AD8116JSTZ Analog Devices Inc, AD8116JSTZ Datasheet - Page 11

AD8116JSTZ

Manufacturer Part Number

AD8116JSTZ

Description

IC VIDEO CROSSPOINT SWIT 128LQFP

Manufacturer

Analog Devices Inc

Datasheet

1.AD8116JSTZ.pdf (28 pages)

Specifications of AD8116JSTZ

Function

Video Crosspoint Switch

Circuit

1 x 16:16

Voltage Supply Source

Dual Supply

Voltage - Supply, Single/dual (±)

±4.5 V ~ 5.5 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

128-LQFP

Crosspoint Switch Type

Analog

Control Interface

Serial

Supply Voltage Range

Â± 4.5V To Â± 5.5V

Operating Temperature Range

0Â°C To +70Â°C

Digital Ic Case Style

LQFP

No. Of Pins

128

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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THEORY OF OPERATION

Loading Data

Data to control the switches is clocked serially into an 80-bit

shift register and then transferred in parallel to an 80-bit latch.

The falling edge of CLK (the serial clock input) loads data into

the shift register. The first five bits of the 80 bits are loaded via

DATA IN (the serial data input) program OUT15. The first of

the five bits (D4) enables or disables the output. The next four

bits (D3–D0, D3 = MSB, D0 = LSB) determine which one of

the 16 inputs will be connected to OUT15 (only one of the 16

inputs can be connected to a given output). The remaining bits

program OUT14 through OUT00.

After the shift register is filled with the new 80 bits of control

data, UPDATE is activated (low) to transfer the data to the

parallel latches. The switch control latches are static and will

hold their data as long as power is applied.

To extend the number of switches in an array, the DATA

OUT and DATA IN pins of multiple AD8116s can be daisy-

chained together. The DATA OUT pin is the end of the shift

the follow-on AD8116. CE can be used to control the clocking

of data into selected devices.

Serial Logic

The AD8116 employs a serial interface for programming the

state of the crosspoint array. The 80-bit shift register (Figure

4) consists of static D flip-flops while the parallel latch uses

transparent latches that are latched by a logic high state of

UPDATE, and transparent on logic low of the same signal.

The 4-to-16 decoder is a small current-mode multilevel gate

array that steers a small select current to the selected point in the

crosspoint array.

The RESET signal is connected to only the enable/disable bit on

each output buffer. This means that the AD8116 will have a ran-

dom configuration on power-up. In normal operation though,

RESET and UPDATE can be used together to alternately

enable and disable an entire array at once, if desired.

Separate chip enable (CE), update (UPDATE) and serial data

out (DATA OUT) signals allow several options for program-

ming larger arrays of AD8116s. The function of each bit in the

80-bit word that programs the state of the AD8116 is shown in

Figure 4. In normal operation, the DATA OUT pin of one

AD8116 is connected to the DATA IN of the next. In this way, for

example, an array of eight AD8116s would be programmed with

one 640-bit sequence. In this mode CE is logic low and the

CLK and UPDATE pins are connected in parallel.

In one alternate mode of programming, the CE pin can be used

to select one AD8116 at a time. This might be desirable when

the ability to program just one device at a time is required. In

this mode CLK, UPDATE and DATA IN are all connected in

parallel. The user then selects each AD8116 in turn (with the

CE signal) and programs it with the desired data. Larger arrays

can also be programmed by connecting each DATA IN signal to

a larger parallel bus. In this way only 80 clock cycles would be

needed to program the entire array. The logic signals are con-

figured so that all programming can be accomplished with

synchronous logic and a continuous clock, so that no missing

cycles or delays need be generated.

APPLICATIONS

Multichannel Video

The excellent video specifications of the AD8116 make it an

ideal candidate for creating composite video crosspoint switches.

These can be made quite dense by taking advantage of the

AD8116’s high level of integration and the fact that composite

video requires only one crosspoint channel per system video

channel. There are, however, other video formats that can be

routed with the AD8116 requiring more than one crosspoint

channel per video channel.

Some systems use twisted pair wiring to carry video signals.

These systems utilize differential signals and can lower costs

because they use lower cost cables, connectors and termination

methods. They also have the ability to lower crosstalk and reject

common-mode signals, which can be important for equip-

ment that operates in noisy environments or where common-

mode voltages are present between transmitting and receiving

equipment.

In such systems, the video signals are differential; there is a

positive and negative (or inverted) version of the signals. These

complementary signals are transmitted onto each of the two

wires of the twisted pair, yielding a first order zero common-

mode voltage. At the receive end, the signals are differentially

received and converted back into a single-ended signal.

When switching these differential signals, two channels are

required in the switching element to handle the two differential

signals that make up the video channel. Thus, one differential

video channel is assigned to a pair of crosspoint channels, both

input and output. For a single AD8116, eight differential video

channels can be assigned to the 16 inputs and 16 outputs. This

will effectively form an 8 × 8 differential crosspoint switch.

Programming such a device will require that inputs and outputs

be programmed in pairs. This information can be deduced by

inspection of the programming format of the AD8116 and the

requirements of the system.

There are other analog video formats requiring more than one

analog circuit per video channel. One two-circuit format that is

more commonly being used in systems such as satellite TV,

digital cable boxes and higher quality VCRs, is called S-video or

Y/C video. This format carries the brightness (luminance or Y)

portion of the video signal on one channel and the color (chromi-

nance or C) on a second channel.

Since S-video also uses two separate circuits for one video chan-

nel, creating a crosspoint system requires assigning one video

channel to two crosspoint channels as in the case of a differen-

tial video system. Aside from the nature of the video format,

other aspects of these two systems will be the same.

There are yet other video formats using three channels to carry

the video information. Video cameras produce RGB (red, green,

blue) directly from the image sensors. RGB is also the usual

format used by computers internally for graphics. RGB can also

be converted to Y, R-Y, B-Y format, sometimes called YUV

format. These three-circuit video standards are referred to as

component analog video.

The three-circuit video standards require three crosspoint chan-

nels per video channel to handle the switching function. In a

fashion similar to the two-circuit video formats, the inputs and

outputs are assigned in groups of three and the appropriate logic

programming is performed to route the video signals.

AD8116

AD8116JSTZ Analog Devices Inc, AD8116JSTZ Datasheet - Page 11

AD8116JSTZ

Specifications of AD8116JSTZ

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