AD725ARZ Analog Devices Inc, AD725ARZ Datasheet - Page 13

AD725ARZ

Manufacturer Part Number

AD725ARZ

Description

IC ENCODER RGB TO NTSC 16-SOIC

Manufacturer

Analog Devices Inc

Type

Video Encoderr

Datasheet

1.AD725ARZ.pdf (20 pages)

Specifications of AD725ARZ

Applications

RGB To NTSC/PAL

Voltage - Supply, Digital

4.75 V ~ 5.25 V

Mounting Type

Surface Mount

Package / Case

16-SOIC (0.300", 7.5mm Width)

Input Format

Digital

Output Format

Analog

Power Dissipation Pd

800mW

Supply Voltage Range

4.75V To 5.25V

Operating Temperature Range

-40Â°C To +85Â°C

Tv / Video Case Style

SOIC

No. Of Pins

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Supply, Analog

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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REV. 0

Low Cost Crystal Oscillator

A low cost oscillator can be made that provides a CW clock that

can be used to drive both the AD725 4FSC and other devices in

the system that require a clock at this frequency. Figure 20 shows a

circuit that uses one inverter of a 74HC04 package to create a

crystal oscillator and another inverter to buffer the oscillator

and drive other loads. The logic family must be a CMOS type

that can support the frequency of operation, and it must NOT

be a Schmitt trigger type of inverter. Resistor R1 from input to

output of U1A linearizes the inverter’s gain such that it provides

useful gain and a 180 degree phase shift to drive the oscillator.

The crystal should be a parallel resonant type at the appropriate

frequency (NTSC/PAL, 4FSC). The series combination of C1

and C2 should approximately equal to the crystal manufacturer’s

specification for the parallel capacitance required for the crystal

to operate at its specified frequency. C1 will usually want to be

a somewhat smaller value because of the input parasitic capaci-

tance of the inverter. If it is desired to tune the frequency to

greater accuracy, C1 can be made still smaller and a parallel

adjustable capacitor can be used to adjust the frequency to the

desired accuracy.

Resistor R2 serves to provide the additional phase shift

required by the circuit to sustain oscillation. It can be sized by

R2 = 1/(2

low pass filter that suppresses oscillations at harmonics of the

fundamental of the crystal and to isolate the output of the in-

verter from the resonant load that the crystal network presents.

The basic oscillator described above is buffered by U1B to drive

the AD725 4FSC pin and other devices in the system. For a

system that requires both an NTSC and PAL oscillator, the

circuit can be duplicated by using a different pair of inverters

from the same package.

Dot Crawl

There are numerous distortions that are apparent in the presen-

tation of composite signals on TV monitors. These effects will

vary in degree depending on the circuitry used by the monitor

to process the signal and on the nature of the image being dis-

played. It is generally not possible to produce pictures on a

composite monitor that are as high quality as those produced by

standard quality RGB, VGA monitors.

One well known distortion of composite video images is called

dot crawl. It shows up as a moving dot pattern at the interface

between two areas of different color. It is caused by the inability

of the monitor circuitry to adequately separate the luminance

and chrominance signals.

One way to prevent dot crawl is to use a video signal that has

separate luminance and chrominance. Such a signal is referred

(OPT)

15pF

Figure 20. Low Cost Crystal Oscillator

47pF

f C2). Other functions of R2 are to provide a

HC04

U1A

200

60pF

HC04

U1B

TO PIN 3

OF AD725

TO OTHER

DEVICE CLOCKS

–13–

to as S-video or Y/C video. Since the luminance and chromi-

nance are already separated, the monitor does not have to per-

form this function. The S-video outputs of the AD725 can be

used to create higher quality pictures when there is an S-video

input available on the monitor.

Flicker

In a VGA conversion application, where the software controlled

registers are correctly set, there are two techniques that are

commonly used by VGA controller manufacturers to generate

the interlaced signal. Each of these techniques introduces a

unique characteristic into the display created by the AD725.

The artifacts described below are not due to the encoder or its

encoding algorithm as all encoders will generate the same dis-

play when presented with these inputs. They are due to the

method used by the controller display chip to convert a non-

interlaced output to an interlaced signal.

The first interlacing technique outputs a true interlaced signal

with odd and even fields (one each to a frame Figure 21a). This

provides the best picture quality when displaying photography,

CD video and animation (games, etc.). However, it will intro-

duce a defect commonly referred to as flicker into the display.

Flicker is a fundamental defect of all interlaced displays and is

caused by the alternating field characteristic of the interlace

technique. Consider a one pixel high black line which extends

horizontally across a white screen. This line will exist in only

one field and will be refreshed at a rate of 30 Hz (25 Hz for

PAL). During the time that the other field is being displayed the

line will not be displayed. The human eye is capable of detect-

ing this, and the display will be perceived to have a pulsating or

flickering black line. This effect is highly content sensitive and

is most pronounced in applications in which text and thin

horizontal lines are present. In applications such as CD video,

photography and animation, portions of objects naturally

occur in both odd and even fields and the effect of flicker is

imperceptible.

The second commonly used technique is to output an odd and

even field that are identical (Figure 21b). This ignores the data

that naturally occurs in one of the fields. In this case the same

one pixel high line mentioned above would either appear as a

two pixel high line, (one pixel high in both the odd and even field)

or not appear at all if it is in the data that is ignored by the control-

ler. Which of these cases occurs is dependent on the placement

of the line on the screen. This technique provides a stable (i.e.,

nonflickering) display for all applications, but small text can be

difficult to read and lines in drawings (or spreadsheets) can

disappear. As above, graphics and animation are not particularly

affected although some resolution is lost.

There are methods to dramatically reduce the effect of flicker and

maintain high resolution. The most common is to ensure that

display data never exists solely in a single line. This can be accom-

plished by averaging/weighting the contents of successive/multiple

noninterlaced lines prior to creating a true interlaced output (Fig-

ure 21c). In a sense, this provides an output that will lie between

the two extremes described above. The weight or percentage of

one line that appears in another, and the number of lines used,

are variables that must be considered in developing a system of

this type. If this type of signal processing is performed, it must

be completed prior to the data being presented to the AD725

for encoding.

AD725

AD725ARZ Analog Devices Inc, AD725ARZ Datasheet - Page 13

AD725ARZ

Specifications of AD725ARZ

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