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| (R) SBPH400-3 IEEE1394 3-Port 400Mbps Physical Layer PRELIMINARY DATA s s FEATURES s 3 ports fully compliant with IEEE 1394-1995 cable environment specification s Fully implements IEEE P1394a D2.0 proposal s S100, S200 and S400 speeds s IEEE P1394a proposal PHY-LINK interface s IEEE P1394a proposal Suspend/Resume s OHCI support s Per port disable s Automatic power saving s Optional isolation support s IEEE P1394a proposal arbitration enhancements s IEEE P1394a proposal register set and remote register read s Advanced Data-Strobe clock and data recovery s Digital delay-lock loop technology - no filtering capacitors s Built-in self-test (BIST) of analog and digital port logic s JTAG Test Access Port s 3.3V supply s 80 pin plastic TQFP package APPLICATIONS s Host processor interface s Host processor adapter cards s Digital set-top box s Digital Video Recorder/ Player s Repeaters P1394a Link interface Link layer interface logic Reset and arbitration Built-in self test Port logic Port logic Port logic 1394 cable interface @400 Mbps 1394 cable 1394 cable interface interface @400 Mbps @400 Mbps 16 March 1998 The information in this datasheet is subject to change 42 1697 05 Table of Contents 1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2.1 2.2 2.3 2.4 2.5 2.6 2.7 Transmitter and receiver port interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Connect detect and bias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Configuration pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Suspend/Resume/Disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Data encoder/decoder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Bus reset, arbitration and control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 PHY packets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 2.7.1 2.7.2 2.7.3 2.7.4 2.7.5 2.7.6 2.7.7 2.8 2.8.1 2.8.2 2.8.3 2.8.4 2.8.5 2.8.6 2.8.7 2.8.8 2.8.9 2.9 Link device interaction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Self-ID packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Link_on packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 PHY configuration packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Ping packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Remote Access and Reply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Remote Command and Confirmation packets . . . . . . . . . . . . . . . . . . . . . . 14 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Types of operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Control pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Link device request (LREQ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Bus request . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Register Read/Write requests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Status transfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Transmit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Link interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 2.8.10 SBPH400 registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Reset and initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 2.9.1 2.9.2 2.9.3 2.9.4 Power on . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 PHY/Link Interface start-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 PHY/Link interface reset and disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 LKON (link on) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 2.10 ISO (isolation) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 2.11 CPS (cable power status) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3. . . . . 32 3 Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 2/43 1 Table of Contents 4 Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 4.1 4.2 4.3 Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Operating conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 DC characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 5 AC characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 6 Package Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 7 Application Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 3/43 SBPH400-3 1 Overview The S B P H 4 0 0-3 provides the analog transceiver functions needed to implement a 3 port node in an IEEE 1394-1995 cable network. There are 2 differential line transceivers in each cable port. The following main functions are included in the chip: * * * * * Detection of connection status using line condition detection circuitry. Node initialization and bus arbitration. Reception and Transmission of Data Strobe Bit Level encoded packets Interface to higher level protocol devices (Link layer). Production test through JTAG The interface to the Link conforms to the IEEE 1394-1995 Annex J with 2 control lines and an 8 bit data bus, as modified by the P1394a proposals. The basic chip timing may be controlled either from a 24.596 MHz crystal controlling an internal oscillator or from an external 24.596 MHz oscillator. The internal delay lock loop (DLL) generates the various internal clocks for the high speed serial data transmission and reception. Note that there is no need to provide filtering capacitors. The input clock is used to derive the 49.152 MHz clock for the interface to a Link layer device, which provides the data to be transmitted on the 8 bit Link data interface. The data from the Link layer device is latched internally in the chip at 49.152 MHz. The bits are serialized and encoded in the Data Strobe Bit Level Encoding format. The Data information is transmitted differentially on the TPB cable pair(s) while the Strobe information is transmitted differentially on the TPA cable pair(s). Data can be transmitted at 98.304 Mbit/s (S100 speed), 196.608 Mbit/s (S200 speed) or 393.216 Mbit/sec (S400 speed). When a packet is received by a port, the corresponding transmitters are disabled and the receivers enabled. The received encoded Data information from TPA cable pair and the encoded Strobe information from the TPB cable pair are decoded to extract the receive clock signal and the data bits. The data bits are converted into a parallel format and transmitted to the Link Layer controller and the other active cable ports after resynchronisation to the system clock. Figure 1.1 is a block diagram of the SBPH400-3. The portion of circuit which is circled by the dash line is termed the Cable Media Interface. All signals between the Digital Circuit and the Cable Media Interface are pure digital signals. The signals which are driven on and received from the cable are analog differential and common mode signals. The differential signals on the cable transmit data or arbitration states, while common mode signals indicate the cable connection status or transmission rate (speed). 4/43 2 SBPH400-3 Figure 1.1 SBPH400-3 block diagram Cable Media Interface D[0:7] Ctl[0:1] LReq SClk CPS LPS ISO CMC LKON PC[0:2] RESET# LACT PDISABLE Arbitration and Control State Machine Logic ... Strb_Tx Data_Tx Strb_Rx Data_Rx Speed_Tx Strb_En Data_En Arb_A_Rx Arb_B_Rx Speed_Rx Port_Status Data Encoder/ Decoder LINK Interface I/O TPA1 Transmitter & Receiver Port 1 (Driver/Receiver, Arb. Comparator, Port_Status, Speed Monitor) TPA1# TPB1 TPB1# Port 2 (same as Port 1) TPA2 TPA2# TPB2 TPB2# TPA3 TPA3# TPB3 TPB3# ... ... Port 3 (same as Port 1) QX1 CLK24/QX0 TCK TRST# TMS TDI TDO TESTMODE TESTENABLE SCI[2:0] SCO[2:0] BUILT-IN SELF TEST TEST ACCESS PORT JTAG Bias TPBias1 TPBias2 TPBias3 R0 R1 ... 5/43 2 SBPH400-3 2 Functional Description 2.1 Transmitter and receiver port interface Figure 2.1 Analog port schematic Twisted Pair A Ph ys ical con ne c tio n de te ction c o m pa rato r Twisted Pair B I CD Con Tp Bia s d isa ble + - T pB ia s ' 0. 3f m in S20 0 Spe e d_T x C o m m o n m o d e sp ee d s ig na l c u rren t VG TPA S4 00 Sp ee d_T x TPB Da ta _T x 5 5 5 5 Da ta _Enab le D rive r Strb_ Tx Strb_ Ena ble R ec eiv er 55 55 TPA* TPB * Da ta_Rx + Strb _ Rx + 5 k - - 5% 25 0 pF VG + Arb_A_Rx A rbitr ation Co m pa ra to rs + (sh ared with TPA a nd othe r p orts) - Arb _ B_Rx A rb itra tion C om p arator s + + - - 7 k S20 0 Spe ed _Rx 7 k 7 k 7k + Bia s S 20 0 _ref + S40 0 Spe ed_ Rx - 0.8V T pB ia s de te c tion c o m pa rato r + - S4 00 _r ef The SBPH400-3 implements three cable interface transceiver ports. Each port operates independently from the other ports, under control of the device control logic. Each port provides two pairs of signals, denoted TPA, TPA#, and TPB, TPB#. Each signal is implemented using a driver and a receiver connected to a single pin (total of four pins per port). In various modes, the driver and receiver are enabled, either separately or both at the same time (for bi-directional signalling). 6/43 2 SBPH400-3 A port may be disconnected, disabled, suspended or active. When active, each port operates in the following modes: Idle mode: In this mode, each port's driver is disabled, i.e. the port presents a high impedance on all four signals. The inputs are continuously sampled, and if a signal is detected (which will normally indicate an arbitration signal from a connected port) then this is passed to the arbitration logic. Arbitration mode: In this mode, both pairs engage in bi-directional untimed digital signalling. Each pair transmits (under the control of the arbitration logic) either a logic 1 using differential signalling, a logic 0 using differential signalling, or high impedance Z. Simultaneously, the signal on each pair is continuously sampled, and is interpreted as a logic 1, logic 0 or high impedance Z. The sampled signal is a combination of the transmitted signal and the signal being transmitted on the corresponding pair by a connected transceiver (NB the cable implements a "twist" - TPA is connected to the far end TPB, and vice versa). The signal is interpreted using the 1394 1's dominant rule and passed to the arbitration logic for interpretation by the arbitration state machine. If a 11 level is received then this is interpreted as a reset signal and passed to the control logic. Speed signalling mode: Speed signalling uses common mode signalling. It is used to signal the transmission speed capabilities of the device (during the Self_ID phase of bus initialization) and in parallel with the transmission of Data_Prefix arbitration signal during arbitration to indicate the speed of the packet about to be transmitted. To send a speed signal, the port generates a common mode current signal on TPB and TPB# for 100 ns. This signal results in a drop of the current mode bias voltage through a pair of 55 Ohm resistors connected between the TpBias output and the TPA, TPA# pair at the receiving end. To receive a speed signal, the port determines the speed by measuring the amount of voltage drop on the TPA pair, compared to the TpBias signal it is generating. The port samples the speed signal at 20ns intervals in order to provide filtering against intermediate values or against noise. The SBPH400 requires two consecutive samples of a S200 or a S400 signal (as appropriate) in order to identify a valid speed signal. If no speed signal is identified when data transmission starts, then the data is assumed to be transmitted at S100 speed. Data transmission mode: In this mode, which always follows arbitration mode, the port transmits the data and strobe signals received from the data encoder on the TPB pair and the TPA pair respectively. The transmission uses uni-directional differential data signalling on each pair. Note that at the end of arbitration mode, the port will be transmitting an untimed signal of 01. If the first bit to be transmitted is a zero, then this will cause a transition on "data" (i.e. TPB, so that TPA, TPB transmit 00), if the first bit to be transmitted is a 1, then this will cause a transition on "strobe" (i.e. TPA, so that TPA, TPB transmit 11). The receivers are disabled during data transmission. At the end of data transmission mode, the port reverts to idle mode. Data reception mode: This mode always follows arbitration mode. The port presents high impedance on its output drivers (and ignores the data which is being repeated to the other ports by the data encoder/decoder). The port implements a differential receiver for each of TPA (data) and TPB (strobe) pairs, and passes the received binary signals to the data 7/43 2 SBPH400-3 decoder. Advanced logic is used to ensure reception of the Data and Strobe signals at speeds of up to 400 MHz. 2.2 Connect detect and bias A low current connect detect circuit is used to detect a physical connection. A current, applied to the TPA pair and sensed via a local Schmitt trigger, will indicate a disconnected state unless there is a physical connection to ground via the 5K resistor connected to the TPB pair at the far end. Note that this does not require the far end to be powered. This mechanism operates only when the port is not generating TpBias. In order to implement the cable detection, suspend/resume and speed signalling functions, a common mode bias voltage has to be provided to the TPA pair. A separate TpBias pin is provided for each port, which should be connected to the TPA pair via a pair of 55 Ohm resistors, as shown in Figure 2.1. The use of a separate pin for each port avoids problems of possible interference between the common mode signalling on each port, or possible misdetection of a disconnect. A single external resistor should be provided between pins R0 and R1 in order to set the internal operating and the cable driver output currents. A low TCR 3K 1% resistor should be used. 2.3 Configuration pins The SBPH400 provides six configuration pins which may be hard wired high or low, or may be directly controlled from a link layer device. Four of the pins are used to initialize registers which control configuration status bits in the self identification packet. The PC[0:2] pins provide the power reset value for the power class register, which is reported in the Self_ID packet in the pwr field. The CMC pin provides the power reset value for the C register, with is reported in the Self_ID packet in the C field to indicate if the node is a contender for the bus or isochronous resource manager. The LACT pin is used to initialize the value of the Link_active register on power reset. If set to zero, this allows the node to appear as having an inactive link (the L field in the Self-ID packet will be zero) until application software sets the Link_active bit to 1. The PDISABLE pin is used to initialize all ports as disabled on power reset. This satisfies the OHCI requirement, and allows software to be initialized before the device starts to participate on power-on as a new device on the bus. The ISO pin is used on power reset to determine the operating mode of the PHY/Link interface (DC coupled or using a DC isolation barrier). The SBPH400 also has a number of pins which are intended for use during production test only, and are held to ground or V DD as appropriate in normal operation. 8/43 2 SBPH400-3 2.4 Suspend/Resume/Disable Each port independently implements the P1394a suspend/resume proposal. At any one time, a port may be disconnected, disabled, suspended or active. On power reset, if PDISABLE = 0 then all ports are initialized as disconnected, and then, if any ports are physically connected, the normal new connection actions taken. If PDISABLE = 1 then all ports are initialized as disabled. When a port is not active, the TpBias output for the port is disabled, all outputs of the port are set to high impedance and any incoming arbitration signals on TPA and TPB are ignored. A port may be disabled or re-enabled by a command (register write) from the local link, or by remote PHY command packet. While disabled, the port ignores any incoming TpBias signal but the port continues to monitor its connection status using the connect_detect mechanism. A change in connection status will cause an interrupt to the link or a LinkOn packet as appropriate and according to the controlling flags. When re-enabled and connected, the port is treated as suspended (see below). When disconnected, a port ignores any incoming TpBias signal but continuously monitors the connection status using the connect detect circuitry. On connection, the port attempts to become active, but if an incoming TpBias is not then detected, then the port is suspended with the fault bit set. While active, the port continuously senses the common-mode bias input voltage on the TPB pair. The presence of a bias voltage on the TPB pair indicates that the port is connected to an active port on some other device. Similarly, the absence of a bias voltage indicates the lack of such a connection or that the far end port has been powered off. On detection of loss of bias, the port is treated as suspended (see below) A port may be suspended by a remote PHY command packet. In this case, it engages in a protocol with the remote connected port, resulting in that port too being suspended. It may be suspended on loss of incoming TpBias on an active port. A port may also be suspended as a result of its active connected port being suspended. A connected disabled port is treated as suspended when re-enabled. While suspended, the port monitors both TpBias and its connection state using the connect_detect mechanism. If a disconnection is detected, then the port becomes disconnected. If a TpBias signal is detected, then the port resumes to its active state. A port may be instructed to resume by means of a remote command packet, in which case it generates a TpBias signal. This will indicate to the connected peer port that it too should resume. It should be noted that any change of port state to or from the active state has the effect of a topology change, and that reconfiguration of the bus is necessary. To ensure that this occurs, the SBPH400 initiates the appropriate bus resets as defined in the P1394a proposal. When a port becomes disconnected, disabled or suspended, it carries out the appropriate actions and then automatically enters a low power mode. Normal operation (on full power) is restored after an appropriate delay (to allow the internal clocks to stabilize) on any change in 9/43 2 SBPH400-3 port state. If all ports are in a low power state, and the PHY/Link interface is disabled, then the SBPH400 implements the necessary delays to allow the SBPH400 core to enter a low power state in future versions with no functional or timing change. 2.5 Data encoder/decoder The data encoder/decoder implements the SGS-Thomson patented "Data/Strobe" clock encoding technique, as described in the 1394 specification. Data to be transmitted is serialized and encoded into the appropriate Data and Strobe signals. These are send simultaneously to all active ports for outputting. All output is clocked by the SBPH400 clock derived from the local crystal. Note that data to be transmitted may be received from an incoming port, or from the link interface. Data received from a port (only at most one port can be receiving data at any one time) is resynchronized to the local clock using a small elastic buffer, as the clock frequency of the incoming data may differ (by up to 200 ppm) from the local clock. The buffer is sized to avoid underflow or overflow for the longest possible packet.The data is repeated to the ports and to the link layer as described above, using the local reference clock. 2.6 Bus reset, arbitration and control The SBPH400 enters bus reset on power reset, if the reset signal is sensed on any connected port's arbitration signal lines, on a request from a link layer device, on resume from suspend or on connection of detection on any port (possibly after a delay, to allow for an incoming reset), on loss of TpBias on an active parent port, on entry to suspend as a result of the peer port being suspended or disabled, or if the device stays in any state other than Idle, Tree-ID start, Transmit or Receive for longer than 300 sec. In some circumstances, the device will arbitrate for the bus before generating a reset signal, as defined in the P1394a proposal. This results in minimum disruption to high priority traffic. On entry to reset, the arbitration control logic enters a Tree-ID phase. Either the node will be identified an isolated node, or the node will be identified as the root, and all active ports will be identified as child ports, or one active port will be the port to the node's parent, and the other active ports will be identified as child ports. The control logic will then engage in Self-ID, in which all nodes are allocated a node-ID and exchange self-ID packets (see 2.7.2). All received self-ID packets are passed to the link layer device. Speed capabilities are exchanged during the Self-ID process with all connected active nodes. In normal operation, the control logic implements the functions of the root, should the result of the Tree-ID process be that this node becomes the root. The control logic accepts arbitration requests from either the local link or any port. Upon receipt of an arbitration request, the request is accepted locally (if the node is the root) or repeated towards the root node via the parent port. Data Prefix (01) is transmitted on all other ports, which indicates that any arbitration request from these ports is rejected. 10/43 2 SBPH400-3 If the request for transmit comes from the local link, then the arbitration control logic waits for an appropriate gap (all interfaces Idle), and then (unless the request is an immediate request) arbitrates as above. The arbitration logic supports all the arbitration enhancements specified in IEEE P1394a:* * * arbitrated reset (a short reset which is delayed until a subaction gap arbitration) ack-accelerated arbitration (immediate arbitration after an ACK) fly-by arbitration (concatenation of packets after a packet received from a child port) 2.7 PHY packets 2.7.1 Link device interaction The SBPH400 will forward to the link (if the PHY/Link interface is active) every PHY packet received on the bus. The SBPH400 will interpret every PHY packet which it receives from the local link device for transmission on the bus (in addition to responding to every PHY packet received from the bus). The SBPH400 will act on it in exactly the same way as if the packet was received from the bus. 2.7.2 Self-ID packet The Self-ID packet has the following format: Figure 2.2 10 Self-ID packet format phy_ID 0L gap_cnt sp rsv c pwr p0 p1 p2 i 0 logical inverse of first quadlet 11/43 2 SBPH400-3 The fields in the Self-ID packet are derived as shown in Table 2.1. Table 2.1 Field phy_ID L gap_cnt sp rsv c pwr p0, p1 p2 Self ID packet fields Derived from self-ID process or set_PHY_ID packet Link enabled register Gap_Count register Max_Phy_Speed (reserved) Contender register Power class register port status for port 0, 1 and 2 respectively initiated reset Comment physical node identifier Logical AND of LPS signal and the Link_active register current value of Gap Count register 10b (S100, S200 and S400 capable) 00b current value of C register current value of Power class register 01 - not active (disabled, disconnected or suspended) 10 - active and connected to parent node 11 - active and connected to child node set whenever the node initiated the current bus reset i 2.7.3 Link_on packet The SBPH400 will respond to a Link_on packet addressed to it received on the bus. The packet has the following format: Figure 2.3 01 Link_on packet format phy_ID 0000 0000 0000 0000 0000 0000 logical inverse of first quadlet If the logical AND of the LPS pin and the Link_active bit is zero, then the SBPH400 will generate a 6.144 MHz signal on the LKON pin, until this logical value becomes 1. Otherwise the packet is forwarded to the local link. Note that all Link_on packets received on the bus are forwarded to the local link if it is active, whether or not the packets are addressed to the local node. 2.7.4 PHY configuration packet The SBPH400 will respond to every PHY configuration packet which it receives on the bus, or from the link device for transmission on the bus. The packet has the format shown in Figure 2.4: 12/43 2 SBPH400-3 Figure 2.4 00 PHY configuration packet format root_ID RT gap_cnt 0000 0000 0000 0000 logical inverse of first quadlet The fields in the PHY configuration packet are interpreted as shown in Table 2.2. Table 2.2 Field root_ID R T gap_cnt PHY configuration packet fields Definition physical ID set root set gap count Gap_Count value Comment the physical node identifier of the node to become root on next reset The Force_Root bit in the SBPH400 is set if R=1 and root_ID = the node_ID of this node If T=1, then the value of the gap count register in the SBPH400 is set to gap_cnt. new value of Gap Count register Note that either or both of R and T must be set to 1. 2.7.5 Ping packet The SBPH400 supports the use of ping timing. The ping packet has the format shown in Figure 2.5: Figure 2.5 00 Ping packet format phy_ID 00 type (0) 00 0000 0000 0000 0000 logical inverse of first quadlet When the SBPH400 receives a ping packet from the bus or from the local link addressed to the node, it responds immediately (without arbitration) with a Self_ID packet to both the bus and the local link. 2.7.6 Remote Access and Reply The SBPH supports remote access to its internal registers. On receipt of a remote access packet addressed to the node (either from the bus or from the local link), the SBPH400 will immediately respond with the appropriate remote reply packet. The remote access packet and the reply packet are also forwarded to the local link. 13/43 2 SBPH400-3 Figure 2.6 00 Remote access packet format phy_ID 00 type page port reg reserved logical inverse of first quadlet Figure 2.7 00 Remote reply packet format phy_ID 00 type page port reg data logical inverse of first quadlet The fields in the remote access and remote reply packets are interpreted as shown in Table 2.3. Table 2.3 Field phy_ID type Remote Access and Remote Reply packet fields Comment Physical node identifier of the destination of the packet (type = 1 or 5) Physical node identifier of the source of the packet (type = 3 or 7) 1 - register read of the base registers 3 - register contents (base registers) 5 - register read of the paged registers 7 - register contents (paged registers) 0 - Port Status Page 1 - Product Identification Page 2-7 - (these pages not implemented, always responds with zero) Identify the port for the selected register page. For values 0, 1 and 2, the page is as defined in Table 2.17. For all other values the SBPH400 always responds with zero. If type = 1, then reg directly addresses one of the base registers. If type = 5, then reg addresses 1000 +reg in the selected page and port. 2 Current value of the SBPH400 register addressed by the immediately preceding Remote Access packet (reserved and unimplemented fields and registers are returned as zero). page port reg data 2.7.7 Remote Command and Confirmation packets The SBPH400 responds to remote command packets by initiating the appropriate action and immediately sending a remote confirmation packet. Figure 2.8 00 Remote command packet format phy_ID 00 type(8) 000 port 0000 0000 cmnd logical inverse of first quadlet 14/43 2 SBPH400-3 Figure 2.9 00 Remote confirmation packet format phy_ID 00 type(A16) 000 port 000 f c b d ok cmnd logical inverse of first quadlet The fields in the remote command and remote confirmation packets are interpreted as shown in Table 2.4. Table 2.4 Field phy_ID type port f c b d ok cmnd Remote Command and Confirmation packet fields Comment Physical node identifier of the destination of the packet (type = 8) Physical node identifier of the source of the packet (type = A ) 16 8 - remote command packet A16 - remote confirmation packet Identify the port for the command or confirmation. For values other than 0, 1 and 2, the SBPH400 always responds with the OK bit set to zero in the confirmation packet. current value of the Fault bit from SBPH400 register 1001 for the addressed port 2 current value of the Connected bit from SBPH400 register 1000 for the addressed port 2 current value of the Bias bit from SBPH400 register 1000 for the addressed port 2 current value of the Disabled bit from SBPH400 register 1000 for the addressed port 2 1 if the immediately preceding remote command was accepted by the SBPH400, zero otherwise type = 8:0 - NOP 1 - Transmit TX_DISABLE_NOTIFY then disable the port 2 - Initiate suspend 4 - Clear the port's Fault bit 5 - Enable port 6 - Resume port type = A16:The cmnd value from the immediately preceding remote command packet Current value of the SBPH400 register addressed by the immediately preceding Remote Access packet (reserved and unimplemented fields and registers are returned as zero). data 2.8 Link interface 2.8.1 Overview The link interface in the SBPH400 operates as described in the IEEE P1394a proposal. The SBPH400 implements an interface to a single 1394 link layer device, using the pins D[0:7], Ctl[0:1], LREQ, SClk, LPS and LKON. The interface is scalable, using 2 data bits in parallel per 100 Mbit/sec. This enables the clock rate of the signals at this interface to remain at 50 MHz. 15/43 2 SBPH400-3 The SBPH400 has control over the bidirectional pins. It will, upon request, transfer this control to the link device, which can then drive these pins. The 8 bidirectional data pins D[0:7] form the data bus. The portion of the D bus which carries packet data is left-justified starting with the 0 bit. Packet data for 100 Mb/s transfers uses D[0:1], 200 Mb/s transfers use D[0:3], and 400 Mb/s transfers use D[0:7]. The unused D[n] signals are transmitted as `0' and are ignored when the link device has control of the bus. The control bus CTL[0:1] carries the control information. The LREQ pin is used by the link device to request access to the serial bus and to read and write the chip registers. 2.8.2 Types of operation The four basic operations which may occur at the PHY-Link interface are: request, status, transmit and receive. Request is the only operation initiated by the link layer device. The link layer device uses the request operation to read or write a register located in the SBPH400 or to request the bus so that the SBPH400 can initiate a transmit action on the bus. The SBPH400 initiates a receive action whenever a packet is received from the serial bus and a status indication to notify events to the link layer device. 2.8.3 Control pins When the SBPH400 has control of the PHY-Link interface the CTL[0:1] lines are encoded as shown in Table 2.5. Table 2.5 CTL[0:1] 00 01 10 11 CTL[0:1] When the SBPH400 is driving NAME Idle Status Receive Grant DESCRIPTION No activity (default mode) The SBPH400 is sending status information to the link device An incoming packet is being transferred from the SBPH400 to the link device The link device is granted the bus to send a packet When the link layer device has been granted the PHY-Link interface by the SBPH400, it should encode the CTL[0:1] lines Table 2.6 Table 2.6 00 01 10 11 CTL[0:1] when the link is driving (upon grant from SBPH400) NAME Idle Hold Transmit unused DESCRIPTION The link device has released the bus (normally after transmission). Note that multiple Idles may need to be transmitted. The link device is preparing data or wishes to reacquire the bus without arbitrating to send another packet The link device is sending a packet to the SBPH400 16/43 2 SBPH400-3 2.8.4 Link device request (LREQ) The link layer device requests the bus or accesses a register in the SBPH400 by sending a short serial stream on the LREQ pin. The information sent includes the type of bus request, the speed at which the packet is to be sent, or a read or write command. The length of the request stream depends on whether it is a bus request (8 bits), a read register request (9 bits), a write register request (17 bits), or an accelerate control request (6 bits). The request stream always commences with a start bit (value 1b) and terminates with a stop bit (0b). Bit 0 is transmitted first on the serial request stream. The LREQ timing and the definition of the bits in the transfer are shown in Figure 2.10 Figure 2.10 LREQ timing LR0 LR1 LR2 LR3 LR(n-2) LR(n-1) The Bus Request is 8 bits long and is specified in Table 2.7. (Note that this is backwards compatible with the 7-bit format as specified in IEEE 1394-1995, which is also supported by the SBPH400.) Table 2.7 Bit(s) 0 1-3 4-6 Bus request format Name Start_Bit Request_Type Request_Speed Description Indicates start of transfer. Always 1. Indicates the type of bus request being performed. See Table 2.12 for the encoding of this field. Indicates the speed at which the SBPH400 will be sending the packet for this request. This field has the same encoding as the speed code from the first symbol of the receive packet. See Table 2.11 for the encoding of this field. Indicates end of transfer. Always 0. 7 Stop_Bit The Read Request is used to read a register in the device. It is 9 bits long and is specified in Table 2.8. Table 2.8 Bit(s) 0 1-3 4-7 8 Read register request format Description Indicates the start of transfer. Always 1. 100b (Register read) Indicates the address of the physical register to be read. Indicates end of transfer. Always 0. Start_Bit Request_Type Address Stop_Bit Name 17/43 2 SBPH400-3 The Write Request is used to write to a register in the device. It is 17 bits long and is specified in Table 2.9. Table 2.9 Bit(s) 0 1-3 4-7 8-15 16 Write register request format Description Indicates the start of transfer. Always 1. 101b (Register write) Indicates the address of the physical register to be written. Indicates the data to be written to the specified physical register. Indicates end of transfer. Always 0. Start_Bit Request_Type Address Data Stop_Bit Name The Accelerate Control Request is used to control the use of arbitration acceleration in order to prevent Cycle Start packet starvation. It is 6 bits long and is specified in Table 2.10 Table 2.10 Bit(s) 0 1-3 4 5 Accelerate control request format Name Start_Bit Request_Type Acceleration_Select Stop_Bit Description Indicates the start of transfer. Always 1. 110b (AccCtrl) 0 = Decelerate 1 = Accelerate Indicates end of transfer. Always 0. The Request Speed field in the bus request is encoded as specified in Table 2.11: Table 2.11 LR[4:6] 000 001 010 011 100 101 110 111 Request speed field Data Rate S100 not supported (S1600) S200 not supported (S3200) S400 reserved not supported (S800) reserved 18/43 2 SBPH400-3 The Request Type field is encoded as specified in Table 2.10: Table 2.12 LR[1:3] 000 001 Request type field Name ImmReq IsoReq Description Used for Acknowledge Transfers. The SBPH400 takes control of the bus immediately upon detecting idle without arbitration. Used for Isochronous Transfers. The SBPH400 arbitrates after an isochronous gap, or transmits immediately if an isochronous packet has just been received from a child port (fly-by arbitration). The SBPH also performs accelerated arbitrations (see AccCtrl below) after receiving this request if the enab_accel register is set to 1. Used for Cycle Master requests. The SBPH400 arbitrates after a subaction gap or, if acceleration enhancements are enabled (enab_accel register is set to 1) and if accelerate control has been set to allow accelerations (see AccCtrl below), arbitrates after an ACK packet has been received, or transmits immediately if an ACK packet has just been received on a child port (see Accelerate/Decelerate below), ignoring the fair protocol. This is also used for the second and subsequent optimized fair transfers Used for Fair Transfers. Used for Fair Transfers. The SBPH400 normally arbitrates after subaction gap. If acceleration enhancements are enabled (enab_accel register is set to 1) and if accelerate control has been set to allow accelerations (see AccCtrl below), then the SBPH400 will arbitrate after an ACK packet has been received, or transmit the packet immediately if an ACK packet has been received on a child port. In all cases the SBPH400 follows the fair protocol (one FairReq packet per arbitration reset gap). Return specified register contents through a status transfer. Note that the result is undefined if a previous RdReg request has not been completed. Write to specified register. Accelerate control. The link should send an AccCtrl request with Acceleration_Select = 0 (Decelerate) if it is not root and when its cycle timer has counted a 125 s interval. The SBPH400 will not employ ACK accelerated arbitration or fly-by arbitration for asynchronous packets until a subsequent Accelerate request with Acceleration_Select = 1 (Accelerate) is received or an IsoReq has been received. The link should send an Accelerate request with Acceleration_Select = 1 after it has received a cycle start packet if it has no isochronous packets to transmit in the current isochronous cycle. ignored 010 PriReq 011 FairReq 100 RdReg 101 110 WrReg AccCtrl 111 reserved 19/43 2 SBPH400-3 2.8.5 Bus request The SBPH400 obeys the rules specified in the P1394a proposal for the disposition of requests received from a link device, provided that the link device follows the P1394a rules for when it may issue requests. The link device sends the request for the bus for fair (FairReq) or priority (PriReq) access at least one clock after the interface becomes idle or during a status transfer from the SBPH400. A cycle master node uses a priority request (PriReq) to send the cycle start packet. A receive state (CTL[0:1]=10) at any time during or after the link device sends a fair or priority request transfer indicates to the link device that the request cannot yet been granted, due to the arrival of an incoming packet. If arbitration acceleration is enabled, and the incoming packet is null or has no more than 8 bits, then the SBPH400 retains the request, otherwise the request is discarded as soon as the SBPH400 determines that the incoming packet has more than 8 bits. The request always discarded if arbitration acceleration is not enabled. The link device should reissue a discarded request on the next idle or status. A link device uses the IsoReq request at any time to request the SBPH400 to send an isochronous packet. The SBPH400 will wait for a an isochronous gap before arbitrating for the bus. The SBPH400 will clear the request only when the bus has been won, or if it performs a status transfer indicating a subaction gap (this indicates an error condition and should not occur). A link device must issue a ImmReq request to send an acknowledge packet during the reception of a packet addressed to it or no later than the fourth SClk cycle after the interface went idle. As soon as the packet reception ends the SBPH400 immediately takes control of the bus and grants the bus to the link device. If the header CRC of the packet happens to be bad the link device should release the bus immediately. Note that the link device should not use this request to send another type of packet. This can be ensured by making the link device wait for 160 ns after the end of the receive packet to allow the SBPH400 to grant it the bus for the acknowledge. The bus is then released before starting another request. After the link issues a request for the access to the bus (immediate, iso, fair, or priority) it cannot issue another bus request until the SBPH400 indicates that the request is either "lost" (incoming packet, other than an ACK packet when accelerations are enabled) or "won" (grant). When a previous bus request is pending the SBPH400 ignores new bus requests. All outstanding requests are cancelled on a bus reset. 2.8.6 Register Read/Write requests For write requests, the SBPH400 takes the data field of the LREQ transfer and loads it into the addressed register as soon as the transfer is complete. For read requests, the SBPH400 returns the contents of the addressed register at the next opportunity through a 16-bit status transfer. The link device may perform a read or write register operation at any time. 20/43 2 SBPH400-3 2.8.7 Status transfer A 4-bit status transfer of S[0:3] is initiated by the SBPH400 when any of the four status bits S[0] to S[3] (as specified in Table 2.13) is set to 1. A 16-bit status transfer of s[0] to s[15] (as specified in Table 2.13 is initiated by the link in response to a register read request from the link device, or to indicate the node's new phy_ID after a bus reset during the Self_ID process. After the link interface is idle, a status transfer is initiated with the assertion of status (CTL[0:1] = 10) condition by the SBPH400. The first two bits of status information (S[0:1]) are made available on D[0:1]. The status condition is held on CTL[0:1] for the duration of transfer. The SBPH400 ensures that there is at least one clock cycle between status transfers. Table 2.13 Bit (S[n]) 0 Status bits Name ArbitrationResetGap Description This bit indicates that the SBPH400 has detected that the serial bus has been idle for an arbitration reset gap time (this is defined in the IEEE 1394 standard). This bit is used by the link device in the busy/retry state machine. This bit is reset after the status transfer or when a transfer occurs on the bus. This bit indicates that the SBPH400 has detected that the serial bus has been idle for a subaction gap time (this is defined in the IEEE 1394 standard). This bit is used by the link device to detect the end of an isochronous cycle. This bit is reset after a status transfer or when a transfer occurs on the bus. This bit indicates that the SBPH400 has entered the bus reset state. This bit is reset after a status transfer This bit is set whenever any of the interrupt-generating status bits (Loop detect, Power fail, State time-out, Port event) is set to 1. This bit is reset after a status transfer. These bits indicate the address of the SBPH400 register whose contents are being transferred to the link device These bits provide the current value of SBPH400's register. 1 SubactionGap 2 3 BusReset PHY_Interrupt 4-7 8-15 Address Data Figure 2.11 SBPH400 CTL[0:1] Status transfer timing 00 01 01 01 00 SBPH400 D[0:1] 00 S[0,1] S[2,3] S[14,15] 00 21/43 2 SBPH400-3 In the event of a packet reception during status transfer, the SBPH400 prematurely ends the transfer by removing the status indication on the CTL[0:1]. Note that any status bits transferred will be reset, even if the status transfer is prematurely terminated (i.e. if it is terminated after the transfer of S[0:1], then S[0:1] will be reset. If it is terminated after the transfer of S[0:n] where n>=3, then S[0:3] will be reset. The status transfer will be retried at the next available opportunity if it was a 16 bit status transfer, or if it was a 4 bit status transfer and at least one of the four status bits S[0] to S[3] is (still) 1. 2.8.8 Transmit The link device requests access to the serial bus through LREQ when it wants to transmit information. The SBPH400 arbitrates, using the timing algorithm appropriate to the request type, to gain access to the serial bus. After the SBPH400 wins the arbitration, it grants the bus to the link device by asserting grant on the CTL pins for one clock cycle, followed by idle for one clock cycle. When it receives control of the bus, the link may assert one cycle of idle on the CTL pins (this may be advisable when using PHY-Link isolation). While preparing data, the link device keeps the ownership of the bus by asserting hold on the CTL pins. It is not necessary for the link device to assert hold if it is ready to transmit as soon as bus is granted. When it is ready to transmit a packet, the link device asserts transmit on the CTL pins along with the first bits of the packet. After sending the last bits of the packet when the link device does not wish to concatenate another packet, the link device asserts idle on the CTL pins for two clock cycles before tristating the CTL pins. After sending the last bits of the packet when the link device wishes to concatenate another packet, the link device asserts hold on the CTL pins for one cycle, together with the speed code for the next packet, followed by a single cycle of idle before tristating the CTL pins. The link device may release the bus after the SBPH400 has asserted grant by asserting idle on the CTL pins for three cycles, and may release the bus after asserting hold by asserting idle on the CTL pins for two cycles. The hold state indicates to the SBPH400 that the link device wants to send another packet without releasing the bus (a concatenated packet). The SBPH400 responds to the hold by waiting the required minimum time and then asserts transmit as before. The speed of the concatenated packet is indicated at the time that the hold state is asserted, using the encoding specified in Table 2.14. Note that it is not permitted to transmit a S100 packet as a concatenated packet after transmitting a higher speed packet. Note that, for compatibility with 1394-1995 PHYs, P1394a requires that if "multi-speed concatenated packets" is not enabled (see Table 2.16), the speed code for any concatenated packet which is received from the link will be ignored, and the packet will be transmitted at the same speed as the packet to which it is concatenated. The SBPH400 will supply the appropriate speed code as it transmits the packet on the bus. When the link device has finished sending the last packet of the current bus ownership, it releases the bus by asserting idle on the CTL pins for two consecutive clock cycles. The transmit timing is shown in Figure 2.12. 22/43 2 SBPH400-3 Figure 2.12 Transmit timing Single Packet SBPH400 CTL[0:1] 00 11 00 ZZ ZZ ZZ ZZ ZZ ZZ ZZ ZZ ZZ SBPH400 D[0:7] 00 00 00 ZZ ZZ ZZ ZZ ZZ ZZ ZZ ZZ ZZ LINK DEVICE CTL[0:1] ZZ ZZ ZZ 00 01 01 10 10 10 00 00 ZZ LINK DEVICE D[0:7] ZZ ZZ ZZ 00 00 00 D0 D1 Dn 00 00 ZZ Optional idle cycle Concatenated packet SBPH400 CTL[0:1] ZZ ZZ ZZ 00 00 11 00 ZZ ZZ ZZ ZZ ZZ SBPH400 D[0:7] ZZ ZZ ZZ 00 00 00 00 ZZ ZZ ZZ ZZ ZZ LINK DEVICE CTL[0:1] 10 01 00 ZZ ZZ ZZ ZZ 00 01 01 10 10 LINK DEVICE D[0:7] Dn SP 00 ZZ ZZ ZZ ZZ 00 00 00 D0 D1 Optional idle cycle 23/43 2 SBPH400-3 2.8.9 Receive When the SBPH400 detects the "data-on" state on the serial bus, it starts the receive operation by asserting receive on the CTL pins and `1' on each of the D pins. The SBPH400 indicates the beginning of the packet by placing on the D pins the speed code, as defined in Table 2.14. The speed code is followed by the contents of the received packet using the appropriate range of D pins (D[0:1] for S100, D[0:3] for S200 and D[0:7] for S400). The CTL pins will remain in the receive state until the last symbol of the packet has been transferred to the link device. The end of the packet is indicated by the CTL pins going back to the idle state. Note that the speed code is part of the link interface protocol and is not included in the calculation of CRC. Note that P1394a requires that, for compatibility with 1394-1995 PHYs, if "multi-speed concatenated packets" is not enabled (see Table 2.16), any concatenated packet which is received without a speed code is assumed to be transmitted at the same speed as the packet to which it is concatenated. If the SBPH400 detects such a packet then it will indeed make this assumption, and will supply the appropriate speed code in front of the packet as it transfers it to the link device. The receive timing is shown in Figure 2.14. Table 2.14 Speed codes on the LINK-PHY interface D[0:7] 00000000 01000000 01010000 11111111 Data Rate S100 S200 S400 "data-on" indication Figure 2.13 Receive timing 00 10 10 10 10 10 10 00 00 CTL[0:1] D[0:7] (hex) 00 FF FF SP D0 D1 Dn 00 00 24/43 2 SBPH400-3 2.8.10 SBPH400 registers The accessible SBPH400 registers are listed in Table 2.15. The descriptions of the fields are given in Table 2.16. Table 2.15 Address 0000 0001 0010 0011 0100 0101 0110 0111 1000-1111 Accessible SBPH400 register 0 RHB 1 IBR 111b (Extended) Max speed Link_active Resume_ int C ISBR rsv rsv 000b (Jitter) Loop Pwr-fail rsv rsv Register 0-7 [Page_select] State t_out 2 3 Physical_ID 4 Gap_count 0011b (Total ports) 0000b (Delay) Power_class Port Enab_ Enab_ event accel multi Port_select 5 6 R 7 PS Page_select Table 2.16 Field Physical_ID R PS RHB SBPH400 register fields Size 6 1 1 1 Type Description R The address of the node determined during self-identification. R R R/W When set to 1, indicates that the node is the root. Cable power status. This value always reflects the filtered voltage sensed on the CPS pin. Root Hold-off bit. When set to 1, instructs the node to attempt to become the root during the next Tree-ID process. Value on power reset is 0. Initiate Bus Reset bit. When set to 1, instructs the SBPH400 to initiate a bus reset for 166 sec immediately. Always reads as zero. Arbitration timer setting. Used to optimize gap times based on the topology of the network. Always reads as 111b to indicate use of the extended PHY register map Always reads as 3 010b (maximum speed is S400) 0000b (maximum repeater delay is 144 ns) Set or cleared by software. Note that the value of the L bit transmitted in the self-ID packet is the AND of the Link_active bit and the LPS pin. Initialized to the value of the LACT configuration pin on power reset. Contender. Set or cleared by software to control the value of the C bit transmitted in the self-ID packet. On power reset this is initialized to the value of the CMC pin. 000b (fastest and slowest repeater delay differ by 20ns) IBR Gap_Count Extended Total_Ports Max_Speed Delay Link_active 1 6 3 4 3 4 1 R/W R/W R R R R R/W C 1 R/W Jitter 3 R 25/43 2 SBPH400-3 Table 2.16 Field Power_class SBPH400 register fields (continued) Size 3 Type Description R/W Power class. Set by software to control the value of the pwr field transmitted in the self-ID packet. On power reset, this is initialized to the values of the PC[0:2] pins. Resume interrupt enable. When set to 1, the SBPH400 sets Port_event to 1 if resume operations commence for any port. Initialized to 0 on power reset. Initiate short (arbitrated) bus reset. Unless entry to suspend or resume is in progress for any of the SBPH400's ports, a write of one to this bit requests the SBPH400 to arbitrate after a sub-action gap and issue a short bus reset. Any outstanding fair request is abandoned. Unlike fair bus requests, the request persists until won, or until a time-out forces a long bus reset. Always reads as 0. Loop detect interrupt. Set to one when the Tree-ID process detected a loop. The PHY_interrupt status bit is set when this bit transitions from 0 to 1. A register write with the value 1 in the field corresponding to this bit clears the register to zero. A register write with a value 0 to the field corresponding to this bit is ignored. Cable power fail interrupt. Set when the PS register changes from 1 to 0. The PHY_interrupt status bit is set when this bit transitions from 0 to 1. A register write with the value 1 in the field corresponding to this bit clears the register to zero. A register write with a value 0 to the field corresponding to this bit is ignored. State time-out interrupt. Set to 1 when the arbitration state machine has been in any state other than Idle, Tree-ID state T0, Transmit or Receive for longer than 300sec. The PHY_interrupt status bit is set when this bit transitions from 0 to 1. A register write with the value 1 in the field corresponding to this bit clears the register to zero. A register write with a value 0 to the field corresponding to this bit is ignored. Port event detect. Set to 1 when any of Connected, Bias, Disabled or Fault change for a port whose Int_enable bit is one, or when resume operations commence for any port and Resume_int is set to 1. The PHY_interrupt status bit is set when this bit transitions from 0 to 1. A register write with the value 1 in the field corresponding to this bit clears the register to zero. A register write with a value 0 to the field corresponding to this bit is ignored. Enable ACK accelerated and fly-by arbitration. Initialized to 0 on power reset. Enable multi-speed packet concatenation. Initialized to 0 on power-on reset. Resume_int 1 R/W ISBR 1 R/W Loop 1 R/W Pwr_fail 1 R/W State t_out 1 R/W Port_event 1 R/W Enab_accel Enab_multi 1 1 R/W R/W 26/43 2 SBPH400-3 Table 2.16 Field Page_select SBPH400 register fields (continued) Size 3 Type Description R/W Select extended register page for a subsequent PHY register read or write operation. 0 = Port Status Page 1 = Product Identification Page Initialized to 0 on power reset. Identify the port for the selected register page for a subsequent PHY register read or write operation. For values 0, 1 and 2, the page is as defined in Table 2.17. For all other values, a subsequent write to any register in the page has no effect, and a subsequent read from any register in the page returns zero. Initialized to 0 on power reset. Field reserved in P1394a for future use. No effect on write, always reads as zero. Port_select 4 R/W rsv R/W Table 2.17 Address 1000 1001 1010-1111 Port status page 0 AStat Negotiated_speed 1 2 BStat Int_ enable rsv 3 4 Child Fault 5 Con 6 Bias rsv 7 Dis Table 2.18 Field AStat BStat Child Con Bias Dis Port status register fields Size 2 2 1 1 1 1 Type R R R R R R/W Description TPA line state on the selected port (112 = Z, 012 = 1,102 = 0, 002 = invalid). TPB line state on the selected port (112 = Z, 012 = 1,102 = 0, 002 = invalid). If 1 the corresponding port is a child, else parent (only valid after Self_ID) If 1 the corresponding port is connected, 0 if the port is disconnected. Reflects the Bias detected status on the port (1 = Bias detected) after filtering The port is disabled when this bit is set to 1, and enabled when this bit is set to 0. Initialized to the value of the PDISABLE pin on power reset. The negotiated speed for this port (only valid after Self_ID). Possible values are 000b (S100), 001b (S200), 010b (S400) Negotiated_speed 3 R 27/43 2 SBPH400-3 Table 2.19 Address 1000 1001 1010 0 1011 1 1100 1 1101 0 1110 0 1111 0 0 0 0 0 Major revision (1) 1 X 0 1 0 0 Product identification page 0 1 2 3 4 5 1 (Compliance level = P1394a) rsv Manufacturer's OUI (MSB - 00 ) 16 0 0 0 0 Manufacturer's OUI (8016) 0 0 0 0 Manufacturer's OUI (LSB - E1 ) 16 1 0 0 0 0 0 0 X 0 1 Division (0816) 1 0 Prod-MSB (0) 0 0 0 X 1 X 0 0 0 0 6 7 Product- LSB (0116) 0 0 Minor revision (see note) The 6-bit Division field identifies the product group within SGS-THOMSON. The 10 bit Product field identifies the product within the Division. The Major revision will increment with each major revision of the device. The minor revision will start at 0 for each major revision and will increment with mask fixes, etc. Note: The Division and Product fields are identical to the corresponding fields when accessing the SBPH400 via the JTAG Test Access Port. 2.9 Reset and initialization 2.9.1 Power on Figure 2.14 SBPH400 reset timing E x t os c illator ( w here use d) R e set# SBP H 400 operational 500 s ec 100 ns m in (V D D present) 28/43 2 SBPH400-3 On Power on, the Reset# pin should be held low for 2ms to allow supplies to settle. To reset the device when VDD is already present, the Reset# pin should be held low until a minimum of 100ns after the external oscillator (if used) is started and operating within specification. The SBPH400 will wait for approximately 500 sec to allow its internal clocking circuitry to stabilize. At the end of the nominal 500 sec period, the SBPH400 becomes fully operational. Prior to the SBPH400 becoming fully operational, all outputs on the PHY/Link interface are held in high impedance, as are the TpBias and TPA and TPB pins for all three ports. When the SBPH400 becomes fully operational, it senses the ISO, PC[0:2], CMC, LACT and PDISABLE. If ISO = 0, then all outputs on the PHY/Link interface are taken to zero, and the SBPH400 will also then respond to LPS if this pin is active (see 2.9.2). 2.9.2 PHY/Link Interface start-up The PHY/Link interface is controlled by the link device via the LPS signal. In order to indicate to the SBPH400 that the link interface is active, LPS should either be held to a logic 1 (possibly by connecting to the VD D supplying the link layer device) or be connected to a pulsed output which meets the specification shown in Figure 2.15 and Table 2.20. If neither of these is true after power reset (see above), then no signal is considered to be received on LPS, the link interface continues to be disabled, and the SBPH400 operates as a PHY repeater. Figure 2.15 LPS timing (isolated interface) LPS (isolated) TLPSH TLPSL Table 2.20 Symbol TLPSL TLPSH LPS timings Parameter LPS low time (isolated interface) LPS high time (Isolated interface) Unit ns ns Min 90 90 Typ Max 1000 1000 When LPS is asserted, the PHY/Link interface starts as illustrated in Figure 2.16 29/43 2 SBPH400-3 Figure 2.16 LPS SC lk (direct) PHY/Link interface start-up timing SC lk (is o) C [0:1], D[0:7] (direct) C [0:1], D[0:7] (iso) 5 ns (m in) 40 - 60 ns (S BP H 400 operational) 500 s nom inal (SBPH 400 suspended) When LPS is reasserted, the SBPH400 resumes sending SCLK (if necessary) after 40-60 ns if the SBPH400 is operational, or otherwise after a nominal period of 500 sec if LPS is used to bring the SBPH400 out of suspend. If the interface is operating in direct mode (ISO = 0) then Ctl[0:1] and D[0:7] are held zero. If the interface is operating in isolated mode (ISO = 1), then the SBPH400 maintains high impedance for the first cycle of SCLK, asserts zeros on Ctl[0:1] and D[0:7] for the second cycle of the resumed SCLK, and maintains high impedance for cycles 3 to 7. The SBPH400 asserts a nominal receive indication on Ctl[0:1] for the eigth cycle, while simultaneously indicating data_prefix on D[0:7] (all 1's). This is maintained for further cycles if the SBPH400 is in a state where it would otherwise be transferring data. 2.9.3 PHY/Link interface reset and disable The PHY-Link interface may be reset by taking LPS low for a minimum of 2.75 sec, but less than 25 sec. During this time the Ctl[0:1] and D[0:7] signals are disabled, but the SBPH400 continues to provide SCLK. If neither of these is true for a period greater than 25 sec, then no signal is considered to be received on LPS, the link interface is disabled, and the SBPH400 operates as a PHY repeater. When the link interface is disabled, all outputs are held to zero if the interface is operating in direct mode (ISO = 0), otherwise (ISO = 1) all outputs are maintained in high impedance. The 30/43 2 SBPH400-3 timing parameters are given in Table 2.21, and the signal relationships are illustrated in Figure 2.17 and Figure 2.18. Table 2.21 Symbol TLPS_RESET TLPS_DIS TRESTORE PHY/Link interface reset and disable timing parameters Parameter Time for SBPH400 to recognize LPS logically deasserted and reset the interface Time for SBPH400 to recognize LPS logically deasserted and disable the interface Time to permit the optional differentiator and isolation circuits to restore during an interface reset Unit s s s Min 1.2 25 15 Typ Max 2.75 30 20 Figure 2.17 SCLK PHY-Link reset timing T LPS_RESET TRESTORE LPS LPS (isolated) DATA CTL LREQ Figure 2.18 SCLK T LPS_DISABLE TRESTORE LPS LPS (isolated) DATA CTL LREQ PHY-Link disable timing 31/43 2 SBPH400-3 2.9.4 LKON (link on) The LKON pin is used as an output to indicate that the SBPH400 has received a Link_On packet. If the there is no signal on the LPS pin (indicating that the link device is not currently powered) or the Link_active register is zero (link interface turned off by software) and a Link_On packet is received addressed to the node, then a 6.144 MHz signal is output on the LKON pin. This signal is turned off within 500 ns when both there is a signal received on LPS and the Link_active register is 1. 2.10 ISO (isolation) The SBPH400 supports the use of an isolation barrier between the chip and a link device. If ISO is set high, then the an internal pulsed differentiating function is used on the CTL[0:1] and the D[0:7] pins when used as outputs. Appropriate threshold circuitry is included on these pins when used as inputs to interpret differentiated signals correctly. The differentiation circuitry transmits a 1 or a 0 when there is a logical transition to 1 or 0 respectively, otherwise the output is set to high impedance. This is shown in Table 2.22. This allows an arbitrary sequence of 1's or 0's to be transmitted across an AC coupled isolation interface. Table 2.22 Output differentiation for isolation Next Previous 0 1 Z 0 1 Z 0 1 2.11 CPS (cable power status) This input should be connected to the power supply provided from the cable via an external series 400 KOhm resistor. The internal logic associated with this pin provides a nominal filtered cable power fail voltage (as applied to the external resistor) threshold of 6.25 volts. The internal logic will report 1 in the PS register when the external voltage on the resistor exceeds the threshold, and will report 0 in the PS register when the external voltage falls below the threshold. A transition from 1 to 0 on the value in the PS register causes the Pwr_fail register to be set to 1, which in turn will cause a link status transfer with the PHY_Interrupt bit set if the Link interface is active, otherwise will cause a LinkOn signal. Appropriate protection is incorporated in the SBPH400 for cable power voltages within the 1394 specification applied via the external series resistor. 32/43 2 SBPH400-3 3 Pin Description Pin description - normal operation Pin number 15, 23, 25, 80 6, 24, 26, 79 38 64 I I I/O Description Analog Ground Analog Supply Voltage External 24.576 MHz oscillator input (optional, see QX0) Configuration Manager Contender. Used to initialize the C register at power-on reset. It should be programmed by connecting it to VDD (C=1) or GND (C=0). Cable power status. Control signals for PHY-Link interface Data signals for PHY-Link interface Digital Ground Table 3.1 Pin name AGND AVDD CLK24 CMC CPS CTL[0:1] D[0:7] DGND 78 46, 45 59 - 51 12, 13, 14, 27, 28, 29, 30, 31, 34, 40, 43, 48, 49, 50, 61, 69, 70, 72, 73, 74 32, 33, 47, 71 68 I I/O I/O DVDD ISO Digital Supply Voltage I Link interface isolation logic control. Logic level 1 on this pin enables the isolation logic, 0 disables the isolation logic (normally tied to VDD or GND as required) Link Active. Used to initialize the Link Active register on power reset. It should be programmed by connecting it to V (Link Active DD = 1) or GND (Link Active = 0). Link on o/p Link power status. Link request to SBPH400 Inputs not used in normal operation, may be connected to V or DD GND, or left unconnected. Oscillator ground Oscillator supply voltage Power Class input Ports disable. Used to initialize all three ports as disabled on power-on reset. 24.508 MHz crystal input 0 (optional, see CLK24) 24.508 MHz crystal input 1 (optional, left unconnected if not used, must not be taken to power or GND) External resistor for bias current setting Reset. Taking this signal low causes all activity to cease. When this signal is taken high, all appropriate registers and outputs are initialized to their power reset values and a 166sec bus reset is initiated. LACT 41 I LKON LPS LREQ N/C OGND OVDD PC[0:2] PDISABLE QX0 QX1 R[0:1] RESET# 42 62 44 35, 75, 76 37 39 65 - 67 63 38 36 22, 21 77 O I I I I I I I I I I 33/43 2 SBPH400-3 Table 3.1 Pin name SCLK TPA1 TPA1# TPB1 TPB1# TPA2 TPA2# TPB2 TPB2# TPA3 TPA3# TPB3 TPB3# TPBIAS1 TPBIAS2 TPBIAS3 Pin description - normal operation (continued) Pin number 60 1 2 3 4 7 8 9 10 16 17 18 19 5 11 20 I/O O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O O O O Description Clock to Link device - 49.152 MHz Positive signal of cable pair A of port 1 Negative signal of cable pair A of port 1 Positive signal of cable pair B of port 1 Negative signal of cable pair B of port 1 Positive signal of cable pair A of port 2 Negative signal of cable pair A of port 2 Positive signal of cable pair B of port 2 Negative signal of cable pair B of port 2 Positive signal of cable pair A of port 3 Negative signal of cable pair A of port 3 Positive signal of cable pair B of port 3 Negative signal of cable pair B of port 3 Cable Termination voltage source for port 1 Cable Termination voltage source for port 2 Cable Termination voltage source for port 3 Some pins on the SBPH400 have different functionality in various test modes. Table 3.2 identifies these pins for ease of reference, but the full description of the associate functions is not included in this data sheet. Table 3.2 Pin name CLK98 PLLDIS SCI[0:2] SCO[0:2] TCK TDI TDO TEST ENABLE TESTMODE TMS TRST# Pin description - test pins Pin number 35 49 76, 67, 65 68, 66, 64 72 75 63 70 30 69 40 I/O I I I I I I O I I I I Description 98.304 MHz Oscillator input, used when PLLDIS is tied to V DD Internal PLL disable pin. Tie to V to disable internal PLL. DD Used to serially shift data into the SBPH400 for production test Used to serially shift data out of the SBPH400 for production test Test clock. Used to clock data into and out of the SBPH400 during operation of the Test Access Port or production test. Test Data Input. Used to serially shift test data and test instructions into the SBPH400 during TAP operations. Test Data Output. Used to serially shift test data and test instructions out of the SBPH400 during TAP operations. Reserved for production test Reserved for production test Test Mode Select. This signal controls the state of the TAP controller within the SBPH400. Test Reset. Resets the TAP controller. 34/43 SBPH400-3 4 Electrical Specifications 4.1 Absolute maximum ratings Table 4.1 Symbol VDD VINL VINH Absolute maximunm ratings Parameter Supply Voltage Logic signal input low level Serial signal input level TTL input signals Units V V V V C C -65 Min 0 -0.5 VDD+0.5 5.5 260 150 Max 4 TCMAX Maximum assembly temperature (for 10 seconds maximum) Storage temperature Note: Stresses greater those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not guaranteed. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. During overload conditions VIN>V DD or V IN Table 4.2 Symbol VDD TA IDD Operating conditions Parameter Supply Voltage Supply Ripple (DC to 1 GHz) Ambient temperature Supply current @ 25C, 3.3 volts with parallel outputs loaded by 10pF Units V mV C mA 0 27 300 Min 3.0 Typ 3.3 Max 3.6 100 70 35/43 SBPH400-3 4.3 DC characteristics The following values apply to the analog signals TPAn, TPAn# Table 4.3 Symbol VOD V(OFF) ZIC ZID VARB1 VARBZ VARB0 VISWS VIT200 VIT400 DC characteristics for TPAn, TPAn# Parameter Differential output peak-to-peak voltage, terminated by 55 load Off-state common mode output voltage Common mode impedance (driver disabled) Differential impedance (driver disabled) Serial input differential amplitude for arbitration '1' detect Serial input differential amplitude for arbitration 'Z' detect Serial input differential amplitude for arbitration '0' detect Serial input differential amplitude (absolute value) during data transmission Speed signal threshold voltage relative to TPBIAS (TPBIAS-TPA common mode voltage), S200 Speed signalling threshold voltage relative to TPBIAS (TPBIAS-TPA common mode voltage), S400 Units mV mV k pF k pF mV mV mV mV mV mV 118 139 445 20 6 168 -89 89 -168 260 264 682 Min 172 Typ Max 265 20 24 6 The following values apply to the analog signals TPBn, TPBn# Table 4.4 Symbol VOD V(OFF) ZIC VTH_BIAS_CON VTH_BIAS_DIS ICM100 ICM200 ICM400 VARB1 VARBZ DC characteristics for TPBn, TPBn# Parameter Units Differential output peak-to-peak voltage, terminated by mV 55 load Off-state common mode output voltage mV Common mode impedance (driver disabled) TpBias connect threshold TpBias disconnect threshold Common mode output current, speed signalling off or speed signal = S100 Common mode output current, speed signal = S200 Common mode output current, speed signal = S400 Serial input differential amplitude for arbitration '1' detect Serial input differential amplitude for arbitration 'Z' detect k pF V V mA mA mA mV mV Min 172 Typ Max 265 20 20 1.0 -0.81 -2.53 -8.10 168 -89 89 0.6 0.44 -4.84 -12.4 24 36/43 SBPH400-3 Table 4.4 Symbol VARB0 VISWS DC characteristics for TPBn, TPBn# (continued) Parameter Serial input differential amplitude for arbitration '0' detect Serial input differential amplitude (absolute value) during data transmission Units mV mV 118 Min Typ Max -168 260 The following values apply to the appropriate device pins in each case Table 4.5 Symbol VOH VOHD VOL VOLD VIH VIL II IPU IPD IOZ VLIT_ISO+ VLIT_ISOVIT_ISO+ VIT_ISOVCPS VO DC characteristics Parameter High level output voltage (IOH = -4 mA) High level output voltage (IOH = -9 mA, CTL[0:1], D[0:7], SCLK and LKON outputs) Low level output voltage (I = 4 mA) OL Low level output voltage (I = 9 mA, CTL[0:1], OL D[0:7], SCLK and LKON outputs) High level input voltage Low level input voltage Input current for CMC, LREQ, LPS, PC[0:2], RESET#, ISO, PWRDWN, EXTCLK inputs Input current for TDI, TMS, TRST# inputs Input current for TESTMODE, BISTRUN, TCK inputs OFF-state output current, CTL[0:1], D[0:7], LKON, TDO Positive input threshold voltage on LPS input (VDD=3.3V) Negative input threshold voltage on LPS input (VDD=3.3V) Positive input thresholds voltage, CTL[0:1], D[0:7], LREQ inputs Negative input thresholds voltage, CTL[0:1], D[0:7], LREQ inputs Threshold input voltage on CPS input as applied via an external 400 K Ohm resistor TPBIAS output voltage Units V V V V V V A A A mA V V V V V V 1.0 VDD/2 +0.3 VDD/2 -0.8 5.0 1.665 6.25 1.85 VDD/2 +0.8 VDD/2 -0.3 7.5 2.015 2.6 -10.0 -125 +25 -10.0 0.7 +10.0 - 25 +125 +10.0 1.8 Min 2.8 VDD-0.4 0.4 0.4 Typ Max 37/43 SBPH400-3 5 AC characteristics AC characteristics (analog interfaces) Parameter Transmit jitter (TPA, TPB) Transmit Skew Transmit rise time Transmit fall time Measured Condition Unit ns ns Rl = 56, Cl = 10pF Rl = 56, Cl = 10pF ns ns 0.5 0.5 Min Typ Max 0.15 0.10 1.2 1.2 Table 5.1 Symbol between TPA and TPB 10% to 90% 10% to 90% tr tf Figure 5.1 Digital interface timing SCLK tpsu tph D, CTL, LREQ SCLK tlsu tlh D, CTL SBPH400 to Link device timing Link device to SBPH400 device timing (NB SCLK runs from SBPH400 to link device) SCLK td1 CTL DATA LPS Link device to SBPH400 timing at the link (Note: SCLK runs from the SBPH to the link device) td2 td3 38/43 SBPH400-3 Table 5.2 AC characteristics (digital interfaces) Measured Condition Unit 50% to 50% ns ns ns ns ns Min 6 0 6.5 0.5 1 10 Typ Max Symbol Parameter tpsu D, CTL, LREQ input setup to SCLK output tph tlsu tlh td1 D, CTL, LREQ hold from SCLK output 50% to 50% D, CTL output setup to SCLK 50% to 50% D, CTL output hold from SCLK Delay time, SCLK input high to initial instances of D, CTL and LREQ outputs valid Delay time, SCLK input high to subsequent instances of D, CTL and LREQ outputs valid 50% to 50% 50% to 50% td2 50% to 50% ns 1 10 td3 Delay time, SCLK input high to D, CTL 50% to 50% and LREQ outputs invalid (tri-state) ns 1 10 Table 5.3 Fextclk Dextclk Jextclk FSCLK DSCLK Clock and reset parameters Measured 50% to 50% 50% to 50% 50% to 50% ms Condition Unit Min Typ Max External clock Frequency External clock duty cycle External clock Jitter peak to peak SCLK frequency SCLK duty cycle Power-on reset time, RESET# input 24.576 MHz +/- 2.45 KHz 45% 55% 100 pS peak to peak Fextclk x 2 45% 2 55% Symbol Parameter 39/43 SBPH400-3 6 Package Specifications The S B PH 4 00 -3 is available in a 80 pin plastic thin quad flat pack Figure 6.1 Normal operation pinout for 80 pin 12mm x 12mmTQFP AGND AVDD CPS RESET# N/C N/C DGND DGND DGND DVDD DGND DGND ISO PC2 PC1 PC0 CMC PDISABLE LPS DGND TPA1 TPA1# TPB1 TPB1# TPBIAS1 AVD D TPA2 TPA2# TPB2 TPB2# TPBIAS2 DGND DGND DGND AGND TPA3 TPA3# TPB3 TPB3# TPBIAS3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 SBPH400-3 53 52 51 50 12mm x 12mm 49 48 47 80 lead TQFP 46 45 44 43 42 41 21 22 2324 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 R1 R0 AGND AVDD AGND AVD D DGND DGND DGND DGND DGND DVDD DVDD DGND N/C QX1 QX0/CLK24 OVDD DGND OGND SCLK DATA0 DATA1 DVDD DATA2 DATA3 DATA4 DATA5 DATA6 DATA7 DGND DGND DGND DVDD CTL0 CTL1 LREQ DGND LKON LACT 40/43 SBPH400-3 Figure 6.2 Data for 80 pin 12mm x 12mmTQFP BODY + 2.00 mm FOOTPRINT DIMS A A1 A2 D D1 E E1 L e b 0 ddd ccc MAX MAX .13 .10 TOLS/LEADS 64L 1.60 80L MAX + .05 + .20 + .10 + .20 + .10 +1.5/-.10 BASIC + .05 .65 .30 .05 MIN /.15 MAX 1.40 14.00 12.00 14.00 12.00 .60 .50 .22 00 - 70 .08 .08 Body: 12 x 12 x 1.60 mm D D1 D3 A2 A A1 33 32 0.10mm Seating Plane N 48 49 A1 A2 A 1 b B b E3 E1 B E1 E E 64 1 e 16 17 C 1.0 ref L L L1 e K TF6 Q4 P 41/43 SBPH400-3 7 Application Circuit VD D Ca ble Po w er 10 0K 0. 1 F N /C u ser setting s 40 0K C able 55 55 5K VDD N /C VDD 80 79 7 8 77 7 6 75 7 4 73 7 2 71 70 69 68 67 66 65 64 6 3 62 61 AGND AVDD CPS RESET# N/C N/C DGND DGND DGND DVDD DGND DGND ISO PC2 PC1 PC0 CMC PDISABLE LPS DGND 250pF 1 TPA1 TPA1# TPB1 TPB1# TPBIAS1 AV DD TPA2 TPA2# TPB2 TPB2# TPBIAS 2 DG ND DG ND DGND AGND TPA3 TPA3 TPB3 TPB3# TPBIAS 3 AGND AVDD AGND AVDD DGND DGND DGND DGND DGND DVDD DVDD DGND SCLK D ATA 0 D ATA 1 D VD D D ATA 2 D ATA 3 D ATA 4 D ATA 5 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 Cable 55 55 VD D 2 3 4 5 VDD LIN K IN T E R FA C E (* ) VD D 3 00nF - 1 F G ro und 6 7 8 9 F or TPA 2/A2 *, TP B2 /B 2*, T PB IA S2, T PA 3 /A 3* , TP B 3/B 3* a nd T PB IA S3 c om po nent con ne ctio ns are the sam e as T P A 1/A 1 *, TP B1 /B 1* and TP B IA S 1 . 10 11 12 13 14 15 16 17 18 19 20 SBPH400-3 D ATA 6 D ATA 7 D GN D D GN D D GN D D VD D CTL0 CTL1 LREQ D GN D LKON LACT OVDD DGND QX0/CLK2 4 OGND QX1 N/C 21 R1 22 R0 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 3.0K +/- 1% VDD N /C V DD VD D N C* * E xternal 24.576 M H z Cr ystal O R E xternal oscill ator option (* ) Iso lation circu it use d if ISO pin enab le (* *) A ll N /C (no n connec ted ) p ins, B UT N O T N C ** (p in 3 6) may b e con nec ted to e ither G N D o r V D D Note: Isolation components when using an isolated PHY-Link interface not shown; 42/43 Notes Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supercedes and replaces all information previously supplied. SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without the express written approval of SGS-THOMSON Microelectronics. (c)1998 SGS-THOMSON Microelectronics - All rights reserved. GLINTTM is a Trademark of BULL S.A. This circuit uses patents licenced by BULL S.A. SGS-THOMSON Microelectronics Group of Companies Australia - Brazil - Canada - China - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A. 43/43 3 |
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