AD9888KS-170 Analog Devices Inc, AD9888KS-170 Datasheet - Page 27

AD9888KS-170

Manufacturer Part Number

AD9888KS-170

Description

IC ANALOG INTRFC 170MSPS 128MQFP

Manufacturer

Analog Devices Inc

Datasheet

1.AD9888KSZ-205.pdf (32 pages)

Specifications of AD9888KS-170

Rohs Status

RoHS non-compliant

Applications

Graphic Cards, VGA Interfaces

Interface

2-Wire Serial

Voltage - Supply

3 V ~ 3.6 V

Package / Case

128-MQFP, 128-PQFP

Mounting Type

Surface Mount

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Sync Processing

Mux

Number(s) Control Bit State

1 and 2

Sync Slicer

The purpose of the sync slicer is to extract the sync signal from

the green graphics channel. A sync signal is not present on all

graphics systems, only those with Sync-on-Green. The sync

signal is extracted from the green channel in a two-step process.

First, the SOG input is clamped to its negative peak (typically

0.3 V below the black level). Next, the signal goes to a comparator

with a variable trigger level, nominally 0.15 V above the clamped

level. The “sliced” sync is typically a composite sync signal

containing both Hsync and Vsync.

Sync Separator

A sync separator extracts the Vsync signal from a composite sync

signal. It does this through a low-pass filter-like or integrator-like

operation. It works on the idea that the Vsync signal stays active

for a much longer time than the Hsync signal. So, it rejects any

signal shorter than a threshold value, which is somewhere between

an Hsync pulsewidth and a Vsync pulsewidth.

The sync separator on the AD9888 is an 8-bit digital counter

with a 5 MHz clock. It works independently of the polarity of

the composite sync signal. (Polarities are determined elsewhere

on the chip.) The basic idea is that the counter counts up when

Hsync pulses are present. But since Hsync pulses are relatively

short in width, the counter only reaches a value of N before the

pulse ends. It then starts counting down, eventually reaching 0

before the next Hsync pulse arrives. The specific value of N will

vary for different video modes, but will always be less than 255.

For example, with a 1 µs width Hsync, the counter will only

REV. B

Table XLII. Control of the Sync Block Muxes via the

Serial Register

SDA

SCL

Serial Bus

0EH: Bit 3

0FH: Bit 5

0EH: Bit 0

15H: Bit 3

STAH

BUFF

Control Bit

DHO

Result

Pass HSYNC

Pass Sync-on-Green

Pass COAST

Pass Vsync

Pass Sync Separator

Signal

Pass Channel 0 Inputs

Pass Channel 1 Inputs

Figure 23. Serial Port Read/Write Timing

DAL

DAH

DSU

–27–

reach 5 (1 µs/200 ns = 5). Now, when Vsync is present on the

composite sync, the counter will also count up. However, since the

Vsync signal is much longer, it will count to a higher number M.

For most video modes, M will be at least 255. So, Vsync can be

detected on the composite sync signal by detecting when the

counter counts to higher than N. The specific count that

triggers detection (T) can be programmed through the serial

Once Vsync has been detected, there is a similar process to

detect when it goes inactive. At detection, the counter first resets

to 0, then starts counting up when Vsync goes away. Similar to

the previous case, it will detect the absence of Vsync when the

counter reaches the threshold count (T). In this way, it will

reject noise and/or serration pulses. Once Vsync is detected to

be absent, the counter resets to 0 and begins the cycle again.

PCB LAYOUT RECOMMENDATIONS

The AD9888 is a high precision, high speed analog device. To

get the maximum performance out of the part, it is important to

have a well laid-out board. The following is a guide for design-

ing a board using the AD9888.

Analog Interface Inputs

Using the following layout techniques on the graphics inputs is

extremely important.

Minimize the trace length running into the graphics inputs. This

is accomplished by placing the AD9888 as close as possible to

the graphics (VGA) connector. Long input trace lengths are

undesirable because they will pick up more noise from the board

and other external sources.

Place the 75 Ω termination resistors (see Figure 1) as close to

the AD9888 chip as possible. Any additional trace length

between the termination resistors and the input of the AD9888

increases the magnitude of reflections, which will corrupt the

graphics signal.

Use 75 Ω matched impedance traces. Trace impedances other

than 75 Ω will also increase the chance of reflections.

The AD9888 has very high input bandwidth (500 MHz). While

this is desirable for acquiring a high resolution PC graphics

signal with fast edges, it means that it will also capture any high

frequency noise present. Therefore, it is important to reduce the

amount of noise that gets coupled to the inputs. Avoid running

any digital traces near the analog inputs.

STASU

STOSU

AD9888

AD9888KS-170 Analog Devices Inc, AD9888KS-170 Datasheet - Page 27

AD9888KS-170

Specifications of AD9888KS-170

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