ISO2-CMOS ST-BUSTM Family MT9173/74 Digital Subscriber Interface Circuit with RxSB Digital Network Interface Circuit with RxSB Data Sheet Features December 2005 • Receive sync output pulse • Full duplex transmission over a single twisted pair • Selectable 80 or 160 kbit/s line rate • Adaptive echo cancellation • Up to 3 km (9173) and 4 km (9174) loop reach • ISDN compatible (2B+D) data format • Transparent modem capability • Frame synchronization and clock extraction • Zarlink ST-BUS compatible • Low power (typically 50 mW), single 5 V supply Ordering Information MT9173AE MT9173AN MT9173AP MT9173AE1 MT9173AP1 MT9173AN1 MT9174AE MT9174AN MT9174AP Description • TDD Digital PCS (DECT, CT2, PHS) base stations requiring cell synchronization • Digital subscriber lines • High speed data transmission over twisted wires • Digital PABX line cards and telephone sets • 80 or 160 kbit/s single chip modem CDSTi/ CDi F0/CLD Transmit Interface Control Register C4/TCK MS0 MS1 MS2 Transmit/ Clock Receive Timing & Control Tubes Tubes Tubes Tubes Tubes Tape & Reel Tubes Tubes Tubes -40°C to +85°C The MT9173 (DSIC) and MT9174 (DNIC) are functionally identical to the MT9171/72 except for the addition of one feature. The MT9173/74 include a digital output pin indicating the temporal position of the received "SYNC" bit of the biphase transmission. This feature is especially useful for systems such as PCS wireless base station applications requiring close synchronization between microcells. Applications DSTi/Di 24 Pin PDIP 24 Pin SSOP 28 Pin PLCC 24 Pin PDIP* 28 Pin PLCC* 24 Pin SSOP* 24 Pin PDIP 24 Pin SSOP 28 Pin PLCC *Pb Free Matte Tin Prescrambler The MT9173 and MT9174 are identical except for the MT9173 having a shorter loop reach. The generic "DNIC" will be used to reference both devices unless otherwise noted. The MT9173/74 are fabricated in Zarlink’s ISO2-CMOS process. Differentially Encoded Biphase Transmitter Scrambler Transmit Timing — ∑ DPLL + MUX Receive Filter LOUT LOUT DIS VBias Address Echo Canceller Error Signal Echo Estimate Master Clock Phase Locked Transmit Filter & Line Driver Precan -1 +2 Sync Detect LIN RegC Status Receive OSC2 DSTo/Do CDSTo/ CDo RxSB Receive Interface DePrescrambler Descrambler VDD VSS Differentially Encoded Biphase Receiver VBias VRef Figure 1 - Functional Block Diagram 1 Zarlink Semiconductor Inc. Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc. Copyright 1999-2005, Zarlink Semiconductor Inc. All Rights Reserved. OSC1 MT9173/74 VRef VBias LOUT NC VDD LIN TEST Data Sheet 4 3 2 1 28 27 26 VDD LIN TEST LOUT DIS Precan OSC1 NC OSC2 C4/TCK F0o/RCK DSTi/Di DSTo/Do MS2 NC MS1 MS0 RegC RxSB F0/CLD 5 6 7 8 9 10 11 ² 12 13 14 15 16 17 18 24 23 22 21 20 19 18 17 16 15 14 13 25 24 23 22 21 20 19 NC LOUT DIS Precan OSC1 OSC2 NC C4/TCK CDSTi/CDi CDSTo/CDo VSS DSTo/Do DSTi/Di F0o/RCK NC 1 2 3 4 5 6 7 8 9 10 11 12 LOUT VBias VRef MS2 MS1 MS0 RegC RxSB F0/CLD CDSTi/CDi CDSTo/CDo VSS 24 PIN PDIP/ SSOP 28 PIN PLCC Figure 2 - Pin Connections Pin Description Pin # Name Description 24 28 1 2 LOUT Line Out. Transmit Signal output (Analog). Referenced to VBias. 2 3 VBias Internal Bias Voltage output. Connect via 0.33 µF decoupling capacitor to VDD. 3 4 VRef Internal Reference Voltage output. Connect via 0.33 µF decoupling capacitor to VDD. 4,5, 6 5,7, 8 7 9 RegC Regulator Control output (Digital). A 512 kHz clock used for switch mode power supplies. Unused in MAS/MOD mode and should be left open circuit. 8 10 RxSB Receive Sync Bit output (Digital). In DN mode, this output is held high until receive synchronization occurs (i.e., until the sync bit in Status Register =1). Once low, indicating synchronized transmission, a high going pulse (6.24 µs wide pulse @ 160 kb/s and 12.5 µs wide @ 80 kb/s) indicates the temporal position of the receive "SYNC" bit in the biphase line transmission. Inactive and low in MOD mode. 9 11 F0/CLD Frame Pulse/C-Channel Load (Digital). In DN mode a 244 ns wide negative pulse input for the MASTER indicating the start of the active channel times of the device. Output for the SLAVE indicating the start of the active channel times of the device. Output in MOD mode providing a pulse indicating the start of the C-channel. 10 12 CDSTi/ CDi Control/Data ST-BUS In/Control/Data In (Digital). A 2.048 Mbit/s serial control & signalling input in DN mode. In MOD mode this is a continuous bit stream at the bit rate selected. 11 13 CDSTo/ CDo Control/Data ST-BUS Out/Control/Data Out (Digital). A 2.048 Mbit/s serial control & signalling output in DN mode. In MOD mode this is a continuous bit stream at the bit rate selected. 12 14 VSS 13 15 MS2-MS0 Mode Select inputs (Digital). The logic levels present on these pins select the various operating modes for a particular application. See Table 1 for the operating modes. Negative Power Supply (0 V). DSTo/Do Data ST-BUS Out/Data Out (Digital). A 2.048 Mbit/s serial PCM/data output in DN mode. In MOD mode this is a continuous bit stream at the bit rate selected. 2 Zarlink Semiconductor Inc. MT9173/74 Data Sheet Pin Description (continued) Pin # Name Description DSTi/Di Data ST-BUS In/Data In (Digital). A 2.048 Mbit/s serial PCM/data input in DN mode. In MOD mode this is a continuous bit stream at the bit rate selected. 24 28 14 16 15 17 F0o/RCK Frame Pulse Out/Receive Bit Rate Clock output (Digital). In DN mode a 244 ns wide negative pulse indicating the end of the active channel times of the device to allow daisy chaining. In MOD mode provides the receive bit rate clock to the system. 16 19 C4/TCK 17 21 OSC2 Oscillator Output. CMOS Output. 19 22 OSC1 Oscillator Input. CMOS Input. D.C. couple signals to this pin. Refer to D.C. Electrical Characteristics for OSC1 input requirements. 20 23 Precan Precanceller Disable. When held to Logic ’1’, the internal path from LOUT to the precanceller is forced to VBias thus bypassing the precanceller section. When logic ’0’, the LOUT to the precanceller path is enabled and functions normally. An internal pulldown (50 kΩ) is provided on this pin. 18 1,6, 18, 20, 25 NC 21 24 22 26 TEST 23 27 LIN Receive Signal input (Analog). 24 28 VDD Positive Power Supply (+5 V) input. Data Clock/Transmit Baud Rate Clock (Digital). A 4.096 MHz TTL compatible clock input for the MASTER and output for the SLAVE in DN mode. For MOD mode this pin provides the transmit bit rate clock to the system. No Connection. Leave open circuit LOUT DIS LOUT Disable. When held to logic “1”, LOUT is disabled (i.e., output = VBias). When logic “0”, LOUT functions normally. An internal pulldown (50 kΩ) is provided on this pin. Test Pin. Connect to VSS. F0 C4 DSTi B17 B16 B15 B14 B13 B12 B11 B10 B17 DSTo B17 B16 B15 B14 B13 B12 B11 B10 B17 F0o Channel Time 0 Figure 3 - DV Port - 80 kbit/s (Modes 2, 3, 6) 3 Zarlink Semiconductor Inc. MT9173/74 Data Sheet F0 C4 DSTi B17 B16 B15 B14 B13 B12 B11 B10 B27 B26 B25 B24 B23 B22 B21 B20 B17 DSTo B17 B16 B15 B14 B13 B12 B11 B10 B27 B26 B25 B24 B23 B22 B21 B20 B17 Channel Time 0 Channel Time 16 F0o Figure 4 - DV Port - 160 kbit/s (Modes 2, 3, 6) Functional Description The MT9173 and MT9174 are multifunction devices capable of providing high speed, full duplex digital transmission at up to 160 kbit/s over a twisted wire pair. They use adaptive echo-cancelling techniques and transfer data in a format compatible to the ISDN basic rate. Several modes of operation allow an easy interface to digital telecommunication networks including PCS wireless base stations, smart telephone sets, workstations, data terminals and computers. The device supports the 2B+D channel format (two 64 kbit/s B-channels and one 16 kbit/s D-channel) over two wires as recommended by the CCITT. The line data is converted to and from the STBUS format on the system side of the network to allow for easy interfacing with other components such as the Sinterface device in an NT1 arrangement, or to digital PABX components. Smart telephone sets with data and voice capability can be easily implemented using the MT9173/74 as a line interface. The device’s high bandwidth and long loop length capability allows its use in a wide variety of sets. This can be extended to provide full data and voice capability to the private subscriber by the installation of equipment in both the home and central office or remote concentration equipment. Within the subscriber equipment the MT9173/74 would terminate the line and encode/ decode the data and voice for transmission while additional electronics could provide interfaces for a standard telephone set and any number of data ports supporting standard data rates for such things as computer communications and telemetry for remote meter reading. Digital workstations with a high degree of networking capability can be designed using the DNIC for the line interface, offering up to 160 kbit/s data transmission over existing telephone lines. The MT9173/74 could also be valuable within existing computer networks for connecting a large number of terminals to a computer or for intercomputer links. With the DNIC, this can be accomplished at up to 160 kbit/s at a very low cost per line for terminal to computer links and in many cases this bandwidth would be sufficient for computer to computer links. Figure 1 shows the block diagram of the MT9173/74. The DNIC provides a bidirectional interface between the DV (data/voice) port and a full duplex line operating at 80 or 160 kbit/s over a single pair of twisted wires. The DNIC has three serial ports. The DV port (DSTi/Di, DSTo/Do), the CD (control/data) port (CDSTi/CDi, CDSTo/CDo) and a line port (LIN, LOUT). The data on the line is made up of information from the DV and CD ports. The DNIC must combine information received from both the DV and CD ports and put it onto the line. At the same time, the data received from the line must be split into the various channels and directed to the proper ports. The usable data rates are 72 4 Zarlink Semiconductor Inc. MT9173/74 Data Sheet and 144 kbit/s as required for the basic rate interface in ISDN. Full duplex transmission is made possible through on board adaptive echo cancellation. The DNIC has various modes of operation which are selected through the mode select pins MS0-2. The two major modes of operation are the MODEM (MOD) and DIGITAL NETWORK (DN) modes. MOD mode is a transparent 80 or 160 kbit/s modem. In DN mode the line carries the B and D channels formatted for the ISDN at either 80 or 160 kbit/s. In the DN mode the DV and CD ports are standard ST-BUS and in MOD mode they are transparent serial data streams at 80 or 160 kbit/s. Other modes include: MASTER (MAS) or SLAVE (SLV) mode, where the timebase and frame synchronization are provided externally or are extracted from the line and DUAL or SINGLE (SINGL) port modes, where both the DV and CD ports are active or where the CD port is inactive and all information is passed through the DV port. For a detailed description of the modes see “Operating Modes” section. In DIGITAL NETWORK (DN) mode there are three channels transferred by the DV and CD ports. They are the B, C and D channels. The B1 and B2 channels each have a bandwidth of 64 kbit/s and are used for carrying PCM encoded voice or data. These channels are always transmitted and received through the DV port (Figures 3, 4, 5, 6). The C-channel, having a bandwidth of 64 kbit/s, provides a means for the system to control the DNIC and for the DNIC to pass status information back to the system. The C-channel has a Housekeeping (HK) bit which is the only bit of the C-channel transmitted and received on the line. The 2B+D channel bits and the HK bit are doublebuffered. The D-channel can be transmitted or received on the line with either an 8, 16 or 64 kbit/s bandwidth depending on the DNIC’s mode of operation. Both the HK bit and the D-channel can be used for end-to-end signalling or low speed data transfer. In DUAL port mode the C and D channels are accessed via the CD port (Figure 7) while in SINGL port mode they are transferred through the DV port (Figures 5, 6) along with the B1 and B2 channels. F0 C4 DSTo D0 D1 D2 D3 D4 D5 D6 D7 C0 C1 C2 C3 C4 C5 C6 C7 B7 B6 B5 B4 B3 B2 B1 B0 D0 DSTi D0 D1 D2 D3 D4 D5 D6 D7 C0 C1 C2 C3 C4 C5 C6 C7 B7 B6 B5 B4 B3 B2 B1 B0 D0 F0o 11.7 µsec Channel Time 0 D-Channel Channel Time 1 C-Channel Channel Time 2 B1-Channel Figure 5 - DV Port - 80 kbit/s (Modes 0,4) F0 C4 DSTo D0 D1 D2 D3 D4 D5 D6 D7 C0 C1 C2 C3 C4 C5 C6 C7 B7 B6 B5 B4 B3 B2 B1 B0 B7 B6 B5 B4 B3 B2 B1 B0 D0 DSTi D0 D1 D2 D3 D4 D5 D6 D7 C0 C1 C2 C3 C4 C5 C6 C7 B7 B6 B5 B4 B3 B2 B1 B0 B7 B6 B5 B4 B3 B2 B1 B0 D0 F0o 15.6 µsec Channel Time 0 D-Channel Channel Time 1 C-Channel Channel Time 2 B1-Channel Channel Time 3 B2-Channel Figure 6 - DV Port - 160 kbit/s (Modes 0,4) 5 Zarlink Semiconductor Inc. MT9173/74 Data Sheet F0 C4 CDSTo C0 C 1 C2 C 3 C4 C5 C6 C7 D 0 D1 D 2 D3 D 4 D5 D 6 D7 C0 CDSTi C0 C 1 C2 C 3 C4 C5 C6 C7 D 0 D1 D 2 D3 D 4 D5 D 6 D7 C0 F0o 3.9 µsec 62.5 µsec 125 µsec Channel Time 0 Channel Time 16 Figure 7 - CD Port (Modes 2,6) CLD TCK CDi C6 C7 C0 C1 C2 C3 C4 C5 C6 C7 C0 C1 CDo C6 C7 C0 C1 C2 C3 C4 C5 C6 C7 C0 C1 Figure 8 - CD Port (Modes 1,5) In DIGITAL NETWORK (DN) mode, upon entering the DNIC from the DV and CD ports, the B-channel data, Dchannel D0 (and D1 for 160 kbit/s), the HK bit of the C-channel (160 kbit/s only) and a SYNC bit are combined in a serial format to be sent out on the line by the Transmit Interface (Figures 11, 12). The SYNC bit produces an alternating 1-0 pattern each frame in order for the remote end to extract the frame alignment from the line. It is possible for the remote end to lock on to a data bit pattern which simulates this alternating 1-0 pattern that is not the true SYNC. To decrease the probability of this happening the DNIC may be programmed to put the data through a prescrambler that scrambles the data according to a predetermined polynomial with respect to the SYNC bit. This greatly decreases the probability that the SYNC pattern can be reproduced by any data on the line. In order for the echo canceller to function correctly, a dedicated scrambler is used with a scrambling algorithm which is different for the SLV and MAS modes. These algorithms are calculated in such a way as to provide orthogonality between the near and far end data streams such that the correlation between the two signals is very low. For any two DNICs on a link, one must be in SLV mode with the other in MAS mode. The scrambled data is differentially encoded which serves to make the data on the line polarity-independent. It is then biphase encoded as shown in Figure 10. See “Line Interface” section for more details on the encoding. Before leaving the DNIC the differentially encoded biphase data is passed through a pulse-shaping bandpass transmit filter that filters out the high and low frequency components and conditions the signal for transmission on the line. 6 Zarlink Semiconductor Inc. MT9173/74 Data Sheet The composite transmit and receive signal is received at LIN. On entering the DNIC this signal passes through a Precanceller which is a summing amplifier and lowpass filter that partially cancels the near-end signal and provides first order antialiasing for the received signal. Internal, partial cancellation of the near end signal may be disabled by holding the Precan pin high. This mode simplifies the design of external line transceivers used for loop extension applications. The Precan pin features an internal pull-down which allows this pin to be left unconnected in applications where this function is not required. The resultant signal passes through a receive filter to bandlimit and equalize it. At this point, the echo estimate from the echo canceller is subtracted from the precancelled received signal. This difference signal is then input to the echo canceller as an error signal and also squared up by a comparator and passed to the biphase receiver. Within the echo canceller, the sign of this error signal is determined. Depending on the sign, the echo estimate is either incremented or decremented and this new estimate is stored back in RAM. The timebase in both SLV and MAS modes (generated internally in SLV mode and externally in MAS mode) is phase-locked to the received data stream. This phase-locked clock operates the Biphase Decoder, Descrambler and Deprescrambler in MAS mode and the entire chip in SLV mode. The Biphase Decoder decodes the received encoded bit stream resulting in the original NRZ data which is passed onto the Descrambler and Deprescrambler where the data is restored to its original content by performing the reverse polynomials. The SYNC bits are extracted and the Receive Interface separates the channels and outputs them to the proper ports in the proper channel times. The destination of the various channels is the same as that received on the input DV and CD ports. 7 Zarlink Semiconductor Inc. MT9173/74 Data Sheet The Transmit/Receive Timing and Control block generates all the clocks for the transmit and receive functions and controls the entire chip according to the control register. In order that more than one DNIC may be connected to the same DV and CD ports an F0o signal is generated which signals the next device in a daisy chain that its channel times are now active. In this arrangement only the first DNIC in the chain receives the system F0 with the following devices receiving its predecessor’s F0o. In MOD mode, all the ports have a different format. The line port again operates at 80 or 160 kbit/s, however, there is no synchronization overhead, only transparent data. The DV and CD ports carry serial data at 80 or 160 kbit/s with the DV port transferring all the data for the line and the CD port carrying the C-channel only. In this mode the transfer of data at both ports is synchronized to the TCK and RCK clocks for transmit and receive data, respectively. The CLD signal goes low to indicate the start of the C-channel data on the CD port. It is used to load and latch the input and output C-channel but has no relationship to the data on the DV port. In DN MAS mode, the RxSB pin outputs a pulse corresponding to the position of the synchronization bit within the received biphase data stream. Since the delay in transmission between DNICs is dependent upon line length, the position of the RxSB pulse will vary as the line length is varied. This feature can be used to determine total loop delay which is necessary in wireless base stations where all of the microcells need to be synchronized. In DN SLV mode, The RxSB pin is also active although its timing is fixed and does not vary with line length. For both DN MAS and SLV modes, the RxSB pin can be also used as a hardware SYNC indicator. In MODEM mode, for both MAS and SLV ends, the RxSB pin is inactive and held low. Operating Modes (MS0-2) The logic levels present on the mode select pins MS0, MS1 and MS2 program the DNIC for different operating modes and configure the DV and CD ports accordingly. Table 1 shows the modes corresponding to the state of MS0-2. These pins select the DNIC to operate as a MASTER or SLAVE, in DUAL or SINGLE port operation, in MODEM or DIGITAL NETWORK mode and the order of the C and D channels on the CD port. Table 2 provides a description of each mode and Table 3 gives a pin configuration according to the mode selected for all pins that have variable functions. These functions vary depending on whether it is in MAS or SLV, and whether DN or MOD mode is used. Mode Select Pins Mode Operating Mode MS2 MS1 MS0 0 0 0 0 SLV MAS E DUAL SINGL MOD 0 0 1 1 E E 0 1 0 2 E E E 0 1 1 3 E E E E E 1 0 0 4 E E E E 1 0 1 5 E E 1 1 0 6 E E E 1 1 1 7 E E E D-C E E E E E DN Table 1 - Mode Select Pins E=Enabled X=Not Applicable Blanks are disabled 8 Zarlink Semiconductor Inc. X E X E C-D ODE E X E E E X E E E MT9173/74 Mode Data Sheet Function SLV Slave - The chip timebase is extracted from the received line data and the external 10.24 MHz crystal is phase locked to it to provide clocks for the entire device and are output for the external system to synchronize to. MAS Master - The timebase is derived from the externally supplied data clocks and 10.24 MHz clock which must be frequency locked. The transmit data is synchronized to the system timing with the receive data recovered by a clock extracted from the receive data and resynchronized to the system timing. DUAL Dual Port - Both the CD and DV ports are active with the CD port transferring the C&D channels and the DV port transferring the B1& B2 channels. SINGL Single Port - The B1& B2, C and D channels are all transferred through the DV port. The CD port is disabled and CDSTi should be pulled high. MOD Modem - Baseband operation at 80 or 160 kbits/s. The line data is received and transmitted through the DV port at the baud rate selected. The C-channel is transferred through the CD port also at the baud rate and is synchronized to the CLD output. DN Digital Network - Intended for use in the digital network with the DV and CD ports operating at 2.048 Mbits/s and the line at 80 or 160 kbits/s configured according to the applicable ISDN recommendation. D-C D before C-Channel C-D ODE - The D-channel is transferred before the C-channel following F0. C before D-Channel - The C-channel is transferred before the D-channel following F0. Output Data Enable - When mode 7 is selected, the DV and CD ports are put in high impedance state. This is intended for power-up reset to avoid bus contention and possible damage to the device during the initial random state in a daisy chain configuration of DNICs. In all the other modes of operation DV and CD ports are enabled during the appropriate channel times. Table 2 - Mode Definitions Mode # F0/CLD F0o/RCK C4/TCK Name Input/Output Name Input/Output Name Input/Output 0 F0 Input F0o Output C4 Input 1 CLD Output RCK Output TCK Output 2 F0 Input F0o Output C4 Input 3 F0 Input F0o Output C4 Input 4 F0 Output F0o Output C4 Output 5 CLD Output RCK Output TCK Output 6 F0 Output F0o Output C4 Output 7 F0 Input F0o Output C4 Input Table 3 - Pin Configurations 9 Zarlink Semiconductor Inc. MT9173/74 Data Sheet The overall mode of operation of the DNIC can be programmed to be either a baseband modem (MOD mode) or a digital network transceiver (DN mode). As a baseband modem, transmit/receive data is passed transparently through the device at 80 or 160 kbit/s by the DV port. The CD port transfers the C-channel and D-Channel also at 80 or 160 kbit/s. In DN mode, both the DV and CD ports operate as ST-BUS streams at 2.048 Mbit/s. The DV port transfers data over pins DSTi and DSTo while on the CD port, the CDSTi and CDSTo pins are used. The SINGL port option only exists in DN mode. In MOD mode, DUAL port operation must be used and the D, B1 and B2 channel designations no longer exist. The selection of SLV or MAS will determine which of the DNICs is using the externally supplied clock and which is phase locking to the data on the line. Due to jitter and end to end delay, one end must be the master to generate all the timing for the link and the other must extract the timing from the receive data and synchronize itself to this timing in order to recover the synchronous data. DUAL port mode allows the user to use two separate serial busses: the DV port for PCM/data (B channels) and the CD port for control and signalling information (C and D channels). In the SINGL port mode, all four channels are concatenated into one serial stream and input to the DNIC via the DV port. The order of the C and D channels may be changed only in DN/DUAL mode. The DNIC may be configured to transfer the D-channel in channel 0 and the C-channel in channel 16 or vice versa. One other feature exists; ODE, where both the DV and CD ports are tristated in order that no devices are damaged due to excessive loading while all DNICs are in a random state on power up in a daisy chain arrangement. DV Port (DSTi/Di, DSTo/Do) The DV port transfers data or PCM encoded voice to and from the line according to the particular mode selected by the mode select pins. The modes affecting the configuration of the DV port are MOD or DN and DUAL or SINGL. In DN mode the DV port operates as an ST-BUS at 2.048 Mbit/s with 32, 8 bit channels per frame as shown in Figure 9. In this mode the DV port channel configuration depends upon whether DUAL or SINGL port is selected. When DUAL port mode is used, the C and D channels are passed through the CD port and the B1 and B2 channels are passed through the DV port. At 80 kbit/s only one channel of the available 32 at the DV port is utilized, this being channel 0 which carries the B1-channel. This is shown in Figure 3. At 160 kbit/s, two channels are used, these being 0 and 16 carrying the B1 and B2 channels, respectively. This is shown in Figure 4. When SINGL port mode is used, channels B1, B2, C and D are all passed via the DV port and the CD port is disabled. See CD port description for an explanation of the C and D channels. F0 125 µsec ST-BUS Channel 31 Channel 0 Channel 1 Channel 2 Most Significant Bit (First) Bit 7 Channel 29 •••••••• Bit 6 Bit 5 Bit 4 Bit 3 Channel 30 Bit 2 Bit 1 Channel 31 Bit 0 Channel 0 Least Significant Bit (Last) 3.9 µsec Figure 9 - ST-BUS Format The D-channel is always passed during channel time 0 followed by the C and B1 channels in channel times 1 and 2, respectively for 80 kbit/s. See Figure 5. For 160 kbit/s the B2 channel is added and occupies channel time 3 of the DV port. See Figure 6. For all of the various configurations the bit orders are shown by the respective diagram. In MOD mode the DV and CD ports no longer operate at 2.048 Mbits/s but are continuous serial bit streams operating at the bit rate selected of 80 or 160 kbit/s. While in the MOD mode only DUAL port operation can be used. 10 Zarlink Semiconductor Inc. MT9173/74 Data Sheet In order for more than one DNIC to be connected to any one DV and CD port, making more efficient use of the busses, the DSTo and CDSTo outputs are put into high impedance during the inactive channel times of the DNIC. This allows additional DNICs to be cascaded onto the same DV and CD ports. When used in this way a signal called F0o is used as an indication to the next DNIC in a daisy chain that its channel time is now active. Only the first DNIC in the chain receives the system frame pulse and all others receive the F0o from its predecessor in the chain. This allows up to 16 DNICs to be cascaded. CD Port (CDSTi/CDi, CDSTo/CDo) The CD port is a serial bidirectional port used only in DUAL port mode. It is a means by which the DNIC receives its control information for things such as setting the bit rate, enabling internal loopback tests, sending status information back to the system and transferring low speed signalling data to and from the line. The CD port is composed of the C and D-Channels. The C-channel is used for transferring control and status information between the DNIC and the system. The D-channel is used for sending and receiving signalling information and lower speed data between the line and the system. In DN/DUAL mode the DNIC receives a Cchannel on CDSTi while transmitting a C-channel on CDSTo. Fifteen channel times later (halfway through the frame) a D-channel is received on CDSTi while a D-channel is transmitted on CDSTo. This is shown in Figure 7. The order of the C and D bytes in DUAL port mode can be reversed by the mode select pins. See Table 1 for a listing of the byte orientations. The D-channel exists only in DN mode and may be used for transferring low speed data or signalling information over the line at 8, 16 or 64 kbit/s (by using the DINB feature). The information passes transparently through the DNIC and is transmitted to or received from the line at the bit rate selected in the Control Register. If the bit rate is 80 kbit/s, only D0 is transmitted and received. At 160 kbit/s, D0 and D1 are transmitted and received. When the DINB bit is set in the Control Register the entire D-channel is transmitted and received in the B1-channel timeslot. The C-channel is used for transferring control and status information between the DNIC and the system. The Control and Diagnostics Registers are accessed through the C-channel. They contain information to control the DNIC and carry out the diagnostics as well as the HK bit to be transmitted on the line as described in Tables 4 and 5. Bits 0 and 1 of the C-channel select between the Control and Diagnostics Register. If these bits are 0, 0 then the C-channel information is written to the Control Register (Table 4). If they are 0, 1 the C-channel is written to the Diagnostics Register (Table 5). 11 Zarlink Semiconductor Inc. MT9173/74 Data Sheet bit 0 bit 1 bit 2 bit 3 bit 4 bit 5 bit 6 bit 7 Reg Sel-1 Reg Sel-2 DRR BRS DINB PSEN ATTACK TxHK Default Mode Selection (Refer to Table 4a) Bit Name Description 0 Reg Sel-1 Register Select-1. Must be set to’0’ to select the Control Register. 1 Reg Sel-2 Register Select-2. Must be set to’0’ to select the Control Register. 2 DRR Diagnostics Register Reset. Writing a "0" to this bit will cause a diagnostics register reset to occur coincident with the next frame pulse as in the MT8972A. When this bit is a logic "1", the Diagnostics Register will not be reset. 3 BRS Bit Rate Select. When set to ’0’ selects 80 kbit/s. When set to ’1’, selects 160 kbit/s. 4 DINB2 D-Channel in B Timeslot. When ’0’, the D-channel bits (D0 or D0 and D1) corresponding to the selected bit rate (80 or 160 kbit/s) are transmitted during the normal D-channel bit times. When set to ’1’, the entire D-channel (D0-D7) is transmitted during the B1-channel timeslot on the line providing a 64 kbit/s D-channel link. 5 PSEN2 Prescrambler/Deprescrambler Enable. When set to ’1’, the data prescrambler and deprescrambler are enabled. When set to ’0’, the data prescrambler and deprescrambler are disabled. 6 ATTACK2 Convergence Speedup. When set to ’1’, the echo canceller will converge to the reflection coefficient much faster. Used on power-up for fast convergence.1 When ’0’, the echo canceller will require the normal amount of time to converge to a reflection coefficient. 7 TxHK2 Transmit Housekeeping. When set to ’0’, logic zero is transmitted over the line as Housekeeping Bit. When set to ’1’, logic one is transmitted over the line as Housekeeping Bit. Table 4 - Control Register Note 1: Suggested use of ATTACK: -At 160 kbit/s full convergence requires 850 ms with ATTACK held high for the first 240 frames or 30 ms. -At 80 kbit/s full convergence requires 1.75 s with ATTACK held high for the first 480 frames or 60 ms. Note 2: When bits 4-7 of the Control Register are all set to one, the DNIC operates in one of the default modes as defined in Table 4a, depending upon the status of bit-3. C-Channel (Bit 0-7) Internal Control Register Internal Diagnostic Register Description XXX01111 00000000 01000000 Default Mode-13: Bit rate is 80 kbit/s. ATTACK, PSEN, DINB, DRR and all diagnostics are disabled. TxHK=0. XXX11111 00010000 Default Mode-24 Bit rate is 160 kbit/s. ATTACK, PSEN, DINB, DRR and all diagnostics are disabled. TxHK=0. Table 4a. Default Mode Selection 01000000 Note 3: Default Mode 1 can also be selected by tying CDSTi/CDi pin low when DNIC is operating in dual mode. Note 4: Default Mode 2 can also be selected by tying CDSTi/CDi pin high when DNIC is operating in dual mode. 12 Zarlink Semiconductor Inc. MT9173/74 bit 0 bit 1 Reg Sel-1 Reg Sel-2 bit 2 bit 3 Loopback Data Sheet bit 4 bit 5 bit 6 bit 7 FUN PSWAP DLO Not Used Default Mode Selection (Refer to Table 4a) Bit Name Description 0 Reg Sel-1 Register Select-1. Must be set to ’0’ to select the Diagnostic Register. 1 Reg Sel-2 Register Select-2. Must be set to ’1’ to select the Diagnostic Register. 2,3 Loopback Bit 2 0 0 1 1 Bit 3 0 1 0 1 All loopback testing functions disabled. Normal operation. DSTi internally looped back into DSTo for system diagnostics. LOUT is internally looped back into LIN for system diagnostics.2 DSTo is internally looped back into DSTi for end-to-end testing.3 4 FUN1 5 PSWAP1 Polynomial Swap. When set to ’1’, the scrambling and descrambling polynomials are interchanged (use for MAS mode only). When set to ’0’, the polynomials retain their normal designations. 6 DLO1 Disable Line Out. When set to ’1’, the signal on LOUT is set to VBias. When set to ’0’, LOUT pin functions normally. 7 Not Used Force Unsync. When set to ’1’, the DNIC is forced out-of-sync to test the SYNC recovery circuitry. When set to ’0’, the operation continues in synchronization. Must be set to ’0’ for normal operation. Table 5 - Diagnostic Register Note 1: When bits 4-7 of the Diagnostic Register are all set to one, the DNIC operates in one of the default modes as defined in Table 4a, depending upon the status of bit-3. Note 2: Do not use L OUT to LIN loopback in DN/SLV mode. Note 3: Do not use DSTo to DSTi loopback in MOD/MAS mode. The Diagnostics Register Reset bit (bit 2) of the Control Register determines the reset state of the Diagnostics Register. If, on writing to the Control Register, this bit is set to logic “0”, the Diagnostics Register will be reset coincident with the frame pulse. When this bit is logic “1”, the Diagnostics Register will not be reset. In order to use the diagnostic features, the Diagnostics Register must be continuously written to. The output C-channel sends status information from the Status Register to the system along with the received HK bit as shown in Table 6. In MOD mode, the CD port is no longer an ST-BUS but is a serial bit stream operating at the bit rate selected. It continues to transfer the C-channel but the D-channel and the HK bit no longer exist. DUAL port operation must be used in MOD mode. The C-channel is clocked in and out of the CD port by TCK and CLD with TCK defining the bits and CLD the channel boundaries of the data stream as shown in Figure 8. 13 Zarlink Semiconductor Inc. MT9173/74 Data Sheet Line Port (LIN, LOUT) The line interface is made up of LOUT and LIN with LOUT driving the transmit signal onto the line and LIN receiving the composite transmit and receive signal from the line. The line code used in the DNIC is Biphase and is shown in Figure 10. The scrambled NRZ data is differentially encoded meaning the previous differential encoded output is XOR’d with the current data bit which produces the current output. This is then biphase encoded where transitions occur midway through the bit cell with a negative going transition indicating a logic "0" and a positive going transition indicating a logic "1". There are some major reasons for using a biphase line code. The power density is concentrated in a spectral region that minimizes dispersion and differential attenuation. This can shorten the line response and reduce the intersymbol interference which are critical for adaptive echo cancellation. There are regular zero crossings halfway through every bit cell or baud which allows simple clock extraction at the receiving end. There is no D.C. content in the code so that phantom power feed may be applied to the line and simple transformer coupling may be used with no effect on the data. It is bipolar, making data reception simple and providing a high signal to noise ratio. The signal is then passed through a bandpass filter which conditions the signal for the line by limiting the spectral content from 0.2fBaud to 1.6fBaud and on to a line driver where it is made available to be put onto the line biased at VBias. The resulting transmit signal will have a distributed spectrum with a peak at 3/4fBaud. The transmit signal (LOUT) may be disabled by holding the LOUT DIS pin high or by writing DLO (bit 6) of the Diagnostics Register to logic “1”. When disabled, LOUT is forced to the VBias level. LOUT DIS has an internal pull-down to allow this pin to be left not connected in applications where this function is not required. The receive signal is the above transmit signal superimposed on the signal from the remote end and any reflections or delayed symbols of the near end signal. The frame format of the transmit data on the line is shown in Figures 11 and 12 for the DN mode at 80 and 160 kbit/s. At 80 kbit/s a SYNC bit for frame recovery, one bit of the D-channel and the B1-channel are transmitted. At 160 kbit/s a SYNC bit, the HK bit, two bits of the D-channel and both B1 and B2 channels are transmitted. If the DINB bit of the Control Register is set, the entire D-channel is transmitted during the B1-channel timeslot. In MOD mode the SYNC, HK and D-channel bits are not transmitted or received but rather a continuous data stream at 80 or 160 kbit/s is present. No frame recovery information is present on the line in MOD mode. 0 1 SYNC 2 CHQual 3 4 Rx HK 5 6 Future Functionality 7 ID Status Register Name 0 SYNC Synchronization - When set this bit indicates that synchronization to the received line data sync pattern has been acquired. For DN mode only. 1-2 CHQual Channel Quality - These bits provide an estimate of the receiver’s margin against noise. The farther this 2 bit value is from 0 the better the SNR. 3 Rx HK Housekeeping - This bit is the received housekeeping (HK) bit from the far end. 4-6 Future Future Functionality. These bits return Logic 1 when read. 7 ID Function This bit provides a hardware identifier for the DNIC revision. The MT9173/74 will return a logic “0” for this bit. Table 6 - Status Register 14 Zarlink Semiconductor Inc. MT9173/74 Bits Bit 7 Data 1 Data Sheet Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 1 1 0 0 1 0 0 NRZ Data Differential Encoded Differential Encoded Biphase Transmit Line Signal VBias Note: Last bit sent was a logic 0 Figure 10 - Data & Line Encoding F0 LOUT B17 SYNC D0 B10 B11 B12 B13 B14 B15 B16 B17 SYNC Figure 11 - Frame Format - 80 kbit/s (Modes 0, 2, 3, 4, 6) F0 LOUT SYNC HK0 D1 D0 B10 B11 B12 B13 B14 B15 B16 B17 B20 B21 B22 B23 B24 B25 B26 B27 SYNC Figure 12 - Frame Format - 160 kbit/s (Modes 0, 2, 3, 4, 6) 15 Zarlink Semiconductor Inc. MT9173/74 Data Sheet Applications Typical connection diagrams are shown in Figures 13 and 14 for the DN mode as a MASTER and SLAVE, respectively. LOUT is connected to the coupling transformer through a resistor R2 and capacitors C2 and C2’ to match the line characteristic impedance. Suggested values of R2, C2 and C2’ for 80 and 160 kbit/s operation are provided in Figures 13 and 14. Overvoltage protection is provided by R1, D1 and D2. C1 is present to properly bias the received line signal for the LIN input. A 2:1 coupling transformer is used to couple to the line with a secondary center tap for optional phantom power feed. Varistors have been shown for surge protection against such things as lightning strikes. If the scramblers power up with all zeros in them, they are not capable of randomizing all-zeros data sequence. This increases the correlation between the transmit and receive data which may cause loss of convergence in the echo canceller and high bit error rates. In DN mode the insertion of the SYNC pattern will provide enough pseudo-random activity to maintain convergence. In MOD mode the SYNC pattern is not inserted. For this reason, at least on ”1” must be fed into the DNIC on power up to ensure that the scramblers will randomize any subsequent all-zeros sequence. C2’ = 1.5 nF DV Port ST-BUS { DSTi CD Port ST-BUS { CDSTi CDSTo { F0 C4 Master Clocks Mode Select Lines +5 V 0.33 µF 0.33 µF To Time Measurement Circuitry DSTo MS0 MS1 MS2 VRef VBias RxSB For 80 kbit/s: C2’ = 3.3 nF +5 V MT9173/74 C2 = 22 nF D1 = D2 = MUR405 LOUT R2 = 390 Ω D2 R1 = 47 Ω LIN OSC1 OSC2 F0o 2:1 Line Feed Voltage 1.0 µF D.C. coupled, Frequency locked 10.24 MHz clock. NC Refer to AC Electrical Characteristics Clock Timing C1 = 0.33 µF DN Mode. 68 Volts (Typ) 2.5 Joules 0.02 Watt Note: Low leakage diodes (1 & 2) are required so that the DC voltage at LIN ª VBias To Next DNIC Figure 13 - Typical Connection Diagram - MAS/DN Mode, 160 kbit/s 16 Zarlink Semiconductor Inc. MT9173/74 Data Sheet C2’ = 1.5 nF For 80 kbit/s: C2’ = 3.3 nF +5 V MT9173/74 { DSTi CD Port ST-BUS { CDSTi CDSTo Master Clocks { F0 C4 DV Port ST-BUS D1 = D2 = MUR405 LOUT R2 = 390Ω 2:1 D2 R1 = 47Ω LIN 1.0 µF MS0 Mode Select Lines +5 V DSTo C2 = 22 nF 0.33 µF 0.33 µF To hardware SYNC Indicator (optional) MS1 MS2 OSC1 VRef VBias OSC2 Supply 68 Volts (Typ) 2.5 Joules 0.02 Watt 10.24 MHz XTAL C1 = 0.33 µF C3=33 pF=C4 RxSB Note: Low leakage diodes (1 & 2) are required so that the DC voltage at LIN ª VBias Figure 14 - Typical Connection Diagram - SLV/DN Mode, 160 kbit/s Absolute Maximum Ratings** - Voltages are with respect to ground (VSS) unless otherwise stated. Parameter Symbol Min. Max. Units 1 Supply Voltage VDD -0.3 7 V 2 Voltage on any pin (other than supply) VMax -0.3 VDD+0.3 V 3 Current on any pin (other than supply) IMax 40 mA 4 Storage Temperature TST +150 °C 5 Package Power Dissipation (Derate 16mW/×C above 75°C) PDiss 750 mW -65 ** Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Recommended Operating Conditions† Characteristics - Voltages are with respect to ground (VSS) unless otherwise stated. Sym. Min. Typ.* Max. Units 5.00 5.25 V Test Conditions 1 Operating Supply Voltage VDD 4.75 2 Operating Temperature TOP -40 +85 °C 3 Input High Voltage (except OSC1) VIH 2.4 VDD V for 400 mV noise margin 4 Input Low Voltage (except OSC1) VIL 0 0.4 V for 400 mV noise margin * Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing. † Parameters over recommended temperature & power supply voltage ranges. 17 Zarlink Semiconductor Inc. MT9173/74 DC Electrical Characteristics† Data Sheet - Voltages are with respect to ground (VSS) unless otherwise stated. Characteristics Sym. Min. Typ.* Max. Units Test Conditions 1 Operating Supply Current IDD 2 Output High Voltage (ex OSC2) VOH 2.4 V 3 Output High Current (except OSC2) IOH 10 mA Source current. VOH=2.4 V Output High Current - OSC2 IOH 10 mA Source current VOH=3.5 V Output Low Voltage (ex OSC2) VOL Output Low Current (except OSC2) IOL 5 Output Low Current - OSC2 IOL 10 8 High Imped. Output Leakage IOZ 9 Output Voltage VO 4 5 6 7 O U T P U T S 10 (VRef) (VBias) 10 mA 0.4 7.5 10 V Sink current. VOL=0.4 V mA Sink current. VOL=1.5 V mA VIN=VSS to VDD V V VBias-1.8 VDD/2 Input High Voltage (ex OSC1) VIH 12 Input Low Voltage (ex OSC1) VIL Input High Voltage (OSC1) VIHo Input Low Voltage (OSC1) VILo 1.0 V IIL 10 mA 14 15 16 I N P U T S Input Leakage Current Input Pulldown Impedance LOUT DIS and Precan 2.0 V 0.8 4.0 V V 50 ZPD IOL=5 mA mA 11 13 IOH=10 mA 17 VIN=VSS to VDD kΩ Input Leakage Current for IIOSC 20 mA OSC1 Input Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing. * † Parameters over recommended temperature & power supply voltage ranges. 18 Zarlink Semiconductor Inc. MT9173/74 AC Electrical Characteristics† - Voltages are with respect to ground (VSS) unless otherwise stated. Characteristics 1 2 3 4 5a 5b I N P U T S 6 7 8 9 10 Sym. Input Voltage (LIN) VIN Input Impedance (LIN) ZIN Crystal/Clock Frequency Min. Typ.* Max. Units 5.0 Vpp 20 kΩ 10.24 fC Test Conditions fBaud=160 kHz MHz TC -100 0 +100 ppm 1 DCC 40 50 60 % Normal temp. & VDD Crystal/Clock Duty Cycle 1 DCC 45 50 55 % Recommended at max./ min. temp. & VDD CL 33 50 pF From OSC1 & OSC2 to VSS. Co 8 pF 500 100 Ω kΩ Crystal/Clock Tolerance Crystal/Clock Duty Cycle Crystal/Clock Loading O U T P U T S Data Sheet Output Capacitance (LOUT) Load Resistance (LOUT) (VBias, VRef) RLout Load Capacitance (LOUT) (VBias, VRef) CLout (LOUT) Output Voltage Vo 20 pF µF Capacitance to VBias. 4.6 Vpp RLout = 500 Ω, CLout = 20 pF 0.1 3.2 4.3 † Timing is over recommended temperature & power supply voltages. * Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing. Note 1: Duty cycle is measured at VDD/2 volts. . AC Electrical Characteristics† - Clock Timing - DN Mode (Figures 16 & 17) Characteristics Sym. Min. Typ.* Max. Units 1 C4 Clock Period tC4P 244 ns 2 C4 Clock Width High or Low tC4W 122 ns 3 Frame Pulse Setup Time tF0S 50 ns 4 Frame Pulse Hold Time tF0H 50 ns 5 Frame Pulse Width tF0W 244 ns 6 10.24 MHz Clock Jitter (wrt C4) JC ±15 ns Test Conditions In Master Mode - Note 1 Note 2 † Timing is over recommended temperature & power supply voltages. * Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing. Note 1: When operating as a SLAVE the C4 clock has a 40% duty cycle. Note 2: When operating in MAS/DN Mode, the C4 and Oscillator clocks must be externally frequency-locked (i.e., F C =2.5xf C4). The relative phase between these two clocks (Φ in Fig. 17) is not critical and may vary from 0 ns to tC4P. However, the relative jitter must be less than JC (see Figure 17). F0 C4 ST-BUS BIT CELLS Channel 31 Channel 0 Bit 0 Bit 7 Channel 0 Bit 6 Figure 15 - C4 Clock & Frame Pulse Alignment for ST-BUS Streams 19 Zarlink Semiconductor Inc. MT9173/74 Data Sheet tC4P C4 0.8 V tF0S F0 tC4W 2.0 V tF0H tC4W tF0W 2.0 V 0.8 V Figure 16 - C4 Clock & Frame Pulse Alignment for ST-BUS Streams in DN Mode C4 2.0 V 0.8 V F JC OSC1 3.0 V 2.0 V Figure 17 - Frequency Locking for the C4 and OSC1 Clocks in MAS/DN Mode AC Electrical Characteristics† - Clock Timing - MOD Mode (Figure 18) Characteristics Sym 80 kbit/s Min. Typ.* 160 kbit/s Max. Min. Typ.* Max. Units 1 TCK/RCK Clock Period tCP 12.5 6.25 µs 2 TCK/RCK Clock Width tCW 6.25 3.125 µs 3 TCK/RCK Clock Transition Time tCT 20 20 µs 4 CLD to TCK Setup Time tCLDS 3.125 1.56 µs 5 CLD to TCK Hold Time tCLDH 3.125 1.56 µs 6 CLD Width Low tCLDW 6.05 2.925 µs 7 CLD Period tCLDP 8xtCP 8xtCP µs † Timing is over recommended temperature & power supply voltage ranges. * Typical figures are at 25°C, for design aid only: not guaranteed and not subject to production testing. 20 Zarlink Semiconductor Inc. Test Conditions CL=40 pF MT9173/74 Data Sheet tCP tCT tCW 2.4 V RCK 0.4 V tCP TCK 2.4 V 0.4 V tCLDH tCLDS tCW tCT tCLDW 2.4 V CLD 0.4 V Note 1: TCK and CLD are generated on chip and provide the data clocks for the CD port and the transmit section of the DV port. RCK, also generated on chip, is extracted from the receive data and only clocks out the data at the Do output and may be skewed with respect to TCK due to end-to-end delay. Note 2: At the slave end TCK is phase locked to RCK. The rising edge of TCK will lead the rising edge of RCK by approximately 90o. Figure 18 - RCK, TCK & CLD Timing For MOD Mode AC Electrical Characteristics† - Data Timing - DN Mode (Figure 19) Characteristics Sym. Min. Typ. Max. Units Test Conditions 1 DSTi/CDSTi Data Setup Time tRS 30 ns 2 DSTi/CDSTi Data Hold Time tRH 50 ns 3a DSTo/CDSTo Data Delay tTD 120 ns CL=40 pF 3b DSTo/CDSTo High Z to Data Delay tZTD 140 ns CL=40 pF † Timing is over recommended temperature & power supply voltage ranges. Bit Stream C4 DSTi CDSTi Bit Cell 2.0 V 0.8 V 2.0 V 0.8 V tTD tZTD DSTo CDSTo tRS 2.4 V 0.4 V Figure 19 - Data Timing For DN Mode 21 Zarlink Semiconductor Inc. tRH tTD MT9173/74 Data Sheet AC Electrical Characteristics† - Data Timing - MOD Mode (Figure 20) Characteristics Sym. 80 kbit/s 160 kbit/s Min. Typ.* Max. Min. Typ.* Max. Units Test Conditions 1 Di/CDi Data Setup Time tDS 150 150 ns 2 Di/CDi Data Hold Time tDH 4.5 2.5 µs 3 Do Data Delay Time tRD 70 70 ns CL=40 pF 4 CDo Data Delay Time tTD 70 70 ns CL=40 pF † Timing is over recommended temperature & power supply voltage ranges. * Typical figures are at 25°C, for design aid only: not guaranteed and not subject to production testing. Performance Characteristics of the MT9173 DSIC Characteristics Sym. Min. Typ.* Max. Units Test Conditions 0 30 25 dB SNR≥16.5 dB (300 kHz bandlimited noise) 1 Allowable Attenuation for Bit Error Rate of 10-6 (Note 1) Afb 2 Line Length at 80 kbit/s -24 AWG -26 AWG L80 3.0 2.2 km attenuation - 6.9 dB/km attenuation - 10.0 dB/km 3 Line Length at 160 kbit/s -24 AWG -26 AWG L160 3.0 2.2 km attenuation - 8.0 dB/km attenuation - 11.5 dB/km Performance Characteristics of the MT9174 DNIC Characteristics Sym. Min. Typ.* Max. Units Test Conditions 0 40 33 dB SNR≥16.5 dB (300 kHz bandlimited noise) 1 Allowable Attenuation for Bit Error Rate of 10-6 (Note 1) Afb 2 Line Length at 80 kbit/s -24 AWG -26 AWG L80 5.0 3.4 km attenuation - 6.9 dB/km attenuation - 10.0 dB/km 3 Line Length at 160 kbit/s -24 AWG -26 AWG L160 4.0 3.0 km attenuation - 8.0 dB/km attenuation - 11.5 dB/km Note 1: Attenuation measured from Master LOUT to Slave LIN at 3/4baud frequency. * Typical figures are at 25°C, for design aid only: not guaranteed and not subject to production testing. 22 Zarlink Semiconductor Inc. MT9173/74 Tx Bit Stream TCK Data Sheet Bit Cell 2.4 V 0.4 V tDS Di CDI tDH 2.0 V 0.8 V tTD tTD CDo 2.4 V 0.4 V Rx Bit Stream Bit Cell tRD tRD RCK Do 2.4 V 0.4 V Figure 20 - Data Timing for Master Modem Mode 23 Zarlink Semiconductor Inc. MT9173/74 TCK Data Sheet 2.4 V 0.4 V tDS tDH ¼ tCP Di CDI 2.0 V 0.8 V tTD tTD CDo 2.4 V 0.4 V RCK Do 2.4 V 0.4 V Figure 21 - Data Timing for Slave Modem Mode F0 tRXD RxSB Figure 22 - RxSB Timing for DN MAS Mode AC Electrical Characteristics† - RxSB Timing - DN MAS Mode (Figure 22) Characteristics 1 RxSB Delay Sym. Min. tRXD Typ.* Max. Units Test Conditions 81.4 us 0 km, 160 kB 35.8 us 0 km, 80 kB 126 us 4 km, 24 AWG, 160 kB 85 us 4 km, 26 AWG, 80 kB * Typical figures are at 25°C, for design aid only: not guaranteed and not subject to production testing. 24 Zarlink Semiconductor Inc. E1 D2 Pin 1 D E A1 A2 A L C e b b1 D1 eB Package Code c Zarlink Semiconductor 2003 All rights reserved. ISSUE ACN DATE APPRD. Previous package codes: For more information about all Zarlink products visit our Web Site at www.zarlink.com Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable. 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This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user’s responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink’s conditions of sale which are available on request. Purchase of Zarlink’s I2C components conveys a licence under the Philips I2C Patent rights to use these components in and I2C System, provided that the system conforms to the I2C Standard Specification as defined by Philips. Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc. Copyright Zarlink Semiconductor Inc. All Rights Reserved. TECHNICAL DOCUMENTATION - NOT FOR RESALE