ICS1562B Datasheet, PDF(2/20 Page) Integrated Circuit Systems – User Programmable Differential Output Graphics Clock Generator

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ICS1562B Datasheet, PDF (2/20 Pages) Integrated Circuit Systems – User Programmable Differential Output Graphics Clock Generator

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ICS1562B

Overview

PLL Post-Scaler

The ICS1562B is ideally suited to provide the graphics system

clock signals required by high-performance video DACs.

Fully programmable feedback and reference divider capability

allow virtually any frequency to be generated, not just simple

multiples of the reference frequency. The ICS1562B uses the

latest generation of frequency synthesis techniques developed

by ICS and is completely suitable for the most demanding

video applications.

PLL Synthesizer Description -

Ratiometric Mode

A programmable post-scaler may be inserted between the VCO

and the CLK+ and CLK- outputs of the ICS1562B. This is

useful in generating lower frequencies, as the VCO has been

optimized for high-frequency operation.

The post-scaler allows the selection of:

â¢ VCO frequency

â¢ VCO frequency divided by 2

â¢ VCO frequency divided by 4

â¢ Internal register bit (AUXCLK) value

The ICS1562B generates its output frequencies using phase-

locked loop techniques. The phase-locked loop (or PLL) is a

closed-loop feedback system that drives the output frequency

to be ratiometrically related to the reference frequency pro-

vided to the PLL (see Figure 1). The reference frequency is

generated by an on-chip crystal oscillator or the reference

frequency may be applied to the ICS1562B from an external

frequency source.

The phase-frequency detector shown in the block diagram

drives the voltage-controlled oscillator, or VCO, to a frequency

that will cause the two inputs to the phase-frequency detector

to be matched in frequency and phase. This occurs when:

Load Clock Divider

The ICS1562B has an additional programmable divider (re-

ferred to in Figure 1 as the N1 divider) that is used to generate

the LOAD clock frequency for the video DAC. The modulus

of this divider may be set to 3, 4, 5, 6, 8, 10, 12, 16 or 20 under

duty factor to be 50/50, even when an odd modulus is selected.

The input frequency to this divider is the output of the PLL

post-scaler described above. Additionally, this divider can be

disabled under register control.

F(VCO): =

F(XTAL1) . Feedback Divider

Reference Divider

This expression is exact; that is, the accuracy of the output

frequency depends solely on the reference frequency provided

to the part (assuming correctly programmed dividers).

The VCO gain is programmable, which permits the ICS1562B

to be optimized for best performance at all operating frequencies.

The reference divider may be programmed for any modulus

from 1 to 128 in steps of one.

The feedback divider may be programmed for any modulus

from 37 through 448 in steps of one. Any even modulus from

448 through 896 can also be achieved by setting the âdoubleâ

bit which doubles the feedback divider modulus. The feedback

divider makes use of a dual-modulus prescaler technique that

allows the programmable counters to operate at low speed

without sacrificing resolution. This is an improvement over

conventional fixed prescaler architectures that typically im-

pose a factor-of-four penalty (or larger) in this respect.

Digital Inputs - ICS1562B-001 Option

The AD0-AD3 pins and the STROBE pin are used to load all

control registers of the ICS1562B (-001 option). The AD0-

AD3 and STROBE pins are each equipped with a pull-up and

will be at a logic HIGH level when not connected. They may

be driven with standard TTL or CMOS logic families.

The address of the register to be loaded is latched from the

AD0-AD3 pins by a negative edge on the STROBE pin. The

data for that register is latched from the AD0-AD3 pins by a

positive edge on the STROBE pin. See Figure 2 for a timing

diagram. After power-up, the ICS1562B-001 requires 32 reg-

ister writes for new programming to become effective. Since

only 13 registers are used at present, the programming system

can perform 19 âdummyâ writes to address 13 or 14 to com-

plete the sequence.

Table 1 permits the derivator of âAâ & âMâ converter program-

ming directly from desired modulus.

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