HW-XGI-VIDEO-US Xilinx Inc, HW-XGI-VIDEO-US Datasheet - Page 37

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HW-XGI-VIDEO-US

Manufacturer Part Number

HW-XGI-VIDEO-US

Description

DAUGHTER CARD VIDEO I/O VIODC

Manufacturer

Xilinx Inc

Datasheet

1.HW-XGI-VIDEO-US.pdf (68 pages)

Specifications of HW-XGI-VIDEO-US

Lead Free Status / RoHS Status

Lead free by exemption / RoHS compliant by exemption

Other names

122-1506
HW-XGI-VIDEO-US

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Bus Interface

Video Input/Output Daughter Card

UG235 (v1.2.1) October 31, 2007

Setting Black Levels

Setting Gain

R

(black arrows). It is also important to note that the VCO frequency range and charge pump

currents must be configured to match the expected frequency.

Setting the feedback divider correctly results in the correct sample frequency, but the

sample phase must also be set. Under ideal conditions, the phase delay would be T/2, to

sample at the center of the pixels. This makes T/2 a reasonable default value. Under actual

operating conditions, there can be skew between the HSYNC signal and the video data

thus requiring phase adjustment.

The process above is quite straightforward if one knows the proper settings for a given

source. VESA timing standards are a good place to start for standard resolutions.

Unfortunately, graphics adapters often do not follow these exactly. In this case, the PLL

divider value and phase must be adjusted to properly digitize the source. This process is

beyond the scope of this document.

The primary mechanism for setting the black level is the input clamp. This clamps the

input to ground, resulting in a DC offset in the coupling capacitor (just outside the

AD9887A) equal to the difference between the current input voltage and ground. After the

clamp is released, this difference is effectively subtracted from the raw input signal,

resulting in an input signal reference to ground. For this circuit to function properly, this

clamp should only be enabled when the input data is known to be black, such as during the

horizontal back porch. The AD9887A has a clamp placement register to control the start of

the clamp, in cycles after the falling edge of HSYNC. The clamp duration register controls

the length of the clamp, in cycles.

The AD9887A also includes offset registers to offset the black level of each color

individually. This control is typically not needed.

The AD9887A includes gain registers to adjust the input range of the ADC. Setting this too

low results in a dim display, while setting it too high results in saturation and clipping of

brighter colors.

The AD9887A data output is synchronous to a differential clock, DATACK. The pixel data

is 8 bits per color. There are two pixel buses, A and B. There are also three key sync signals

– HS, VS, and DE.

The data bus can be operated in either single pixel mode or dual pixel mode. Single pixel

mode only uses port A and the clock rate is equal to the pixel rate. In dual pixel mode, port

A carries even pixels and port B carries odd pixels, and the clock rate is half the pixel rate.

The single pixel more would be desirable to reduce the number of signals, but the

AD9887A has a max DATACK frequency of 140 MHz, so for pixel rates greater than

140 MHz, the bus has to be operated in dual pixel mode.

HSYNC

Sample

RGB

Figure 4-5: Ideal ADC Sampling Positions

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Bus Interface

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