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IDT72V71660DR

3.3 VOLT TIME SLOT INTERCHANGE DIGITAL SWITCH 16,384 X 16,384

Integrated Device Technology 

IDT72V71660 3.3V TIME SLOT INTERCHANGE

DIGITAL SWITCH 16,384 x 16,384

INDUSTRIAL TEMPERATURE RANGE

DESCRIPTION (CONTINUED)

The 64 serial input streams (RX) of the IDT72V71660 can run up to

16.384Mb/s allowing 256 channels per 125µs frame. The data rates on the

output streams (TX) are identical to those on the input streams (RX).

With two main operating modes, Processor Mode and Connection Mode, the

IDT72V71660 can easily switch data from incoming serial streams (Data

Memory) or from the controlling microprocessor via Connection Memory. As

control and status information is critical in data transmission, the Processor Mode

is especially useful when there are multiple devices sharing the input and output

streams.

With data coming from multiple sources and through different paths, data

entering the device is often delayed. To handle this problem, the IDT72V71660

has a Frame Evaluation feature to allow individual streams to be offset from the

frame pulse in half clock-cycle intervals up to +7.5 clock cycles.

The IDT72V71660 also provides a JTAG Test Access Port, memory block

programming, a simple microprocessor interface and automatic ST-BUS® /GCI

sensing to shorten setup time, aid in debugging and ease use of the device

without sacrificing capabilities.

FUNCTIONAL DESCRIPTION

DATA AND CONNECTION MEMORY

All data that comes in through the RX inputs go through a serial-to-parallel

conversion before being stored into internal Data Memory. The 8 KHz frame

pulse (FP) is used to mark the 125µs frame boundaries and to sequentially

address the input channels in Data Memory.

Data output on the TX streams may come from either the serial input streams

(Data Memory) or from the microprocessor (Connection Memory). In the case

that RX input data is to be output, the addresses in Connection Memory are used

to specify a stream and channel of the input. The Connection Memory is setup

in such a way that each location corresponds to an output channel for each

particular stream. In that way, more than one channel can output the same data.

In Processor Mode, the microprocessor writes data to the Connection Memory

locations corresponding to the stream and channel that is to be output. The lower

half (8 least significant bits) of the Connection Memory is output every frame until

the microprocessor changes the data or mode of the channel. By using this

Processor Mode capability, the microprocessor can access input and output

time-slots on a per-channel basis.

The two most significant bits of the Connection Memory are used to control

the per-channel mode of the out put streams. Specifically, the MOD1-0 bits are

used to select Processor Mode, Constant or Variable delay Mode, and the high-

impedance state of output drivers. If the MOD1-0 bits are set to 1-1 accordingly,

only that particular output channel (8 bits) will be in the high-impedance state.

If however, the ODE input pin is LOW and the Output Standby Bit in the Control

Register is LOW, all of the outputs will be in a high-impedance state even if a

particular channel in Connection Memory has enabled the output for that

channel. In other words, the ODE pin and Output Stand By control bit are master

output enables for the device (See Table 3).

SERIAL DATA INTERFACE TIMING

When a 16.384Mb/s serial data rate is required, the master clock frequency

will be running at 16.384 MHz resulting in a single-bit per clock. For all other

cases, 2.048Mb/s, 4.096Mb/s, and 8.192Mb/s, the master clock frequency will

be twice the data rate on the serial streams, resulting in two clocks per bit. Use

Table 5 to determine clock speed and the DR1-0 bits in the Control Register to

setup the device. The IDT72V71660 provides two different interface timing

modes, ST-BUS® or GCI. The IDT72V71660 automatically detects the pres-

ence of an input frame pulse and identifies it as either ST-BUS® or GCI.

In ST-BUS®, when running at 16.384 MHz, data is clocked out on the falling

edge and is clocked in on the subsequent rising-edge. At all other data rates,

there are two clock cycles per bit and 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 14 for timing.

In GCI format, when running at 16.384 MHz, data is clocked out on the rising

edge and is clocked in on the subsequent falling edge. At all other data rates,

there are two clock cycles per bit and 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 15 for timing.

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 . 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 input

streams.

Each input stream can have its own delay offset value by programming the

frame input offset registers (FOR, Table 8). The maximum allowable skew is +7.5

master clock (CLK) periods forward with a resolution of ½ clock period, see

Table 9. The output frame cannot be adjusted.

SERIAL INPUT FRAME ALIGNMENT EVALUATION

The IDT72V71660 provides the Frame Evaluation input to determine

different data input delays with respect to the frame pulse FP. A measurement

cycle is started by setting the Start Frame Evaluation bit of the Control Register

LOW for at least one frame. When the Start Frame Evaluation bit in the Control

Register is changed from LOW to HIGH, the evaluation starts. Two frames later,

the Complete Frame Evaluation bit of the Frame Alignment Register changes

from LOW to HIGH to signal that a valid offset measurement is ready to be read

from bits 0 to 11 of the Frame Alignment Register. The Start Frame Evaluation

bit must be set to zero before a new measurement cycle is started.

In ST-BUS ® mode, the falling edge of the frame measurement signal (Frame

Evaluation) is evaluated against the falling edge of the ST-BUS ® frame pulse.

In GCI mode, the rising edge of Frame Evaluation is evaluated against the rising

edge of the GCI frame pulse. See Table 7 and Figure 1 for the description of

the Frame Alignment Register.

MEMORY BLOCK PROGRAMMING

The IDT72V71660 provides users with the capability of initializing the entire

Connection Memory block in two frames. To set bits 14 and 15 of every

Connection Memory location, first program the desired pattern in the Block

Programming Data Bits (BPD 1-0), located in bits 7 and 8 of the Control Register.

The block programming mode is enabled by setting the Memory Block

Program bit of the Control Register HIGH. When the Block Programming Enable

bit of the Control Register is set to HIGH, the Block Programming Data will be

loaded into the bits 14 and 15 of every Connection Memory location. The other

Connection Memory bits (bit 0 to bit 13) are loaded with zeros. When the memory

block programming is complete, the device resets the Block Programming

Enable , BPD 1-0 and MBP bits to zero.

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