIC e 1) or data symbols (BIC e 0). BID7 BID6 BID5 BID4 110 108 106 102 O PHY Port B Indicate Data: TTL output signals representing the first 4-bit data/control symbol. BID3 BID2 BID1 BID0 100 98 96 94 O BRP 115 I PHY Port B Request Parity: A TTL input signal representing odd parity for the 10-bit wide Port A Request signals (BRP, BRC, and BRDk7:0l). BRC 113 I PHY Port B Request Control: A TTL input signal indicating that the two 4-bit symbols (BRDk7:4l and BRDk3:0l) are either control symbols (BRC e 1) or data symbols (BRC e 0). AID7 is the most significant bit and AID4 is the least significant bit of the first symbol. PHY Port A Indicate Data: TTL output signals representing the second 4-bit data/control symbol. AID3 is the most significant bit and AID0 is the least significant bit of the second symbol. ARD7 is the most significant bit and ARD4 is the least significant bit of the first symbol. PHY Port A Request Data: TTL input signals representing the second 4-bit data/control symbol. ARD3 is the most significant bit and ARD0 is the least significant bit of the second symbol. BID7 is the most significant bit and BID4 is the least significant bit of the first symbol. PHY Port B Indicate Data: TTL output signals representing the second 4-bit data/control symbol. BID3 is the most significant bit and BID0 is the least significant bit of the second symbol. 104 6.0 Signal Descriptions (Continued) Pin Ý I/O BRD7 BRD6 BRD5 BRD4 Symbol 111 109 107 103 I BRD3 BRD2 BRD1 BRD0 101 99 97 95 I Description PHY Port B Request Data: TTL input signals representing the first 4-bit data/control symbol. BRD7 is the most significant bit and BRD4 is the least significant bit of the first symbol. PHY Port B Request Data: TTL input signals representing the second 4-bit data/control symbol. BRD3 is the most significant bit and BRD0 is the least significant bit of the second symbol. 105 6.0 Signal Descriptions (Continued) CONTROL BUS INTERFACE The Control Bus Interface consists of I/O signals used to connect the PLAYER a device to Station Management (SMT). The Control Bus is an asynchronous interface between the PLAYER a device and a general purpose microprocessor or other controller. It provides access to 64 8-bit internal registers. In the PLAYER a device the Control Bus address range has been expanded by 1-bit to 6 bits of address space. Symbol Pin Ý I/O E CE 118 I Control Enable: An active-low, TTL, input signal which enables the Control Bus port for a read or write cycle. R/ E W, CBAk5:0l, CBP, and CBDk7:0l must be valid at the time E CE is low. Description R/ E W 117 I Read/ E Write: A TTL input signal which indicates a read Control Bus cycle (R/ E W e 1), or a write Control Bus cycle (R/ E W e 0). E ACK 120 O E Acknowledge: An active low, TTL, open drain output signal which indicates the completion of a read or write cycle. During a read cycle, CBDk7:0l are valid as long as E ACK is low ( E ACK e 0). During a write cycle, a microprocessor must hold CBDk7:0l valid until E ACK becomes low. Once E ACK is low, it will remain low as long as E CE remains low ( E CE e 0). E INT 119 O E Interrupt: An active low, open drain, TTL, output signal indicating that an interrupt condition has occurred. The Interrupt Condition Register (ICR) should be read in order to find out the source of the interrupt. Interrupts can be masked through the use of the Interrupt Condition Mask Register (ICMR). CBA5 CBA4 CBA3 CBA2 CBA1 CBA0 135 134 133 132 129 128 I Control Bus Address: TTL input signals used to select the address of the register to be read or written. CBP 148 I/O CBA5 is the most significant bit (MSB) and CBA0 is the least significant bit (LSB) of the address signals. Control Bus Parity: A bidirectional, TTL signal representing odd parity for the Control Bus data (CBDl7:0l). During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. If incorrect parity is used during a write cycle, the PLAYER a device will inhibit the write cycle and set the Control Bus Data Parity Error (CPE) bit in the Interrupt Condition Register (ICR). CBD7 CBD6 CBD5 CBD4 CBD3 CBD2 CBD1 CBD0 147 146 145 144 143 142 141 138 I/O Control Bus Data: Bidirectional, TTL signals containing the data to be read from or written to a register. During a read cycle, the signal is held valid by the PLAYER a device as long as E ACK is low. During a write cycle, the signal must be valid when E CE is low, and must be held valid until E ACK becomes low. 106 6.0 Signal Descriptions (Continued) CLOCK INTERFACE The Clock Interface consists of 12.5 MHz and 25 MHz clocks supplied by the PLAYER a device as well as reference and feedback inputs. Symbol Pin Ý I/O LBC1 LBC2 LBC3 LBC4 LBC5 4 3 2 1 160 O Local Byte Clock: TTL compatible, 12.5 MHz, 50% duty cycle clock outputs which are phase locked to a crystal oscillator or reference signal. The PHÐSEL input determines whether the five phase outputs are phase offset by 8 ns or 16 ns. PHÐSEL 34 I Phase Select: TTL compatible input used to select either a 8 ns or 16 ns phase offset between the 5 local byte clocks (LBC’s). The LBC’s are phase offset 8 ns apart when PHÐSEL is at a logic LOW level and 16 ns apart when at a logic HI level. FBKÐIN 37 I Feedback Input: TTL compatible input for use as the PLL’s phase comparator feedback input to close the Phase Locked Loop. This input is intended to be driven from one of the Local Byte Clocks (LBC’s) from the same PLAYER a device. LSC 159 O Local Symbol Clock: TTL compatible 25 MHz output for driving the MACSI or BMAC devices. This output’s negative phase transition is aligned with the LBC1 output transitions and has a 40% HI and 60% LOW duty cycle. 5 O Clock 16/32: TTL compatible clock with a selectable frequency of approximately 15.625 MHz or 31.25 MHz. The frequency can be selected using the Clock Select (CLKSEL) bit of the Mode 2 Register (MODE2). CLK16 Description Note: No glitches appear at the output when switching frequencies. XTALÐIN 46 I External Crystal Oscillator Input: This input in conjunction with the XTALÐOUT output, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . This input is selected when the REFÐSEL input is at a logic LOW level. When not being used, this input should be tied to ground. XTALÐOUT 45 O External Crystal Oscillator Output: This output in conjunction with the XTALÐIN input, is designed for use of an external crystal oscillator network as the frequency reference for the clock generation module’s internal VCO. A diagram of the required circuit, which includes only a 12.5 MHz crystal and 2 loading capacitors, is shown in Figure 3-19 . REFÐIN 36 I Reference Input: TTL compatible input for use as the PLL’s phase comparator reference frequency. This input is for use in dual attach station or concentrator configurations where there are multiple PLAYER a devices at a given site requiring synchronization. REFÐSEL 35 I This input is selected when the REFÐSEL input is at a logic HI level. Reference Select: TTL compatible input which selects either the crystal oscillator inputs XTALÐIN and XTALÐOUT or the REFÐIN inputs as the reference frequency inputs for the PLL. The crystal oscillator inputs are selected when REFÐSEL is at a logic LOW level and the REFÐIN input is selected as the reference when REFÐSEL is at a logic HI level. LPFLTR 49 O Loop Filter: This is a diagnostic output that allows monitoring of the clock generation module’s filter node. This output is disabled by default and does not need to be connected to any external device. It can be enabled using the FLTREN bit of the Clock generation module register (CGMREG). Note: In normal operation this pin should be disabled. 107 6.0 Signal Descriptions (Continued) MISCELLANEOUS INTERFACE The Miscellaneous Interface consist of a reset signal, user definable sense signals, and user definable enable signals. Symbol Pin Ý I/O E RST Description 116 I Reset: An active low, TTL, input signal which clears all registers. The signal must be kept asserted for a minimum amount of time. Once the E RST signal is asserted, the PLAYER a device should be allowed the specified amount of time to reset internal logic. Note that bit zero of the Mode Register will be set to zero (i.e. Stop Mode). See section 4.2, Stop Mode of Operation for more information SP0 63 I User Definable Sense Pin 0: A TTL input signal from a user defined source. Sense Bit 0 (SB0) of the User Definable Register (UDR) will be set to one if the signal is asserted for a minimum of 160 ns. Once the asserted signal is latched, Sense Bit 0 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts. SP1 65 I User Definable Sense Pin 1: A TTL input signal from a user defined source. Sense Bit 1 (SB1) of the User Definable Register (UDR) will be set to one if the signal is asserted for a minimum of 160 ns. Once the asserted signal is latched, Sense Bit 1 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts. SP2 67 I User Definable Sense Pin 2: A TTL input signal from a user defined source. Sense Bit 2 (SB2) of the User Definable Register (UDR) will be set to one if the signal is asserted for a minimum of 160 ns. Once the asserted signal is latched, Sense Bit 2 can only be cleared through the Control Bus Interface, even if the signal is deasserted. This ensures that the Control Bus Interface will record the source of events which can cause interrupts. EP0 64 O User Definable Enable Pin 0: A TTL output signal allowing control of external logic through the Control Bus Interface. EP0 is asserted/deasserted through Enable Bit 0 (EB0) of the User Definable Register (UDR). When Enable Bit 0 is set to zero, EP0 is deasserted. When Enable Bit 0 is set to one, EP0 is asserted. EP1 66 O User Definable Enable Pin 1: A TTL output signal allowing control of external logic through the Control Bus Interface. EP1 is asserted/deasserted through Enable Bit 1 (EB1) of the User Definable Register (UDR). When Enable Bit 1 is set to zero, EP1 is deasserted. When Enable Bit 1 is set to one, EP1 is asserted. EP2 68 O User Definable Enable Pin 2: A TTL output signal allowing control of external logic through the Control Bus Interface. EP2 is asserted/deasserted through Enable Bit 2 (EB2) of the User Definable Register (UDR). When Enable Bit 2 is set to zero, EP2 is deasserted. When Enable Bit 2 is set to one, EP2 is asserted. CS 69 I Cascade Start: A TTL input signal used to synchronize cascaded PLAYER a devices in point-to-point applications. The signal is asserted when all of the cascaded PLAYER a devices have the Cascade Mode (CM) bit of the Mode Register (MR) set to one, and all of the Cascade Ready (CR) pins of the cascaded PLAYER a devices have been released. When Cascade Mode is not being used, this input should be tied to Ground. For further information, refer to section 4.4, Cascade Mode of Operation. CR 70 O Cascade Ready: An Open Drain output signal used to synchronize cascaded PLAYER a devices in point-to-point applications. The signal is released (i.e. an Open Drain line is released) when all the cascaded PLAYER a devices have the Cascade Mode (CM) bit of the Mode Register (MR) is set to one and a JK symbol pair has been received. When Cascade Mode is not being used, this input should be left Not Connected (N/C). For further information, refer to section 4.4, Cascade Mode of Operation. 108 6.0 Signal Descriptions (Continued) POWER AND GROUND All power pins should be connected to a single a 5V power supply using the recommended filtering. All ground pins should be connected to a common 0V ground supply. Bypassing and filtering requirements are given in a separate User Information Document. Symbol Pin Ý VCCÐANALOG 32 I/O Description Power: Positive 5V power supply for the PLAYER a device’s CGM VCO. GNDÐANALOG 33 Ground: Power supply return for the PLAYER a device’s CGM VCO. VCCÐCORE 140 Power: Positive 5V power supply for the core PLAYER logic gates. GNDÐCORE 139 Ground: Power supply return for the core PLAYER logic gates. VCCÐECL 52, 57, 71, 89 Power: Positive 5V power supply for the PLAYER a device’s ECL logic gates. GNDÐECL 58, 72, 88 Ground: Power supply return for the PLAYER a device’s ECL logic gates. VCCÐESD 47 GNDÐESD 48 Power: Positive 5V power supply for the PLAYER a device’s ESD protection circuitry. Ground: Power supply return for the PLAYER a device’s ESD protection circuitry. VCCÐIO 16, 105, 131, 158 Power: Positive 5V power supply for the input/output buffers. GNDÐIO 17, 104, 130, 157 Ground: Power supply return for the input/output buffers. SPECIAL CONNECT PINS These are pins that have special connection requirements. No Connect (N/C) pins should not be connected to anything. This means not to power, not to ground, and not to each other. ReservedÐ0 (RESÐ0) pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. ReservedÐ1 (RESÐ1) pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. Symbol Pin Ý I/O Description N/C 38, 39, 40, 41, 42, 43, 44, 79, 80, 81, 87, 121, 122, 123, 124, 125, 126, 127, 149, 150, 151, 152, 153,154, 155, 156 No Connect: Pins should not be connected to anything. This means not to power, not to ground, and not to each other. RESÐ0 28, 29, 30, 31, 84, 85, 86, 90, 91, 92, 93, 136 Reserved 0: Pins must be connected to ground. These pins are not used to supply device power so they do not need to be filtered or bypassed. RESÐ1 137 Reserved 1: Pins must be connected to power. These pins are not used to supply device power so they do not need to be filtered or bypassed. 109 7.0 Electrical Characteristics 7.1 ABSOLUTE MAXIMUM RATINGS Max Units VCC Symbol Supply Voltage Parameter Conditions b 0.5 Min Typ 7.0 V DCIN Input Voltage b 0.5 VCC a 0.5 V DCOUT Output Voltage b 0.5 VCC a 0.5 V 0.3 V VCCÐESD to other VCC Maximum Voltage Differential Storage Temperature ECL b 65 Signal Output Current ESD Protection 150 §C b 50 mA 2000 V 7.2 RECOMMENDED OPERATING CONDITIONS Symbol Parameter VCC Supply Voltage TA Operating Temperature FREF Conditions Min Reference Input Frequency Max Units 4.75 Typ 5.25 V 0 70 §C 12.5 – 50 ppm 12.5 a 50 ppm MHz 12.5 7.3 RECOMMENDED EXTERNAL COMPONENTS Symbol XTAL Parameter Conditions Min Typ Max Units Crystal Specifications Center Frequency 12.5 Frequency Calibration Frequency Stability Over Temperature Aging Less Than MHz b 10 10 ppm b 10 10 ppm 5 ppm b5 Recommended Power Supply Bypassing Capacitor Value 0.1 mF Note: Capacitors should be placed between each supply pair as close to the device as possible. 7.4 DC ELECTRICAL CHARACTERISTICS The DC characteristics are specified over the Recommended Operating Conditions, unless otherwise specified. DC Electrical Characteristics for All TTL-Compatible Inputs The following signals are covered: PHY Port Request Signals (ARD, ARC, ARP, BRD, BRC, BRP), Phase Select (PHÐSEL), Reference Select (REFÐSEL), Sense Pins (SP), Cascade Start (CS), PMD Transmitter Enable Level (TEL), Device Reset ( E RST), and Control Bus Interface Inputs (R/ E W, E CE, CBA). Symbol Parameter Conditions Min Typ Max Units 0.8 V VIH Input High Voltage 2.0 VIL Input Low Voltage VIC Input Clamp Voltage IIN e b18 mA b 1.5 V IIL Input Low Current VIN e GND b 10 mA IIH Input High Current VIN e VCC a 10 mA 110 V 7.0 Electrical Characteristics (Continued) DC Electrical Characteristics for All TTL-Compatible Non-TRI-STATE Outputs The following signals are covered: Clock 16/32 (CLK16), Enable Pins (EP), and PMD Transmitter Enable (TXE). Parameter Conditions Min VOH Symbol Output High Voltage IOH e b2 mA VCC b 0.5 VOL Output Low Voltage IOL e 4 mA Typ Max Units V 0.5 V Max Units DC Electrical Characteristics for All TTL-Compatible TRI-STATE Outputs The following signals are covered: PHY Port Indicate Signals (AID, AIC, AIP, BID, BIC, BIP). Symbol Parameter Conditions Min Output High Voltage IOH e b2 mA VCC b 0.5 VOL Output Low Voltage IOL e 4 mA 0.5 V IOZ3 TRI-STATE Leakage VOUT e VCC (Note 1) 60 mA IOZ4 TRI-STATE Leakage VOUT e VGND (Note 1) b 500 mA Max Units VOH Typ V Note 1: Output buffer has a p-channel pullup device. DC Electrical Characteristics for All TTL-Compatible Input/Outputs The following signals are covered: Control Bus Interface I/O (CBD, CBP). Symbol Parameter VIH Input High Voltage VIL Input Low Voltage Conditions Min Typ 2.0 V 0.8 V VIC Input Clamp Voltage IIN e b18 mA IIL Input Low Current VIN e GND IIH Input High Current VIN e VCC VOH Output High Voltage IOH e b2 mA VOL Output Low Voltage IOL e 4 mA 0.5 V IOZ1 TRI-STATE Leakage VOUT e VCC 10 mA IOZ2 TRI-STATE Leakage VOUT e VGND b 10 mA 111 b 1.5 V b 10 mA a 10 mA VCC b 0.5 V 7.0 Electrical Characteristics (Continued) DC Electrical Characteristics for All FDDI Clock Outputs The following signals are covered: Local Byte Clocks (LBC1 – LBC5), and Local Symbol Clock (LSC). These outputs are designed to drive capacitive loads from 20 pF to 60 pF. Symbol Parameter Conditions Min VOH Output High Voltage IOH e b400 mA VCC b 2 VOL Output Low Voltage IOL e 8 mA Typ Max Units V 0.5 V DC Electrical Characteristics for All Clock Reference Inputs The following signals are covered: Reference In (REFÐIN) and Feedback In (FBKÐIN). Symbol Parameter Max Units 0.8 V IIN e b18 mA b 1.5 V Input Low Current VIN e GND b 10 mA Input High Current VIN e VCC a 10 mA VIH Input High Voltage VIL Input Low Voltage VIC Input Clamp Voltage IIL IIH Conditions Min Typ 2.0 V DC Electrical Characteristics for Crystal Inputs and Outputs The following signals are covered: Crystal In (XTALÐIN) and Crystal Out (XTALÐOUT). Symbol Parameter Conditions IOL Output Low Current VOUT e 1V (Note A) IOH Output High Current VTH Min Typ Max Units 4 mA VOUT e VCC b 1V (Note A) b4 mA Small Signal Gain XTALÐIN e 100 mV Centered about VTH (Note A) 45 Input Threshold Voltage (Note A) 2.2 V XTALÐIN to XTALÐOUT Delay (Note A) 7.0 ns Output Impedance (Note A) 270 X Internal Resistor Variation (Note A) 10 kX Note A: This parameter is presented as a typical value to provide enough information to design an appropriate crystal network. DC Electrical Characteristics for All Open Drain Outputs The following signals are covered: Interrupt ( E INT), Acknowledge ( E ACK), and Cascade Ready (CR). Parameter Conditions VOL Symbol Output Low Voltage IOL e 8 mA 0.5 V IOZ TRI-STATE Leakage VOUT e VCC 10 mA 112 Min Typ Max Units 7.0 Electrical Characteristics (Continued) DC Electrical Characteristics for All 100K ECL Compatible Inputs The following signals are covered: PMD Indicate Data (PMID), Receive Clock In (RXCÐIN), Receive Data In (RXDÐIN), and Signal Detect (SD). Symbol Parameter Conditions VDIFF Input Voltage Differential (Note 1) VCM Common Mode Voltage VDIFF e 300 mV (Notes 1, 2) IIN Input Current VIN e VCC or GND Min Typ Max 150 Units mV VCC b 2.0 VCC b 0.5 V b 200 200 mA Note 1: Both inputs of each differential pair are tested together. These specifications guarantee that the inputs are compatible with standard 100K ECL voltage level outputs. Note 2: VCM is measured from the crossover point of the 300 mV differential test input. DC Electrical Characteristics for 100K ECL Compatible Outputs The following signals are covered: PMD Request Data (PMRD) and Transmit Clock (TXC). Parameter Conditions Min Max Units VOH Symbol Output High Voltage VCC b 1.025 VCC b 0.880 V VOL Output Low Voltage VIL e VCC b 1.810 VIH e VCC b 0.880 Typ VCC b 1.810 VCC b 1.620 V DC Electrical Characteristics for Alternate PMD ECL Outputs The following signals are covered: Receive Clock Out (RXCÐOUT) and Receive Data Out (RXDÐOUT). Parameter Conditions Min Max Units VOH Symbol Output High Voltage VCC b 1.155 VCC b 0.880 V VOL Output Low Voltage VIL e VCC b 1.810 VIH e VCC b 0.880 (Note 3) Typ VCC b 1.810 VCC b 1.550 V Note 3: It is recommended that RXCÐOUT a and RXCÐOUT b always be used together as a differential pair. It is recommended that RXDÐOUT a and RXDÐOUT b always be used together as a differential pair. Supply Current Electrical Characteristics Symbol Parameter Conditions Min Typ Max Units 350* mA ICC Total Supply LBC1 e 12.5 MHz ECLÐICC ECL Supply Current LBC1 e 12.5 MHz 200* mA ANALOGÐICC ANALOG Supply Current LBC1 e 12.5 MHz 20* mA *Note: The PLAYER a device has multiple pairs of differential ECL outputs that need to be terminated. The additional current needed for this termination is not included in the PLAYER a ’s total supply current, but can be calculated as follows: VOHÐmax e VCC b 0.88V VOLÐmax e VCC b 1.62V Since the outputs are differential, the average output level is VCC b 1.25V. The test load per output is 50X at VCC b 2V, therefore the external load current through the 50X resistor is: ILOAD e [(VCC b 1.25) b (VCC b 2)]/50 e 0.015A e 15 mA As a result, the termination for each pair of active ECL outputs typically consumes 30 mA, time averaged. 113 7.0 Electrical Characteristics (Continued) 7.5 AC ELECTRICAL CHARACTERISTICS The AC Electrical characteristics are specified over the Recommended Operating Conditions, unless otherwise specified. AC Characteristics for the Control Bus Interface The following signals are covered: Control Bus Interface (R/ E W, E CE, E INT, E ACK, CBA, CBD, and CBP). Symbol Descriptions Min Max Units T1 CE Setup to LBC 15 T2 LBC Period 80 T3 LBC1 to ACK Low T4 CE Low to ACK Low T5 LBC1 Low to CBD(7–0) and CBP Valid T6 LBC1 to CBD(7–0) and CBP Active T7 CE Low to CBD(7–0) and CBP Active 225 475 T8 CE Low to CBD(7–0) and CBP Valid 265 515 ns T9 LBC Pulse Width High 35 45 ns T10 LBC Pulse Width Low 35 T11 CE High to ACK High T12 R/W, CBA(5–0), CBD(7–0) and CBP Setup to CE Low 5 ns T13 CE High to R/W, CBA(5–0), CBD(7–0) and CBP Hold Time 0 ns T14 R/W, CBA(5–0), CBD(7–0) and CBP to LBC1 Setup Time 20 ns T15 ACK Low to CE High Lead Time 0 ns T16 CE Minimum Pulse Width High 20 T17 CE High to CBD(7–0) and CBP TRI-STATE T18 ACK High to CE Low 0 ns T19 CBD(7–0) Valid to ACK Low Setup 20 ns T20a LBC1 to R/W Hold Time 10 ns T20b LBC1 to CBA Hold Time 10 ns T20c LBC1 to CBD and CBP Hold Time 20 ns T21 LBC1 to INT Low T22 LBC1 to EP Change 290 T1 a (3 * T2) a T3 T4 (max) T1 a (6 * T2) a T3 T7 (min) T1 a (2 * T2) a T6 T7 (max) T1 a (5 * T2) a T6 T8 (min) T1 a (2 * T2) a T9 a T5 T8 (max) T1 a (5 * T2) a T9 a T5 ns 45 ns 540 ns 60 ns 5 Note: Min/Max numbers are based on T2 e 80 ns and T9 e T10 e 40 ns. 114 ns ns 45 ns 45 ns ns 55 5 Asynchronous Definitions T4 (min) ns ns 55 ns 25 ns 7.0 Electrical Characteristics (Continued) TL/F/11708 – 29 FIGURE 7-1. Asynchronous Control Bus Write Cycle Timing TL/F/11708 – 30 FIGURE 7-2. Asynchronous Control Bus Read Cycle Timing 115 7.0 Electrical Characteristics (Continued) TL/F/11708 – 31 FIGURE 7-3. Control Bus Synchronous Writes TL/F/11708 – 32 FIGURE 7-4. Control Bus Synchronous Reads TL/F/11708 – 50 FIGURE 7-5. Control Bus Interrupt Timing 116 7.0 Electrical Characteristics (Continued) AC Characteristics for the Clock Interface Signals (Timing and Relationships) Symbol Parameter Min Typ Max Units TPhase1 LBC1–LBC2 Timing PHÐSEL e LOW 5.0 8 11.0 ns TPhase2 LBC1–LBC3 Timing PHÐSEL e LOW 13.0 16 19.0 ns TPhase3 LBC1–LBC4 Timing PHÐSEL e LOW 21.0 24 27.0 ns TPhase4 LBC1–LBC5 Timing PHÐSEL e LOW 29.0 32 35.0 ns TPhase1 LBC1–LBC2 Timing PHÐSEL e HIGH 45.0 48 51.0 ns TPhase2 LBC1–LBC3 Timing PHÐSEL e HIGH 13.0 16 19.0 ns TPhase3 LBC1–LBC4 Timing PHÐSEL e HIGH 61.0 64 67.0 ns TPhase4 LBC1–LBC5 Timing PHÐSEL e HIGH 29.0 32 35.0 ns TPhase5 LBC5 RisingLBC1 Falling Timing PHÐSEL e LOW or PHÐSEL e HIGH 5.0 8 12.0 ns T23 LSC Falling to LBC1 (Note 1) b3 a6 ns b2 a2 ns T24 REFÐIN to FBKÐIN Conditions In Lock Note 1: LSC loading must always be less than or equal to LBC1 loading. TL/F/11708 – 33 FIGURE 7-6. Clock Signal Relationships 117 7.0 Electrical Characteristics (Continued) TL/F/11708 – 51 FIGURE 7-7. Typical Clock Signal Relationships Based on Phase Select (PHÐSEL) Setting 118 7.0 Electrical Characteristics (Continued) AC Characteristics for the Clock Interface Signals (Periods and Pulse Widths) Symbol Parameter Conditions Min Typ Max 80 Units T2 LBC Period T9 LBC Pulse Width High 35 45 ns ns T10 LBC Pulse Width Low 35 45 ns T25 LSC Pulse Width High 12 19 ns T26 LSC Pulse Width Low 21 28 ns T27 CLK16 Period MODE2.CLKSEL e 0 T28 CLK16 Pulse Width MODE2.CLKSEL e 0 (Note 1) T27 CLK16 Period MODE2.CLKSEL e 1 T28 CLK16 Pulse Width MODE2.CLKSEL e 1 (Note 1) T29 REFÐIN Pulse Width High 64 27 32 ns 37 32 11 16 35 ns ns 21 ns 45 ns Note 1: This parameter is not tested, but is assured by correlation with characterization data. TL/F/11708 – 34 FIGURE 7-8. Clock Pulse Widths AC Characteristics for Port A Interface and Port B Interface The following signals are covered: PHY Port A (AID, AIP, AIC, ARD, ARP, ARC) and PHY Port B (BID, BIP, BIC, BRD, BRP, BRC). Max Units T30 Symbol LBC1 to Indicate Data Changes from TRI-STATE to Valid Data Parameter Conditions Min Typ 70 ns T31 LBC1 to Indicate Data Changes from Active to TRI-STATE 70 ns T32 LBC1 to Indicate Data Sustain T33 LBC1 to Valid Indicate Data T34 Request Data to LBC1 Setup Time 15 ns T35 Request Data to LBC1 Hold Time 3 ns 9 ns 45 TL/F/11708 – 35 FIGURE 7-9. PHY Port Interface Timing 119 ns 7.0 Electrical Characteristics (Continued) AC Characteristics for the PMD Interface The following signals are covered: PMD Indicate Data (PMID), Signal Detect (SD), and PMD Request Data (PMRD). Symbol Parameter Conditions Min Typ Max T36 PMID g to PMRD g Latency Looped Back through Configuration Switch. LBC1 e 12.5 MHz In Lock (Note 1) T37 SD Minimum Pulse Width T38 PMRD Rise Time (Note 2) 1.5 ns T39 PMRD Fall Time (Note 2) 1.5 ns 5 LBC Cycles 120 ns Note 1: This only applies when the Alternate PMD Interface is disabled, APMDREG.APMDEN e 0. Note 2: This parameter is not tested, but is assured by correlation with characterization data. TL/F/11708 – 36 FIGURE 7-10. Primary PMD Timing Diagrams 120 Units 7.0 Electrical Characteristics (Continued) AC Characteristics for the Alternate PMD Interface The following input signals are covered: PMD Indicate Data (PMID), Signal Detect (SD), Receive Data In (RXDÐIN), Receive Clock In (RXCÐIN). The following output signals are covered: PMD Request Data (PMRD), Transmit Clock (TXC), Recovered Data Out (RXDÐOUT), Recovered Clock Out (RXCÐOUT). Note: The Alternate PMD Interface is only available on the 160 pin DP83257 PLAYER a Device and the 100 pin DP83256-AP Device. The Transmit Clock is enabled by the CGMREG.TXCE bit. The rest of the Alternate PMD Interface is enabled by the APMDREG.APMDEN bit. Symbol Parameter Conditions Min T40 RXCÐOUT a to RXDÐOUT g Change Time T41 PMID g to RXDÐOUT Latency T42 RXDÐIN g to RXCÐIN a Setup Time 4.0 T43 RXDÐIN g to RXCÐIN a Hold Time 0.5 T44 TXC a to PMRD g Change Time 4.0 T42 SD Minimum Pulse Width 120 T45 RXCÐOUT g Pulse Width High (Note 1) T46 RXCÐOUT g Rise Time T47 RXCÐOUT g Fall Time T48 Typ 1.0 In Lock Max Units 5.0 ns 16 ns ns ns 7.0 ns ns 3.5 4.5 ns (Note 1) 1.5 ns (Note 1) 1.5 ns RXDÐOUT g Rise Time (Note 1) 1.5 ns T49 RXDÐOUT g Fall Time (Note 1) 1.5 ns T50 TXC g Pulse Width High (Note 1) 4.5 ns T51 TXC g Rise Time (Note 1) 1.5 ns T52 TXC g Fall Time (Note 1) 1.5 ns T38 PMRD Rise Time (Note 1) 1.5 ns T39 PMRD Fall Time (Note 1) 1.5 ns 3.5 Note 1: This parameter is not tested, but is assured by correlation with characterization data. TL/F/11708 – 52 FIGURE 7-11. ECL Rise and Fall Times 121 7.0 Electrical Characteristics (Continued) TL/F/11708 – 53 FIGURE 7-12. Alternate PMD Timing Diagrams 122 7.0 Electrical Characteristics (Continued) AC Characteristics for the PMD Interface Inputs (ANSI Specifications) The following input signals are covered: PMD Indicate Data (PMID), Receive Data In (RXDÐIN), Receive Clock In (RXCÐIN). Note: The Alternate PMD Interface is only available on the 160 pin DP83257 PLAYER a Device and the 100 pin DP83256-AP Device. The Transmit Clock is enabled by the CGMREG.TXCE bit. The rest of the Alternate PMD Interface is enabled by the APMDREG.APMDEN bit. All comments in square brackets are section references to the ANSI documents where these specifications can be found. Symbol Parameter Conditions Max Units b3 3 ns b 100 100 ppm From 1st Data and SD Active [PHY 5.2.6] 100 ms From Line State Change [PHY 5.2.6] 15 ms T53 CRM Window Recognition Region (PMID Inputs) [PMD E.2] T54 PMID Receive Clock Tolerance (Lock Acquisition Range) [PHY 5.2.4] T55 Receive Clock Acquisition Time T56 Receive Clock Acquisition Time Min Typ TL/F/11708 – 54 TL/F/11708 – 55 FIGURE 7-13. Alternate PMD Input Timing DiagramsÐANSI Specifications 123 7.0 Electrical Characteristics (Continued) AC Characteristics for the PMD Interface Outputs (ANSI Specifications) The following output signals are covered: PMD Request Data (PMRD), Transmit Clock (TXC), Recovered Data Out (RXDÐOUT), Recovered Clock Out (RXCÐOUT). Note: The Alternate PMD Interface is only available on the 160 pin DP83257 PLAYER a Device and the 100 pin DP83256-AP Device. The Transmit Clock is enabled by the CGMREG.TXCE bit. The rest of the Alternate PMD Interface is enabled by the APMDREG.APMDEN bit. Comments in square brackets are section references to the ANSI documents where these specifications can be found. Max Units T57 Symbol PMRD Total Transmit Jitter [Duty Cycle Distortion (DCD) a Data Dependent Jitter (DDJ) a Random Jitter (RJ)] Parameter (Note 1) [PMD 8.1] Conditions Min 0.72 ns p-p T58 Total Recovered Clock (RXCÐOUT) Jitter [Static Alignment Error Accuracy (SAE) a Clock Data Dependent Jitter (CÐDDJ) a Random Jitter (CÐRJ)] (Note 1) [PMD E.2] 2.5 ns p-p Note 1: This parameter is not tested, but is assured through characterization data and periodic testing of sample units. 124 Typ 7.0 Electrical Characteristics (Continued) AC Characteristics for User Definable Pins The following signals are covered: Sense Pins (SP). For Enable Pins (EP) timing see AC Characteristics for the Control Bus Interface. Symbol T59 Parameter Conditions Min SP Minimum Pulse Width Typ Max Units 120 ns TL/F/11708 – 56 FIGURE 7-14. SP Minimum Pulse Width AC Characteristics for Miscellaneous Interface The following signal is covered: Reset ( E RST). Symbol Parameter Conditions T60 Minimum Reset ( E RST) Pulse Width T61 Maximum Power Up Reset Cycle Duration T62 Maximum Hardware Reset ( E RST) Cycle Duration Min Typ Max Units 10 ms 0.5 ms 300 (Notes 1, 2) ns Note 1: This parameter is not tested, but is assured by correlation with characterization data. Note 2: User must wait this long before trying to access the device after power up. It is recommended that a Hardware Reset be used sometime after the Power Up Reset cycle is complete to insure proper device reset. TL/F/11708 – 57 FIGURE 7-15. Reset Timing 125 7.0 Electrical Characteristics (Continued) AC TEST CIRCUITS TL/F/11708 – 37 Note: S1 is closed for TPZL and TPLZ S2 is closed for TPZH and TPHZ S1 and S2 are open otherwise FIGURE 7-16. Switching Test Circuit for All TRI-STATE Output Signals TL/F/11708 – 38 FIGURE 7-17. Switching Test Circuit for All TTL Output Signals TL/F/11708 – 39 FIGURE 7-18. Switching Test Circuit for All Open Drain Output Signals (INT, ACK, and CR) TL/F/11708 – 40 FIGURE 7-19. Switching Test Circuit for All ECL Input and Output Signals 126 7.0 Electrical Characteristics (Continued) TEST WAVEFORMS TL/F/11708 – 41 FIGURE 7-20. ECL Output Test Waveform TL/F/11708 – 42 Note: All CMOS Inputs and outputs are TTL compatible. FIGURE 7-21. TTL Output Test Waveform TL/F/11708 – 43 FIGURE 7-22. TRI-STATE Output Test Waveform 127 8.0 Connection Diagrams 8.1 DP83256VF CONNECTION DIAGRAM For a Pinout Summary List, refer to Table 8-1. TL/F/11708 – 44 FIGURE 8-1. DP83256VF 100-Pin JEDEC Metric PQFP Pinout 128 8.0 Connection Diagrams (Continued) TABLE 8-1. DP83256 100-Pin PQFP Pinout Summary Pin No. Symbol I/O Pin Type 1 Local Byte Clock 4 Signal Name LBC4 O TTL 2 Local Byte Clock 3 LBC3 O TTL 3 Local Byte Clock 2 LBC2 O TTL 4 Local Byte Clock 1 LBC1 O TTL 5 Clock 16/32 CLK16 O TTL 6 PHY Port A Indicate Parity AIP O TTL 7 PHY Port A Indicate Control AIC O TTL 8 PHY Port A Indicate Datak7l AID7 O TTL 9 PHY Port A Indicate Datak6l AID6 O TTL 10 PHY Port A Indicate Datak5l AID5 O 11 I/O Power VCCÐIO a 5V 12 I/O Ground GNDÐIO a 0V 13 PHY Port A Indicate Datak4l AID4 O TTL 14 PHY Port A Indicate Datak3l AID3 O TTL 15 PHY Port A Indicate Datak2l AID2 O TTL 16 PHY Port A Indicate Datak1l AID1 O TTL 17 PHY Port A Indicate Datak0l AID0 O 18 ReservedÐ0 19 ReservedÐ0 20 ANALOG Power TTL TTL RESÐ0 a 0V RESÐ0 a 0V VCCÐANALOG a 5V GNDÐANALOG a0 V 21 ANALOG Ground 22 Phase Select PHÐSEL I TTL 23 Reference Select REFÐSEL I TTL 24 Reference Input REFÐIN I TTL 25 Feedback Input FBKÐIN I TTL 26 Crystal Output XTALÐOUT O 27 Crystal Input XTALÐIN I 28 ESD Power VCCÐESD a 5V 29 ESD Ground GNDÐESD a 0V 30 Loop Filter LPFLTR 31 ECL Power VCCÐECL 32 PMD Request Data b PMRDb O ECL 33 PMD Request Data a PMRD a O ECL 34 ECL Power VCCÐECL 35 ECL Ground GNDÐECL 36 Signal Detect b SDb I ECL 37 Signal Detect a SD a I ECL 38 PMD Indicate Data b PMIDb I ECL 129 O a 5V a 5V a 0V 8.0 Connection Diagrams (Continued) TABLE 8-1. DP83256 100-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name Symbol I/O Pin Type 39 PMD Indicate Data a PMID a I ECL 40 Sense Pin 0 SP0 I TTL 41 Enable Pin 0 EP0 O TTL 42 Sense Pin 1 SP1 I TTL 43 Enable Pin 1 EP1 O 44 ECL Power VCCÐECL a 5V 45 ECL Ground GNDÐECL a 0V 46 PMD Transmitter Enable TXE O TTL 47 PMD Transmitter Enable Level TEL I TTL 48 ReservedÐ0 RESÐ0 49 No Connect N/C 50 ReservedÐ0 RESÐ0 a 0V 51 ReservedÐ0 RESÐ0 a 0V 52 ReservedÐ0 RESÐ0 a 0V 53 ReservedÐ0 RESÐ0 a 0V 54 No Connect N/C 55 ECL Ground GNDÐECL a 0V 56 ECL Power VCCÐECL a 5V 57 ReservedÐ0 RESÐ0 a 0V 58 ReservedÐ0 RESÐ0 a 0V 59 PHY Port B Request Datak0l BRD0 I TTL 60 PHY Port B Request Datak1l BRD1 I TTL 61 PHY Port B Request Datak2l BRD2 I TTL 62 PHY Port B Request Datak3l BRD3 I TTL 63 PHY Port B Request Datak4l BRD4 I 64 I/O Ground GNDÐIO 65 I/O Power VCCÐIO 66 PHY Port B Request Datak5l BRD5 I TTL 67 PHY Port B Request Datak6l BRD6 I TTL 68 PHY Port B Request Datak7l BRD7 I TTL 69 PHY Port B Request Control BRC I TTL 70 PHY Port B Request Parity BRP O TTL 71 E Device Reset E RST I TTL 72 Read/ E Write R/ E W I TTL 73 Chip Enable E CE I TTL 74 E Interrupt E INT O Open Drain 75 E Acknowledge E ACK O Open Drain 76 Control Bus Addressk0l CBA0 I TTL 130 TTL a 0V TTL a 0V a 5V 8.0 Connection Diagrams (Continued) TABLE 8-1. DP83256 100-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name 77 Control Bus Addressk1l Symbol I/O CBA1 I 78 I/O Logic Ground GNDÐIO 79 I/O Logic Power VCCÐIO 80 Control Bus Addressk2l CBA2 I TTL 81 Control Bus Addressk3l CBA3 I TTL 82 Control Bus Addressk4l CBA4 I TTL 83 Control Bus Addressk5l CBA5 I 84 ReservedÐ0 RESÐ0 a 0V 85 ReservedÐ1 RESÐ1 a 5V 86 Control Bus Datak0l 87 Core Ground GNDÐCORE 88 Core Power VCCÐCORE 89 Control Bus Datak1l CBD1 I/O TTL 90 Control Bus Datak2l CBD2 I/O TTL 91 Control Bus Datak3l CBD3 I/O TTL 92 Control Bus Datak4l CBD4 I/O TTL 93 Control Bus Datak5l CBD5 I/O TTL 94 Control Bus Datak6l CBD6 I/O TTL 95 Control Bus Datak7l CBD7 I/O TTL 96 Control Bus Data Parity CBP I/O 97 I/O Ground GNDÐIO a 0V 98 I/O Power VCCÐIO a 5V CBD0 Pin Type TTL a 0V a 5V I/O TTL TTL a 0V a 5V TTL 99 Local Symbol Clock LSC O TTL 100 Local Byte Clock5 LBC5 O TTL 131 8.0 Connection Diagrams (Continued) 8.2 DP83256VF-AP CONNECTION DIAGRAM For a Pinout Summary List, refer to Table 8-2. TL/F/11708 – 58 FIGURE 8-2. DP83256VF-AP 100-Pin JEDEC Metric PQFP Pinout 132 8.0 Connection Diagrams (Continued) TABLE 8-2. DP83256VF-AP 100-Pin PQFP Pinout Summary Pin No. Symbol I/O Pin Type 1 Local Byte Clock 4 Signal Name LBC4 O TTL 2 Local Byte Clock 3 LBC3 O TTL 3 Local Byte Clock 2 LBC2 O TTL 4 Local Byte Clock 1 LBC1 O TTL 5 Clock 16/32 CLK16 O TTL 6 PHY Port A Indicate Parity AIP O TTL 7 PHY Port A Indicate Control AIC O TTL 8 PHY Port A Indicate Datak7l AID7 O TTL 9 PHY Port A Indicate Datak6l AID6 O TTL 10 PHY Port A Indicate Datak5l AID5 O 11 I/O Power VCCÐIO a 5V 12 I/O Ground GNDÐIO a 0V 13 PHY Port A Indicate Datak4l AID4 O TTL 14 PHY Port A Indicate Datak3l AID3 O TTL 15 PHY Port A Indicate Datak2l AID2 O TTL 16 PHY Port A Indicate Datak1l AID1 O TTL 17 PHY Port A Indicate Datak0l AID0 O 18 ReservedÐ0 19 ReservedÐ0 20 ANALOG Power TTL TTL RESÐ0 a 0V RESÐ0 a 0V VCCÐANALOG a 5V GNDÐANALOG a0 V 21 ANALOG Ground 22 Phase Select PHÐSEL I TTL 23 Reference Select REFÐSEL I TTL 24 Reference Input REFÐIN I TTL 25 Feedback Input FBKÐIN I TTL 26 Crystal Output XTALÐOUT O 27 Crystal Input XTALÐIN I 28 ESD Power VCCÐESD a 5V 29 ESD Ground GNDÐESD a 0V 30 Transmit Clockb TXCb O 31 Transmit Clock a TXC a O 32 ECL Power 33 PMD Request Data b 34 35 VCCÐECL ECL ECL a 5V PMRDb O ECL PMD Request Data a PMRD a O ECL Receive Clock Outb RXCÐOUTb O ECL 36 Receive Clock Out a RXCÐOUT a O 37 ECL Power VCCÐECL a 5V 38 ECL Ground GNDÐECL a 0V 133 ECL 8.0 Connection Diagrams (Continued) TABLE 8-2. DP83256VF-AP 100-Pin PQFP Pinout Summary (Continued) Pin No. Symbol I/O Pin Type 39 Signal Detectb Signal Name SDb I ECL 40 Signal Detect a SD a I ECL 41 PMD Indicate Datab PMIDb I ECL 42 PMD Indicate Date a PMID a I ECL 43 Enable Pin 0 EP0 O TTL 44 Enable Pin 1 EP1 O 45 ECL Power VCCÐECL a 5V 46 ECL Ground GNDÐECL a 0V 47 Receive Clock Inb RXCÐINb I ECL 48 Receive Clock In a RXCÐIN a I ECL 49 Receive Data Inb RXDÐINb I ECL 50 Receive Data In a RXDÐIN a I ECL 51 Receive Data Outb RXDÐOUTb O ECL 52 Receive Data Out a RXDÐOUT a O ECL 53 No Connect N/C 54 No Connect N/C 55 ECL Ground GNDÐECL a 0V 56 ECL Power VCCÐECL a 5V 57 ReservedÐ0 RESÐ0 a 0V 58 ReservedÐ0 RESÐ0 a 0V 59 PHY Port B Request Datak0l BRD0 I TTL 60 PHY Port B Request Datak1l BRD1 I TTL 61 PHY Port B Request Datak2l BRD2 I TTL 62 PHY Port B Request Datak3l BRD3 I TTL 63 PHY Port B Request Datak4l BRD4 I 64 I/O Ground GNDÐIO 65 I/O Power VCCÐIO 66 PHY Port B Request Datak5l BRD5 I TTL 67 PHY Port B Request Datak6l BRD6 I TTL 68 PHY Port B Request Datak7l BRD7 I TTL 69 PHY Port B Request Control BRC I TTL 70 PHY Port B Request Parity BRP O TTL 71 E Device Reset E RST I TTL 72 Read/ E Write R/ E W I TTL 73 Chip Enable E CE I TTL 74 E Interrupt E INT O Open Drain 75 E Acknowledge E ACK O Open Drain 76 Control Bus Addressk0l CBA0 I TTL 134 TTL TTL a 0V a 5V 8.0 Connection Diagrams (Continued) TABLE 8-2. DP83256VF-AP 100-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name 77 Control Bus Addressk1l Symbol I/O CBA1 I 78 I/O Logic Ground GNDÐIO 79 I/O Logic Power VCCÐIO 80 Control Bus Addressk2l CBA2 I TTL 81 Control Bus Addressk3l CBA3 I TTL 82 Control Bus Addressk4l CBA4 I TTL 83 Control Bus Addressk5l CBA5 I 84 ReservedÐ0 RESÐ0 a 0V 85 ReservedÐ1 RESÐ1 a 5V 86 Control Bus Datak0l 87 Core Ground GNDÐCORE 88 Core Power VCCÐCORE 89 Control Bus Datak1l CBD1 I/O TTL 90 Control Bus Datak2l CBD2 I/O TTL 91 Control Bus Datak3l CBD3 I/O TTL 92 Control Bus Datak4l CBD4 I/O TTL 93 Control Bus Datak5l CBD5 I/O TTL 94 Control Bus Datak6l CBD6 I/O TTL 95 Control Bus Datak7l CBD7 I/O TTL 96 Control Bus Data Parity CBP I/O 97 I/O Ground GNDÐIO a 0V 98 I/O Power VCCÐIO a 5V CBD0 Pin Type TTL a 0V a 5V I/O TTL TTL a 0V a 5V TTL 99 Local Symbol Clock LSC O TTL 100 Local Byte Clock5 LBC5 O TTL 135 8.0 Connection Diagrams (Continued) 8.3 DP83257VF CONNECTION DIAGRAM For a Pinout Summary List, refer to Table 8-3. TL/F/11708 – 45 FIGURE 8-3. DP83257VF 160-Pin JEDEC Metric PQFP Pinout 136 8.0 Connection Diagrams (Continued) TABLE 8-3. DP83257 160-Pin PQFP Pinout Summary Pin No. Signal Name Symbol I/O Pin Type 1 Local Byte Clock 4 LBC4 O TTL 2 Local Byte Clock 3 LBC3 O TTL 3 Local Byte Clock 2 LBC2 O TTL 4 Local Byte Clock 1 LBC1 O TTL 5 Clock 16/32 CLK16 O TTL 6 PHY Port A Indicate Parity AIP O TTL 7 PHY Port A Request Parity ARP I TTL 8 PHY Port A Indicate Control AIC O TTL 9 PHY Port A Request Control ARC I TTL 10 PHY Port A Indicate Datak7l AID7 O TTL 11 PHY Port A Request Datak7l ARD7 I TTL 12 PHY Port A Indicate Datak6l AID6 O TTL 13 PHY Port A Request Datak6l ARD6 I TTL 14 PHY Port A Indicate Datak5l AID5 O TTL 15 PHY Port A Request Datak5l ARD5 I 16 I/O Power VCCÐIO 17 I/O Ground GNDÐIO 18 PHY Port A Indicate Datak4l AID4 19 PHY Port A Request Datak4l 20 PHY Port A Indicate Datak3l 21 TTL a 5V a 0V O TTL ARD4 I TTL AID3 O TTL PHY Port A Request Datak3l ARD3 I TTL 22 PHY Port A Indicate Datak2l AID2 O TTL 23 PHY Port A Request Datak2l ARD2 I TTL 24 PHY Port A Indicate Datak1l AID1 O TTL 25 PHY Port A Request Datak1l ARD1 I TTL 26 PHY Port A Indicate Datak0l AID0 O TTL 27 PHY Port A Request Datak0l ARD0 I 28 ReservedÐ0 RESÐ0 a 0V 29 ReservedÐ0 RESÐ0 a 0V 30 ReservedÐ0 RESÐ0 a 0V 31 ReservedÐ0 RESÐ0 a 0V 32 ANALOG Power VCCÐANALOG a 5V 33 ANALOG Ground GNDÐANALOG 34 Phase Select 35 TTL a 0V PHÐSEL I TTL Reference Select REFÐSEL I TTL 36 Reference Input REFÐIN I TTL 37 Feedback Input FBKÐIN I TTL 38 No Connect N/C 137 8.0 Connection Diagrams (Continued) TABLE 8-3. DP83257 160-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name Symbol 39 No Connect N/C 40 No Connect N/C 41 No Connect N/C 42 No Connect N/C 43 No Connect N/C 44 No Connect 45 Crystal Output 46 I/O Pin Type N/C XTALÐOUT O Crystal Input XTALÐIN I 47 ESD Power VCCÐESD a 5V 48 ESD Ground GNDÐESD a 0V 49 Loop Filter LPFLTR O 50 Transmit Clockb TXCb O 51 Transmit Clock a TXC a O 52 ECL Power 53 PMD Request Datab PMRDb O ECL 54 PMD Request Data a PMRD a O ECL 55 Receive Clock Outb RXCÐOUTb O ECL 56 Receive Clock Out a RXCÐOUT a O VCCÐECL ECL ECL a 5V ECL 57 ECL Power VCCÐECL 58 ECL Ground GNDÐECL 59 Signal Detectb SDb I ECL 60 Signal Detect a SD a I ECL 61 PMD Indicate Datab PMIDb I ECL 62 PMD Indicate Data a PMID a I ECL 63 Sense Pin 0 SP0 I TTL 64 Enable Pin 0 EP0 O TTL 65 Sense Pin 1 SP1 I TTL 66 Enable Pin 1 EP1 O TTL 67 Sense Pin 2 SP2 I TTL 68 Enable Pin 2 EP2 O TTL 69 Cascade Start CS I TTL 70 Cascade Ready CR O Open Drain 71 ECL Power VCCÐECL 72 ECL Ground GNDÐECL 73 PMD Transmitter Enable 74 PMD Transmitter Enable Level TEL I TTL 75 Receive Clock Inb RXCÐINb I ECL 76 Receive Clock In a RXCÐIN a I ECL TXE 138 a 5V a 0V a 5V a 0V O TTL 8.0 Connection Diagrams (Continued) TABLE 8-3. DP83257 160-Pin PQFP Pinout Summary (Continued) Pin No. Symbol I/O Pin Type 77 Receive Data Inb Signal Name RXDÐINb I ECL 78 Receive Data In a RXDÐIN a I ECL 79 No Connect N/C 80 No Connect N/C 81 No Connect N/C 82 Receive Data Outb RXDÐOUTb O ECL 83 Receive Data Out a RXDÐOUT a O 84 ReservedÐ0 RESÐ0 a 0V 85 ReservedÐ0 RESÐ0 a 0V 86 ReservedÐ0 RESÐ0 a 0V 87 No Connect N/C 88 ECL Ground GNDÐECL a 0V 89 ECL Power VCCÐECL a 5V 90 ReservedÐ0 RESÐ0 a 0V 91 ReservedÐ0 RESÐ0 a 0V 92 ReservedÐ0 RESÐ0 a 0V 93 ReservedÐ0 RESÐ0 94 PHY Port B Indicate Datak0l BID0 95 PHY Port B Request Datak0l 96 PHY Port B Indicate Datak1l 97 ECL a 0V O TTL BRD0 I TTL BID1 O TTL PHY Port B Request Datak1l BRD1 I TTL 98 PHY Port B Indicate Datak2l BID2 O TTL 99 PHY Port B Request Datak2l BRD2 I TTL 100 PHY Port B Indicate Datak3l BID3 O TTL 101 PHY Port B Request Datak3l BRD3 I TTL 102 PHY Port B Indicate Datak4l BID4 O TTL 103 PHY Port B Request Datak4l BRD4 I 104 I/O Ground GNDÐIO 105 I/O Power VCCÐIO 106 PHY Port B Indicate Datak5l BID5 107 PHY Port B Request Datak5l 108 PHY Port B Indicate Datak6l 109 PHY Port B Request Datak6l 110 111 112 113 114 TTL a 0V a 5V O TTL BRD5 I TTL BID6 O TTL BRD6 I TTL PHY Port B Indicate Datak7l BID7 O TTL PHY Port B Request Datak7l BRD7 I TTL PHY Port B Indicate Control BIC O TTL PHY Port B Request Control BRC I TTL PHY Port B Indicate Parity BIP O TTL 139 8.0 Connection Diagrams (Continued) TABLE 8-3. DP83257 160-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name Symbol I/O Pin Type 115 PHY Port B Request Parity BRP I TTL 116 E Device Reset E RST I TTL 117 Read/ E Write R/ E W I TTL 118 Chip Enable E CE I TTL 119 E Interrupt E INT O Open Drain 120 E Acknowledge E ACK O Open Drain 121 No Connect N/C 122 No Connect N/C 123 No Connect N/C 124 No Connect N/C 125 No Connect N/C 126 No Connect N/C 127 No Connect 128 Control Bus Addressk0l CBA0 I TTL 129 Control Bus Addressk1l CBA1 I 130 I/O Logic Ground GNDÐIO 131 I/O Logic Power VCCÐIO 132 Control Bus Addressk2l CBA2 I TTL 133 Control Bus Addressk3l CBA3 I TTL 134 Control Bus Addressk4l CBA4 I TTL 135 Control Bus Addressk5l CBA5 I 136 ReservedÐ0 RESÐ0 a 0V 137 ReservedÐ1 RESÐ1 a 5V 138 Control Bus Datak0l 139 Core Ground GNDÐCORE a 0V 140 Core Power VCCÐCORE a 5V 141 Control Bus Datak1l CBD1 I/O TTL 142 Control Bus Datak2l CBD2 I/O TTL 143 Control Bus Datak3l CBD3 I/O TTL 144 Control Bus Datak4l CBD4 I/O TTL 145 Control Bus Datak5l CBD5 I/O TTL 146 Control Bus Datak6l CBD6 I/O TTL 147 Control Bus Datak7l CBD7 I/O TTL 148 Control Bus Data Parity CBP I/O TTL 149 No Connect N/C 150 No Connect N/C 151 No Connect N/C N/C CBD0 140 TTL a 0V a 5V I/O TTL TTL 8.0 Connection Diagrams (Continued) TABLE 8-3. DP83257 160-Pin PQFP Pinout Summary (Continued) Pin No. Signal Name Symbol I/O Pin Type 152 No Connect N/C 153 No Connect N/C 154 No Connect N/C 155 No Connect N/C 156 No Connect N/C 157 I/O Ground GNDÐIO 158 I/O Power VCCÐIO 159 Local Symbol Clock LSC O TTL 160 Local Byte Clock5 LBC5 O TTL 141 a 0V a 5V 9.0 Package Information The information contained in this section describes the two packages used for the PLAYER a device. Land pattern information is provided to assist in surface mount layout using each of the available PLAYER a device packages. Mechanical drawings of each of the packages are also provided. 9.1 LAND PATTERNS TL/F/11708 – 46 FIGURE 9-1. Layout Land Patterns TABLE 9-1. Layout Land Pattern Dimensions Device A (mm) B (mm) P (mm) X (mm) DP83256VF and DP83256VF-AP 14mm x 14mm x 2.0mm 100-lead JEDEC FPQFP 14.60 18.45 0.50 0.35 DP83257VF 28mm x 28mm x 3.42mm 160-lead JEDEC MQFP 28.90 33.40 0.65 0.45 9.2 MECHANICAL DRAWINGS The following two pages contain the mechanical drawings for each of the available PLAYER a device packages. 142 Physical Dimensions millimeters Plastic Quad Flatpak (VJU) Order Number DP83256VF and DP83256VF-AP NS Package Number VJU100A 143 DP83256/56-AP/57 PLAYER a Device (FDDI Physical Layer Controller) Physical Dimensions millimeters (Continued) Plastic Quad Flatpak (V) Order Number DP83257VF NS Package Number VUL160A LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein: 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. National Semiconductor Corporation 1111 West Bardin Road Arlington, TX 76017 Tel: 1(800) 272-9959 Fax: 1(800) 737-7018 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. National Semiconductor Europe Fax: (a49) 0-180-530 85 86 Email: cnjwge @ tevm2.nsc.com Deutsch Tel: (a49) 0-180-530 85 85 English Tel: (a49) 0-180-532 78 32 Fran3ais Tel: (a49) 0-180-532 93 58 Italiano Tel: (a49) 0-180-534 16 80 National Semiconductor Hong Kong Ltd. 13th Floor, Straight Block, Ocean Centre, 5 Canton Rd. Tsimshatsui, Kowloon Hong Kong Tel: (852) 2737-1600 Fax: (852) 2736-9960 National Semiconductor Japan Ltd. Tel: 81-043-299-2309 Fax: 81-043-299-2408 National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.