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72V70180PF

72V70180PF

  • 厂商:

    RENESAS(瑞萨)

  • 封装:

    TQFP64_14X14MM

  • 描述:

    IC MULTIPLEXER 1 X 4:4 64TQFP

  • 数据手册
  • 价格&库存
72V70180PF 数据手册
3.3 VOLT TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 FEATURES: • • • • • • • • • • • • • • 128 x 128 channel non-blocking switching at 2.048 Mb/s Per-channel variable or constant throughput delay Automatic identification of ST-BUS®/GCI interfaces Accepts 4 serial data streams of 2.048 Mb/s Automatic frame offset delay measurement Per-stream frame delay offset programming Per-channel high impedance output control Per-channel Processor Mode Control interface compatible to Intel/Motorola CPUs Connection memory block programming Available in 64-pin Thin Plastic Quad Flatpack (TQFP) and 64-pin Small Thin Quad Flatpack (STQFP) IDT72V70180 3.3V Power Supply Operating Temperature Range -40°°C to +85°°C 3.3V I/O with 5V Tolerant Inputs DESCRIPTION: The IDT72V70180 is a non-blocking digital switch that has a capacity of 128 x 128 channels at 2.048 Mb/s. Some of the main features are: programmable stream and channel control, Processor Mode, input offset delay and highimpedance output control. Per-stream input delay control is provided for managing large multi-chip switches that transport both voice channel and concatenated data channels. In addition, input streams can be individually calibrated for input frame offset. FUNCTIONAL BLOCK DIAGRAM VCC GND RESET ODE Loopback RX0 TX0 RX1 RX2 Output MUX Data Memory Receive Serial Data Streams RX3 Connection Memory Internal Registers Timing Unit CLK F0i FE TX1 Transmit Serial Data Streams TX2 TX3 Microprocessor Interface IC AS/ IM DS/ RD ALE CS R/W / A0-A7 DTA D8-D15/ WR AD0-AD7 IDT and the IDT logo are registered trademarks of Integrated Device Technology, Inc. The ST-BUS® is a trademark of Mitel Corp. 5716 drw01 MARCH 2003 1 © 2003 Integrated Device Technology, Inc. All rights reserved. Product specifications subject to change without notice. DSC-5716/4 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE IC IC TX3 TX2 TX1 TX0 ODE GND DNC DTA D15 D14 59 58 57 56 55 54 53 52 51 50 49 IC 62 61 60 GND IC 63 VCC 64 PIN CONFIGURATIONS PIN 1 GND 1 48 D13 RX0 2 47 D12 RX1 3 46 D11 RX2 4 45 D10 RX3 5 44 D9 IC 6 43 D8 IC 7 42 GND IC 8 41 VCC IC 9 40 AD7 F0i 10 39 AD6 FE 11 38 AD5 GND 12 37 AD4 22 23 24 25 26 27 28 29 30 31 32 A3 A4 A5 A6 A7 DS/R D R/W /R W CS AS/ALE IM GND RESET A2 34 33 AD1 16 21 15 DNC 20 DNC A1 AD2 18 35 19 AD3 IC 36 14 A0 13 17 CLK VCC TQFP 0.80mm pitch, 14mm x 14mm (PN64-1, order code: PF) STQFP 0.50mm pitch, 10mm x 10mm (PP64-1, order code: TF) TOP VIEW NOTES: 1. DNC - Do Not Connect. 2. All I/O pins are 5V tolerant. 3. IC - Internal Connection, tie to Ground for normal operation. 2 AD0 5716 drw02 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE PIN DESCRIPTION SYMBOL GND Vcc TX0-3 RX0-3 F0i NAME Ground. Vcc TX Output 0 to 3 (Three-state Outputs) RX Input 0 to 3 Frame Pulse I/O O I I FE CLK RESET Frame Evaluation Clock Device Reset (Schmitt Trigger Input) I I I A0-7 Address 0-7 I DS/RD Data Strobe/Read I R/W / WR Read/Write / Write I IM Chip Select Address Strobe or Latch Enable CPU Interface Mode AD0-7 Address/Data Bus 0 to 7 I/O D8-15 DTA Data Bus 8-15 Data Transfer Acknowledgment ODE Output Drive Enable CS AS/ALE I I I I/O O I DESCRIPTION Ground Rail. +3.3 Volt Power Supply. Serial data output stream. These streams have a data rate of 2.048 Mb/s. Serial data input stream. These streams have a data rate of 2.048 Mb/s. This input accepts and automatically identifies frame synchronization signals formatted according to ST-BUS® and GCI specifications. This pin is the frame measurement input. Serial clock for shifting data in/out on the serial streams (RX/TX 0-3). This input accepts a 4.096 MHz clock. This input (active LOW) puts the IDT72V70180 in its reset state that clears the device internal counters, registers and brings TX0-3 and microport data outputs to a high-impedance state. The time constant for a power up reset circuit must be a minimum of five times the rise time of the power supply. In normal operation, the RESET pin must be held LOW for a minimum of 100ns to reset the device. When non-multiplexed CPU bus operation is selected, these lines provide the A0-A7 address lines to the internal memories. For Motorola multiplexed bus operation, this input is DS. This active HIGH DS input works in conjunction with CS to enable the read and write operations. For Motorola non-multiplexed CPU bus operation, this input is DS. This active LOW input works in conjunction with CS to enable the read and write operations. For Intel multiplexed bus operation, this input is RD. This active LOW input sets the data bus lines (AD0-7, D8-15) as outputs. In the cases of Motorola non-multiplexed and multiplexed bus operations, this input is R/W. This input controls the direction of the data bus lines (AD0-7, D8-15) during a microprocessor access. For Intel multiplexed bus operation, this input is WR. This active LOW input is used with RD to control the data bus (AD0-7) lines as inputs. Active LOW input used by a microprocessor to activate the microprocessor port of IDT72V70180. This input is used if multiplexed bus operation is selected via the IM input pin. For Motorola non-multiplexed bus operation, connect this pin to ground. When IM is HIGH, the microprocessor port is in the multiplexed mode. When IM is LOW, the microprocessor port is in non-multiplexed mode. These pins are the eight least significant data bits of the microprocessor port. In multiplexed mode, these pins are also the input address bits of the microprocessor port. These pins are the eight most significant data bits of the microprocessor port. This active LOW output signal indicates that a data bus transfer is complete. When the bus cycle ends, this pin drives HIGH and then goes high-impedance, allowing for faster bus cycles with a weaker pull-up resistor. A pull-up resistor is required to hold a HIGH level when the pin is in high-impedance. This is the output enable control for the TX0 to TX3 serial outputs. When ODE input is LOW and the OSB bit of the IMS register is LOW, TX0-3 are in a high-impedance state. If this input is HIGH, the TX0-3 output drivers are enabled. However, each channel may still be put into a high-impedance state by using the per channel control bit in the connection memory. 3 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE FUNCTIONAL DESCRIPTION As the IDT72V70180 can be used in a wide variety of applications, the device also has memory locations to control the outputs based on operating mode. Specifically, the IDT72V70180 provides five per-channel control bits for the following functions: processor or connection mode, constant or variable delay, enables/three-state the TX output drivers and enables/disable the loopback function. In addition, one of these bits allows the user to control the CCO output. If an output channel is set to a high-impedance state through the connection memory, the TX output will be in a high-impedance state for the duration of that channel. In addition to the per-channel control, all channels on the ST-BUS® outputs can be placed in a high impedance state by either pulling the ODE input pin low or programming the Output Stand-By (OSB) bit in the interface mode selection register. This action overrides the per-channel programming in the connection memory bits. The connection memory data can be accessed via the microprocessor interface. The addressing of the devices internal registers, data and connection memories is performed through the address input pins and the Memory Select (MS) bit of the control register. For details on device addressing, see Software Control and Control Register bits description (Table 3 and 5). The IDT72V70180 is capable of switching 128 x 128, 64 Kbit/s PCM or N x 64 Kbit/s channel data. The device maintains frame integrity in data applications and minimum throughput delay for voice applications on a per channel basis. The serial input streams of the IDT72V70180 can have a bit rate of 2.048 Mb/s and are arranged in 125μs wide frames, which contain 32 channels respectively. The data rates on input and output streams are identical. In Processor Mode, the microprocessor can access input and output timeslots on a per channel basis allowing for transfer of control and status information. The IDT72V70180 automatically identifies the polarity of the frame synchronization input signal and configures the serial streams to either ST-BUS® or GCI formats. With the variety of different microprocessor interfaces, IDT72V70180 has provided an Input Mode pin (IM) to help integrate the device into different microprocessor based environments: Non-multiplexed or Multiplexed. These interfaces provide compatibility with multiplexed and Motorola non-multiplexed buses. The device can also resolve different control signals eliminating the use of glue logic necessary to convert the signals (R/W/WR, DS/RD, AS/ALE). The frame offset calibration function allows users to measure the frame offset delay using a frame evaluation pin (FE). The input offset delay can be programmed for individual streams using internal frame input offset registers, see Table 8. The internal loopback allows the TX output data to be looped around to the RX inputs for diagnostic purposes. A functional Block Diagram of the IDT72V70180 is shown in Figure 1. SERIAL DATA INTERFACE TIMING The master clock frequency must always be twice the data rate. For serial data rates of 2.048 Mb/s, the master clock (CLK) must be at 4.096 MHz. The input and output stream data rates will always be identical. The input 8 KHz frame pulse can be in either ST-BUS® or GCI format. The IDT72V70180 automatically detects the presence of an input frame pulse and identifies it as either ST-BUS® or GCI. In ST-BUS® format, every second falling edge of the master clock marks a bit boundary and the data is clocked in on the rising edge of CLK, three quarters of the way into the bit cell, see Figure 7. In GCI format, every second rising edge of the master clock marks the bit boundary and data is clocked in on the falling edge of CLK at three quarters of the way into the bit cell, see Figure 8. DATA AND CONNECTION MEMORY The received serial data is converted to parallel format by internal serialto-parallel converters and stored sequentially in the data memory. The 8KHz input frame pulse (F0i) is used to generate channel and frame boundaries of the input serial data. Depending on the interface mode select (IMS) register, the usable data memory may be as large as 128 bytes. Data to be output on the serial streams (TX0-3) may come from either the data memory or connection memory. For data output from data memory (connection mode), addresses in the connection memory are used. For data to be output from connection memory, the connection memory control bits must set the particular TX output in Processor Mode. One time-slot before the data is to be output, data from either connection memory or data memory is read internally. This allows enough time for memory access and parallel-to-serial conversion. INPUT FRAME OFFSET SELECTION Input frame offset selection allows the channel alignment of individual input streams to be offset with respect to the output stream channel alignment (i.e. F0i). Although all input data comes in at the same speed, delays can be caused by variable path serial backplanes and variable path lengths which may be implemented in large centralized and distributed switching systems. Because data is often delayed, this feature is useful in compensating for the skew between clocks. Each input stream can have its own delay offset value by programming the frame input offset registers (FOR). The maximum allowable skew is +4.5 master clock (CLK) periods forward with resolution of ½ clock period. The output frame offset cannot be offset or adjusted. See Figure 5, Table 8 and 9 for delay offset programming. CONNECTION AND PROCESSOR MODES In the Connection Mode, the addresses of the input source data for all output channels are stored in the connection memory. The connection memory is mapped in such a way that each location corresponds to an output channel on the output streams. For details on the use of the source address data (CAB and SAB bits), see Table 10. Once the source address bits are programmed by the microprocessor, the contents of the data memory at the selected address are transferred to the parallel-to-serial converters and then onto a TX output stream. By having the each location in the connection memory specify an input channel, multiple outputs can specify the same input address. This can be a powerful tool used for broadcasting data. In Processor Mode, the microprocessor writes data to the connection memory. Each location in the connection memory corresponds to a particular output stream and channel number and is transferred directly to the parallel-toserial converter one time-slot before it is to be output. This data will be output on the TX streams in every frame until the data is changed by the microprocessor. SERIAL INPUT FRAME ALIGNMENT EVALUATION The IDT72V70180 provides the frame evaluation (FE) input to determine different data input delays with respect to the frame pulse F0i. A measurement cycle is started by setting the start frame evaluation (SFE) bit low for at least one frame. When the SFE bit in the IMS register is changed from low to high, the evaluation starts. Two frames later, the complete frame evaluation (CFE) bit of the frame alignment register (FAR) changes from low to high to signal that a valid offset measurement is ready to be read from bits 0 to 11 of the FAR register. The SFE bit must be set to zero before a new measurement cycle started. 4 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE In ST-BUS® mode, the falling edge of the frame measurement signal (FE) is evaluated against the falling edge of the ST-BUS® frame pulse. In GCI mode, the rising edge of FE is evaluated against the rising edge of the GCI frame pulse. See Table 7 and Figure 4 for the description of the frame alignment register. to output time-slot 0. The maximum delay of 94 time-slots of delay occurs when time-slot 0 in a frame is switched to time-slot 31 in the frame. See Table 2. MICROPROCESSOR INTERFACE The IDT72V70180 provides a parallel microprocessor interface for multiplexed or non-multiplexed bus structures. This interface is compatible with Motorola non-multiplexed and multiplexed buses. If the IM pin is low a Motorola non-multiplexed bus should be connected to the device. If the IM pin is high, the device monitors the AS/ALE and DS/RD to determine what mode the IDT72V70180 should operate in. If DS/RD is low at the rising edge of AS/ALE, then the mode 1 multiplexed timing is selected. If DS/RD is high at the rising edge of AS/ALE, then the mode 2 multiplexed bus timing is selected. For multiplexed operation, the required signals are the 8-bit data and address (AD0-AD7), 8-bit Data (D8-D15), Address strobe/Address latch enable (AS/ ALE), Data strobe/Read (DS/RD), Read/Write /Write (R/W / WR), Chip select (CS) and Data transfer acknowledge (DTA). See Figure 11 and Figure 12 for multiplexed parallel microport timing. For the Motorola non-multiplexed bus, the required signals are the 16-bit data bus (AD0-AD7, D8-D15), 8-bit address bus (A0-A7) and 4 control lines (CS, DS, R/W and DTA). See Figure 13 and 14 for Motorola non-multiplexed microport timing. The IDT72V70180 microport provides access to the internal registers, connection and data memories. All locations provide read/write access except for the data memory and the frame alignment register which are read only. MEMORY BLOCK PROGRAMMING The IDT72V70180 provides users with the capability of initializing the entire connection memory block in two frames. To set bits 11 to 15 of every connection memory location, first program the desired pattern in bits 5 to 9 of the IMS register. The block programming mode is enabled by setting the memory block program (MBP) bit of the control register high. When the block programming enable (BPE) bit of the IMS register is set to high, the block programming data will be loaded into the bits 11 to 15 of every connection memory location. The other connection memory bits (bit 0 to bit 10) are loaded with zeros. When the memory block programming is complete, the device resets the BPE bit to zero. LOOPBACK CONTROL The loopback control (LPBK) bit of each connection memory location allows the TX output data to be looped backed internally to the RX input for diagnostic purposes. If the LPBK bit is high, the associated TX output channel data is internally looped back to the RX input channel (i.e., data from TX n channel m routes to the RX n channel m internally); if the LPBK bit is low, the loopback feature is disabled. For proper per-channel loopback operation, the contents of frame delay offset registers must be set to zero. DELAY THROUGH THE IDT72V70180 MEMORY MAPPING The address bus on the microprocessor interface selects the internal registers and memories of the IDT72V70180. If the A7 address input is low, then A6 through A0 are used to address the interface mode selection (IMS), control (CR), frame alignment (FAR) and frame input offset (FOR) registers (Table 4). If the A7 is high, A6 and A5 are low, then A4 through A0 are used to select 32 locations corresponding to data rate of the ST-BUS®. The address input lines and the stream address bits (STA) of the control register allow access to the entire data and connection memories. The control and IMS registers together control all the major functions of the device, see Figure 3. As explained in the Serial Data Interface Timing and Switching Configurations sections, after system power-up, the IMS register should be programmed immediately to establish the desired switching configuration. The data in the control register consists of the memory block programming bit (MBP), the memory select bit (MS) and the stream address bits (STA). As explained in the Memory Block Programming section, the MBP bit allows the entire connection memory block to be programmed. The memory select bit is used to designate the connection memory or the data Memory. The stream address bits select internal memory subsections corresponding to input or output serial streams. The data in the IMS register consists of block programming bits (BPD0BPD4), block programming enable bit (BPE), output stand by bit (OSB) and start frame evaluation bit (SFE). The block programming and the block programming enable bits allows users to program the entire connection memory (see Memory Block Programming section). If the ODE pin is low, the OSB bit enables (if high) or disables (if low) all ST-BUS® output drivers. If the ODE pin is high, the contents of the OSB bit is ignored and all TX output drivers are enabled. The switching of information from the input serial streams to the output serial streams results in a throughput delay. The device can be programmed to perform time-slot interchange functions with different throughput delay capabilities on the per-channel basis. For voice applications, variable throughput delay is best as it ensures minimum delay between input and output data. In wideband data applications, constant throughput delay is best as the frame integrity of the information is maintained through the switch. The delay through the device varies according to the type of throughput delay selected in the V/C bit of the connection memory. VARIABLE DELAY MODE (V/C BIT = 0) In this mode, the delay is dependent only on the combination of source and destination channels and is independent of input and output streams. The minimum delay achievable in the IDT72V70180 is three time-slots. If the input channel data is switched to the same output channel (channel n, frame p), it will be output in the following frame (channel n, frame p+1). The same is true if input channel n is switched to output channel n+1 or n+2. If the input channel n is switched to output channel n+3, n+4,..., the new output data will appear in the same frame. Table 1 shows the possible delays for the IDT72V70180 in the variable delay mode. CONSTANT DELAY MODE (V/C BIT = 1) In this mode, frame integrity is maintained in all switching configurations by making use of a multiple data memory buffer. Input channel data is written into the data memory buffers during frame n will be read out during frame n+2. In the IDT72V70180, the minimum throughput delay achievable in the constant delay mode will be one frame. For example, when input time-slot 31 is switched 5 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE If the LPBK bit is high, the associated TX output channel data is internally looped back to the RX input channel (i.e., RX n channel m data comes from the TX n channel m). If the LPBK bit is low, the loopback feature is disabled. For proper per-channel loopback operation, the contents of the frame delay offset registers must be set to zero. CONNECTION MEMORY CONTROL If the ODE pin or the OSB bit is high, the OE bit of each connection memory location controls the output drivers-enables (if high) or disables (if low). See Table 4 for detail. The processor channel (PC) bit of the connection memory selects between Processor Mode and Connection Mode. If high, the contents of the connection memory are output on the TX streams. If low, the stream address bit (SAB) and the channel address bit (CAB) of the connection memory defines the source information (stream and channel) of the time-slot that will be switched to the output from data memory. The V/C (Variable/Constant Delay) bit in each connection memory location allows the per-channel selection between variable and constant throughput delay modes. Control Register CRb7 CRb6 CRb5 INITIALIZATION OF THE IDT72V70180 After power up, the state of the connection memory is unknown. As such, the outputs should be put in high impedance by holding the ODE low. While the ODE is low, the microprocessor can initialize the device, program the active paths, and disable unused outputs by programming the OE bit in connection memory. Once the device is configured, the ODE pin (or OSB bit depending on initialization) can be switched. CRb4 CRb3 CRb2 CRb1 CRb0 CRb4 0 1 The Control Register is only accessed when A7-A0 are all zeroed. When A7 =1, up to 32 bytes are randomly accessable via A0-A4 at any one instant. Of which stream these bytes (channels) are accessed is determined by the state of CRb1 -CRb0. Connection Memory Data Memory CRb1 Channel 0 Channel 1 Channel 2 Channel 0 Channel 0 Channel 0 Channel 1 Channel 1 Channel 1 Channel 2 Channel 2 Channel 2 Channel 31 Channel 31 Channel 31 Channel 31 10000000 10000001 10000010 10011111 0 0 1 1 CRb0 Stream 0 0 1 1 2 0 1 3 External Address Bits A7-A0 5716 drw03 Figure 3. Addressing Internal Memories 6 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 2 — CONSTANT THROUGHPUT DELAY VALUE TABLE 1 — VARIABLE THROUGHPUT DELAY VALUE Delay for Variable Throughput Delay Mode Input Rate (m – output channel number) (n – input channel number) m n+2 2.048 Mb/s 32 – (n-m) time-slots m-n + 32 time-slots m-n time-slots Input Rate 2.048 Mb/s Delay for Constant Throughput Delay Mode (m – output channel number) (n – input channel number) 32 + (32 – n) + m time-slots TABLE 3 — INTERNAL REGISTER AND ADDRESS MEMORY MAPPING A7(1) A6 A5 A4 A3 A2 A1 A0 Location 0 0 0 0 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 . 1 1 0 0 0 0 0 0 . 1 1 0 0 0 0 0 0 . 1 1 0 0 1 1 0 0 . 1 1 0 1 0 1 0 1 . 0 1 Control Register, CR Interface Mode Selection Register, IMS Frame Alignment Register, FAR Frame Input Offset Register, FOR Ch0 Ch1 . Ch30 Ch31 NOTE: 1. Bit A7 must be high for access to data and connection memory positions. Bit A7 must be low for access to registers. TABLE 4 — OUTPUT HIGH IMPEDANCE CONTROL OE bit in Connection Memory 0 ODE pin Don’t Care OSB bit in IMS Register Don’t Care 1 1 1 1 0 0 1 1 0 1 1 0 7 TX Output Driver Status Per Channel High-Impedance High-Impedance Enable Enable Enable IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 5 — CONTROL REGISTER (CR) BITS Read/Write Address: 00H. Reset Value: 0000H. 15 14 13 12 11 10 9 8 7 6 5 4 3 2 0 0 0 0 0 0 0 0 0 0 MBP MS 0 0 Bit 15-6 5 1 0 STA1 STA0 Name Unused MBP (Memory Block Program) Description Must be zero for normal operation. When 1, the connection memory block programming feature is ready for the programming of Connection Memory high bits, bit 11 to bit 15. When 0, this feature is disabled. MS (Memory Select) When 0, connection memory is selected for read or write operations. When 1, the data memory is selected for read operations and connection memory is selected for write operations. (No microprocessor write operation is allowed for the data memory). 3-2 Unused Must be zero for normal operation. 1-0 STA1-0 (Stream Address Bits) The binary value expressed by these bits refers to the input or output data stream, which corresponds to the subsection of memory made accessible for subsequent operations. (STA1 = MSB, STA0 = LSB) 4 TABLE 6 — INTERFACE MODE SELECTION (IMS) REGISTER BITS Read/Write Address: Reset Value: 01H, 0000H. 15 14 13 12 11 10 0 0 0 0 0 0 Bit 15-10 9 8 7 6 5 BPD4 BPD3 BPD2 BPD1 BPD0 Name 4 3 2 1 0 BPE OSB SFE 0 0 Description Unused Must be zero for normal operation. 9-5 BPD4-0 (Block Programming Data) These bits carry the value to be loaded into the connection memory block whenever the memory block programming feature is activated. After the MBP bit in the control register is set to 1 and the BPE bit is set to 1, the contents of the bits BPD4-0 are loaded into bit 15 and 11 of the connection memory. Bit 10 to bit 0 of the connection memory are set to 0. 4 BPE (Begin Block Programming Enable) A zero to one transition of this bit enables the memory block programming function. The BPE and BPD4-0 bits in the IMS register have to be defined in the same write operation. Once the BPE bit is set HIGH, the device requires two frames to complete the block programming. After the programming function has finished, the BPE bit returns to zero to indicate the operation is completed. When the BPE = 1, the BPE or MBP can be set to 0 to abort to ensure proper operation. When BPE = 1, the other bit in the IMS register must not be changed for two frames to ensure proper operation. 3 OSB (Output Stand By) When ODE = 0 and OSB = 0, the output drivers of TX0 to TX3 are in high impedance mode. When ODE= 0 and OSB = 1, the output driver of TX0 to TX3 function normally. When ODE = 1, TX0 to TX3 output drivers function normally. 2 SFE (Start Frame Evaluation) A zero to one transition in this bit starts the frame evaluation procedure. When the CFE bit in the FAR register changes from zero to one, the evaluation procedure stops. To start another fame evaluation cycle, set this bit to zero for at least one frame. Unused Must be zero for normal operation. 1-0 8 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 7 — FRAME ALIGNMENT REGISTER (FAR) BITS Read/Write Address: Reset Value: 02H. 0000H. 15 14 13 12 0 0 0 CFE Bit 15-13 12 11 10-0 11 10 FD11 FD10 Name Unused CFE (Complete Frame Evaluation) FD11 (Frame Delay Bit 11) FD10-0 (Frame Delay Bits) 9 8 7 6 5 4 3 2 1 0 FD9 FD8 FD7 FD6 FD5 FD4 FD3 FD2 FD1 FD0 Description Must be zero for normal operation. When CFE =1, the frame evaluation is completed and bits FD10 to FD0 bits contains a valid frame alignment offset. This bit is reset to zero, when SFE bit in the IMS register is changed from 1 to 0. The falling edge of FE (or rising edge for GCI mode) is sampled during the CLK-high phase (FD11 = 1) or during the CLK-low phase (FD11 = 0). This bit allows the measurement resolution to ½ CLK cycle. The binary value expressed in these bits refers to the measured input offset value. These bits are rest to zero when the SFE bit of the IMS register changes from 1 to 0. (FD10 – MSB, FD0 – LSB) ST-BUS® Frame CLK Offset Value 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 13 14 15 FE Input (FD[10:0] = 06H) (FD11 = 0, sample at CLK LOW phase) GCI Frame CLK Offset Value 0 1 2 3 4 5 6 7 8 9 10 11 12 FE Input (FD[10:0] = 09H) (FD11 = 1, sample at CLK HIGH phase) 5716 drw04 Figure 4. Example for Frame Alignment Measurement 9 16 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 8 — FRAME INPUT OFFSET REGISTER (FOR) BITS Read/Write Address: Reset Value: 03H. 0000H. 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 OF32 OF31 OF30 DLE3 OF22 OF21 OF20 DLE2 OF12 OF11 OF10 DLE1 OF02 OF01 OF00 DLE0 FOR Register Name(1) OFn2, OFn1, OFn0 (Offset Bits 2, 1 & 0) DLEn (Data Latch Edge) Description These three bits define how long the serial interface receiver takes to recognize and store bit 0 from the RX input pin: i.e., to start a new frame. The input frame offset can be selected to +4.5 clock periods from the point where the external frame pulse input signal is applied to the F0i input of the device. See Figure 5. ST-BUS® mode: GCI mode: DLEn = 0, if clock rising edge is at the ¾ point of the bit cell. DLEn = 1, if when clock falling edge is at the ¾ of the bit cell. DLEn = 0, if clock falling edge is at the ¾ point of the bit cell. DLEn = 1, if when clock rising edge is at the ¾ of the bit cell. NOTE: 1. n denotes an input stream number from 0 to 3. 10 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 9 — OFFSET BITS (OFn2, OFn1, OFn0, DLEn) & FRAME DELAY BITS (FD11, FD2-0) Measurement Result from Frame Delay Bits Input Stream Offset No clock period shift (Default) + 0.5 clock period shift + 1.0 clock period shift + 1.5 clock period shift + 2.0 clock period shift + 2.5 clock period shift + 3.0 clock period shift + 3.5 clock period shift + 4.0 clock period shift + 4.5 clock period shift FD11 1 0 1 0 1 0 1 0 1 0 FD2 0 0 0 0 0 0 0 0 1 1 FD1 0 0 0 0 1 1 1 1 0 0 Corresponding Offset Bits FD0 0 0 1 1 0 0 1 1 0 0 OFn2 0 0 0 0 0 0 0 0 1 1 OFn1 0 0 0 0 1 1 1 1 0 0 OFn0 0 0 1 1 0 0 1 1 0 0 DLEn 0 1 0 1 0 1 0 1 0 1 ST-BUS® F0i CLK RX Stream Bit 7 RX Stream Bit 7 Bit 7 RX Stream Bit 7 RX Stream offset = 0, DLE = 0 offset = 1, DLE = 0 offset = 0, DLE = 1 offset = 1, DLE = 1 offset = 0, DLE = 0 offset = 1, DLE = 0 offset = 0, DLE = 1 offset = 1, DLE = 1 denotes the 3/4 point of the bit cell GCI F0i CLK RX Stream Bit 0 Bit 0 RX Stream RX Stream RX Stream Bit 0 Bit 0 denotes the 3/4 point of the bit cell Figure 5. Examples for Input Offset Delay Timing 11 5716 drw 05 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE TABLE 10 — CONNECTION MEMORY BITS 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 LPBK V/C PC CCO OE 0 0 SAB1 SAB0 0 0 CAB4 CAB3 CAB2 CAB1 CAB0 Bit 15 14 13 12 11 10,9 8,7(1) 6,5(1) 4-0(1) Name LPBK (Per Channel Loopback) V/C (Variable/Constant Throughput Delay) PC (Processor Channel) CCO (Control Channel Output) OE (Output Enable) Unused SAB1-0 (Source Stream Address Bits) Unused CAB4-0 (Source Channel Address Bits) Description When 1, the RX n channel m data comes from the TX n channel m. For proper per channel loopback operations, set the delay offset register bits OFn[2:0] to zero for the streams which are in the loopback mode. This bit is used to select between the variable (LOW) and constant delay (HIGH) mode on a per-channel basis. When 1, the contents of the connection memory are output on the corresponding output channel and stream. Only the lower byte (bit 7 – bit 0) will be output to the TX output pins. When 0, the contents of the connection memory are the data memory address of the switched input channel and stream. This bit is output on the CCO pin one channel early. The CCO bit for stream 0 is output first. This bit enables the TX output drivers on a per-channel basis. When 1, the output driver functions normally. When 0, the output driver is in a high-impedance state. Must be zero for normal operation. The binary value is the number of the data stream for the source of the connection. Must be zero for normal operation. The binary value is the number of the channel for the source of the connection. NOTE: 1. If bit 13 (PC) of the corresponding connection memory location is 1 (device in processor mode), then these entire 8 bits (SAB0, bits 6-5, CAB4 - CAB0) are output on the output channel and stream associated with this location. 12 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE ABSOLUTE MAXIMUM RATINGS(1) Symbol VCC Parameter Min. Max. Unit Supply Voltage -0.3 5.0 V GND -0.3 5.5 V 20 mA Vi Voltage on Digital Inputs IO Current at Digital Outputs TS Storage Temperature -65 +125 °C PD Package Power Dissapation ⎯ 1 W RECOMMENDED DC OPERATING CONDITIONS Symbol NOTE: 1. Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Parameter Min. Typ. Max. Units VCC Positive Supply 3.0 ⎯ 3.6 V VIH Input HIGH Voltage 2.0 ⎯ Vcc V VIL Input LOW Voltage GND ⎯ 0.8 V TOP Operating Temperature Commercial -40 ⎯ +85 °C NOTE: 1. Voltages are with respect to ground unless other wise stated. DC ELECTRICAL CHARACTERISTICS Symbol Characteristics Supply Current Min. @ 2.048 Mb/s Typ. Max. Units ⎯ 7 10 mA IIL Input Leakage (input pins) ⎯ ⎯ 15 μA IBL Input Leakage (I/O pins) ⎯ ⎯ 50 μA CI Input Pin Capacitance ⎯ ⎯ 10 pF ICC (1) IOZ High-impedance Leakage ⎯ ⎯ 5 μA VOH Output HIGH Voltage 2.4 ⎯ ⎯ V VOL Output LOW Voltage ⎯ ⎯ 0.4 V CO Output Pin Capacitance ⎯ ⎯ 10 pF NOTE: 1. Outputs Unloaded. Test Point S1 is open circuit except when testing output levels or high impedance states. S2 is switched to VCC or GND when testing output levels or high impedance states. VCC RL Output Pin S1 S2 CL GND GND 5716 drw06 Figure 6. Output Load 13 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS - FRAME PULSE AND CLK Symbol Characteristics Min. Typ. Max. Units tFPW Frame Pulse Width (ST-BUS , GCI) ⎯ Bit rate = 2.048 Mb/s 26 ⎯ 295 ns tFPS Frame Pulse Setup time before CLK falling (ST-BUS® or GCI) 5 ⎯ ⎯ ns ® tFPH Frame Pulse Hold Time from CLK falling (ST-BUS or GCI) 10 ⎯ ⎯ ns tCP CLK Period ⎯ Bit rate = 2.048 Mb/s 190 ⎯ 300 ns tCH CLK Pulse Width HIGH ⎯ Bit rate = 2.048 Mb/s 85 ⎯ 150 ns tCL CLK Pulse Width LOW ⎯ Bit rate = 2.048 Mb/s 85 ⎯ 150 ns tr, tf Clock Rise/Fall Time ⎯ ⎯ 10 ns ® AC ELECTRICAL CHARACTERISTICS - SERIAL STREAMS (1) Symbol Characteristics Min. Typ. Max. Unit Test Conditions tSIS RX Setup Time 0 ⎯ ⎯ ns tSIH RX Hold Time 10 ⎯ ⎯ ns tSOD TX Delay – Active to Active ⎯ ⎯ ⎯ ⎯ 30 40 ns ns CL = 30pF CL = 200pF tDZ TX Delay – Active to High-Z ⎯ ⎯ 32 ns RL = 1KΩ, CL = 200pF tZD TX Delay – High-Z to Active ⎯ ⎯ 32 ns RL = 1KΩ, CL = 200pF tODE Output Driver Enable (ODE) Delay ⎯ ⎯ 32 ns RL = 1KΩ, CL = 200pF NOTE: 1. High Impedance is measured by pulling to the appropriate rail with RL, with timing corrected to cancel time taken to discharge CL. 14 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE tFPW F0i tFPS tFPH tCH tCP tCL tr tf CLK tSOD Bit 0, Last Ch (1) TX Bit 7, Channel 0 tSIS RX Bit 0, Last Ch(1) Bit 6, Channel 0 Bit 5, Channel 0 tSIH Bit 7, Channel 0 Bit 6, Channel 0 Bit 5, Channel 0 5716 drw07 NOTE: 1. last channel = ch 31. Figure 7. ST-BUS® Timing tFPW F0i tFPS tFPH tCH tCP tCL tr tf CLK tSOD TX Bit 7, Last Ch(1) Bit 0, Channel 0 tSIS RX Bit 7, Last Ch(1) Bit 1, Channel 0 Bit 2, Channel 0 tSIH Bit 0, Channel 0 Bit 2, Channel 0 Bit 1, Channel 0 5716 drw08 NOTE: 1. last channel = ch 31. Figure 8. GCI Timing CLK (ST-BUS® or WFPS mode) CLK (GCI mode) tDZ ODE TX VALID DATA tODE tZD TX VALID DATA TX tODE VALID DATA 5716 drw09 5716 drw10 Figure 10. Output Driver Enable (ODE) Figure 9. Serial Output and External Control 15 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS - MULTIPLEXED BUS TIMING (INTEL) Symbol Parameter Min. Typ. Max. Units tALW ALE Pulse Width 20 ns tADS Address Setup from ALE falling 3 ns tADH Address Hold from ALE falling 3 ns tALRD RD Active after ALE falling 3 ns tDDR Data Setup from DTA LOW on Read 5 ns tCSRW CS Hold after RD/WR 5 ns tRW RD Pulse Width (Fast Read) 45 ns tCSR CS Setup from RD 0 ns tDHR(1) Data Hold after RD 10 tWW WR Pulse Width (Fast Write) 45 ns tALWR WR Delay after ALE falling 3 ns 20 CL = 150pF ns tCSW CS Setup from WR 0 ns tDSW Data Setup from WR (Fast Write) 20 ns tSWD Valid Data Delay on Write (Slow Write) tDHW Data Hold after WR Inactive tAKD Acknowledgment Delay: tAKH (1) Test Conditions 122 CL = 150pF, RL = 1K ns 5 ns CL = 150pF Reading/Writing Registers 43/43 ns Reading/Writing Memory 760/750 ns CL = 150pF 22 ns CL = 150pF, RL = 1K Acknowledgment Hold Time NOTE: 1. High Impedance is measured by pulling to the appropriate rail with RL, with timing corrected to cancel time taken to discharge CL. tALW ALE tADS tADH AD0-AD7 D8-D15 DATA ADDRESS tALRD tCSRW CS tCSR tDHR tRW RD tWW tCSW tDHW tDSW WR tALWR tSWD tAKD tDDR DTA tAKH 5716 drw11 Figure 11. Multiplexed Bus Timing (Intel Mode) 16 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS - MULTIPLEXED BUS TIMING (MOTOROLA) Symbol Parameter Min. tASW ALE Pulse Width 20 ns tADS Address Setup from AS falling 3 ns tADH Address Hold from AS falling 3 ns tDDR Data Setup from DTA LOW on Read 5 ns tCSH CS Hold after DS falling 0 ns tCSS CS Setup from DS rising 0 ns ns tDHW Data Hold after Write 5 tDWS Data Setup from DS – Write (Fast Write) 20 tSWD Valid Data Delay on Write (Slow Write) Typ. Max. Units CL = 150pF ns 122 ns tRWS R/W Setup from DS Rising 60 ns tRWH R/W Hold from DS Rising 5 ns tDHR(1) Data Hold after Read 10 tDSH DS Delay after AS falling 10 tAKD Acknowledgment Delay: 20 ns CL = 150pF, RL = 1K ns CL = 150pF Reading/Writing Registers 43/43 ns Reading/Writing Memory 760/750 ns CL = 150pF 22 ns CL = 150pF, RL = 1K Acknowledgment Hold Time tAKH(1) Test Conditions NOTE: 1. High Impedance is measured by pulling to the appropriate rail with RL, with timing corrected to cancel time taken to discharge CL. DS tRWH tRWS R/W tASW tDSH AS tADS AD0-AD7 D8-D15 WR AD0-AD7 D8-D15 RD CS tADH tSWD ADDRESS tDHW tDWS DATA tDHR ADDRESS DATA tCSH tCSS tDDR tAKD DTA tAKH 5716 drw12 Figure 12. Multiplexed Bus Timing (Motorola Mode) 17 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS-MOTOROLA NON-MULTIPLEXED BUS MODE Symbol Parameter Min. Typ. Max. Units tCSS CS Setup from DS falling 0 ns tRWS R/W Setup from DS falling 10 ns tADS Address Setup from DS falling 2 ns tCSH CS Hold after DS rising 0 ns tRWH R/W Hold after DS Rising 2 ns tADH Address Hold after DS Rising 2 ns tDDR Data Setup from DTA LOW on Read 2 tDHR Data Hold on Read 10 tDSW Data Setup on Write (Fast Write) 5 tSWD Valid Data Delay on Write (Slow Write) tDHW Data Hold on Write tAKD Acknowledgment Delay: tAKH(1) 20 Test Conditions ns CL = 150pF ns CL = 150pF, RL = 1K ns 122 ns 5 ns CL = 150pF Reading/Writing Registers 43/43 ns Reading/Writing Memory 760/750 ns CL = 150pF 22 ns CL = 150pF, RL = 1K Acknowledgment Hold Time NOTE: 1. High Impedance is measured by pulling to the appropriate rail with RL, with timing corrected to cancel time taken to discharge CL. DS tCSS tCSH tCSS tCSH CS tRWS tRWH tRWS tRWH R/W tADS A0-A7 tADH tDSW AD0-AD7/ D8-D15 tADH tADS VALID READ ADDRESS VALID WRITE ADDRESS tDHR tDHW VALID WRITE DATA VALID READ DATA tDDR tAKD tAKH tAKD tAKH DTA 5716 drw13 Figure 13. Motorola Non-Multiplexed Asyncronous Bus Timing 18 IDT72V70180 3.3V TIME SLOT INTERCHANGE DIGITAL SWITCH 128 x 128 COMMERCIAL TEMPERATURE RANGE CLK GCI CLK ST-BUS® tDSS tDSPW tDSS DS tCSS tCSH tCSS tCSH tRWS tRWH tRWS tRWH tADS tADH tADS tADH CS R/W A0-A7 tSWD AD0-AD7/ D8-D15 VALID READ ADDRESS VALID WRITE ADDRESS tDHW tDHR VALID WRITE DATA tCKAK VALID READ DATA tDDR tCKAK tAKH tAKH DTA 5716 drw14 Figure 14. Motorola Non-Multiplexed Syncronous Bus Timing 19 ORDERING INFORMATION IDT XXXXX XX XX Device Type Package Process/ Temp. Range Blank 0ºC to +70ºC T PFG TQFP – Green 72V70180 128 x 128 – 3.3V Time Slot Interchange Digital Switch DATASHEET DOCUMENT HISTORY 5/02/2000 pg.1 1/04/2001 1/25/2001 08/06/2001 03/24/2003 pgs. 4, 5, 9, 10, 13, 15, 16, 17, 18 and 19. pgs. 13 and 18. pg. 1 pg. 1 CORPORATE HEADQUARTER 2975 Stender Way Santa Clara, CA 95054 for SALES: 800-345-7015 or 408-727-6116 fax: 408-492-8674 www.idt.com 20 for Tech Support: 408-330-1753 email: TELECOMhelp@idt.com IMPORTANT NOTICE AND DISCLAIMER RENESAS ELECTRONICS CORPORATION AND ITS SUBSIDIARIES (“RENESAS”) PROVIDES TECHNICAL SPECIFICATIONS AND RELIABILITY DATA (INCLUDING DATASHEETS), DESIGN RESOURCES (INCLUDING REFERENCE DESIGNS), APPLICATION OR OTHER DESIGN ADVICE, WEB TOOLS, SAFETY INFORMATION, AND OTHER RESOURCES “AS IS” AND WITH ALL FAULTS, AND DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING, WITHOUT LIMITATION, ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT OF THIRD PARTY INTELLECTUAL PROPERTY RIGHTS. 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Renesas' products are provided only subject to Renesas' Terms and Conditions of Sale or other applicable terms agreed to in writing. No use of any Renesas resources expands or otherwise alters any applicable warranties or warranty disclaimers for these products. (Rev.1.0 Mar 2020) Corporate Headquarters Contact Information TOYOSU FORESIA, 3-2-24 Toyosu, Koto-ku, Tokyo 135-0061, Japan www.renesas.com For further information on a product, technology, the most up-to-date version of a document, or your nearest sales office, please visit: www.renesas.com/contact/ Trademarks Renesas and the Renesas logo are trademarks of Renesas Electronics Corporation. All trademarks and registered trademarks are the property of their respective owners. © 2020 Renesas Electronics Corporation. All rights reserved.
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