EL4585CSZ Intersil, EL4585CSZ Datasheet - Page 8

EL4585CSZ

Manufacturer Part Number

EL4585CSZ

Description

IC PLL VIDEO GP 36MHZ 16-SOIC

Manufacturer

Intersil

Type

Phase Lock Loop (PLL)r

Datasheet

1.EL4585CSZ.pdf (15 pages)

Specifications of EL4585CSZ

Pll

Yes

Input

Clock

Output

CMOS, TTL

Number Of Circuits

Ratio - Input:output

3:1

Differential - Input:output

No/No

Frequency - Max

36MHz

Divider/multiplier

Yes/No

Voltage - Supply

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

16-SOIC (3.9mm Width)

Frequency-max

36MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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varactor within this range. Crystal oscillators are more stable

than LC oscillators, which translates into lower jitter, but LC

oscillators can be pulled from their mid-point values further,

resulting in a greater capture and locking range. If the

incoming horizontal sync signal is known to be very stable,

then a crystal oscillator circuit can be used. If the H

signal experiences frequency variations of greater than

about 300ppm, an LC oscillator should be considered, as

crystal oscillators are very difficult to pull this far. When

charge pump output (pin 7) sources current into the filter

capacitor, increasing the voltage across the varactor, thus

tending to increase VCO frequency. Conversely, charge

pump output pulls current from the filter capacitor when

frequency lower.

Loop Filter

The loop filter controls how fast the VCO will respond to a

change in phase comparator output stimulus. Its

components should be chosen so that fast lock can be

achieved, yet with a minimum of VCO “hunting”, preferably in

one to two oscillations of charge pump output, assuming the

VCO frequency starts within capture range. If the filter is

under-damped, the VCO will over and under-shoot the

desired operating point many times before a stable lock

takes place. It is possible to under-damp the filter so much

that the loop itself oscillates, and VCO lock is never

achieved. If the filter is over-damped, the VCO response

time will be excessive and many cycles will be required for a

lock condition. Over-damping is also characterized by an

easily unlocked system because the filter can’t respond fast

enough to perturbations in VCO frequency. A severely over

damped system will seem to endlessly oscillate, like a very

large mass at the end of a long pendulum. Due to parasitic

effects of PCB traces and component variables, it will take

some trial and error experimentation to determine the best

values to use for any given situation. Use the component

tables as a starting point, but be aware that deviations from

these values are not out of the ordinary.

External Divide

DIV SEL (pin 8) controls the use of the internal divider. When

high, the internal divider is enabled and EXT DIV (pin 13)

outputs the CLK out divided by 2N. This is the signal to

which the horizontal sync input will lock. When divide select

is low, the internal divider output is disabled, and external

divide becomes an input from an external divider, so that a

divisor other than one of the 8 pre-programmed internal

divisors can be used.

Normal Mode

Normal mode is enabled by pulling COAST (pin 9) low

(below 1/3*V

frequency difference, an error signal is generated and sent

to the charge pump. The charge pump will either force

current into or out of the filter capacitor in an attempt to

SYNC

input frequency is greater than CLK frequency ÷ 2N,

frequency is less than CLK ÷ 2N, forcing the VCO

). If H

SYNC

and CLK ÷ 2N have any phase or

SYNC

EL4585

modulate the VCO frequency. Modulation will continue until

the phase and frequency of CLK ÷ 2N exactly match the

some offset in phase that is a function of the VCO

characteristics), the error signal goes to zero, lock detect no

longer pulses high, and the charge pump enters a high

impedance state. The clock is now locked to the H

input. As long as phase and frequency differences remain

small, the PLL can adjust the VCO to remain locked and lock

detect remains low.

Fast Lock Mode

Fast Lock mode is enabled by either allowing coast to float,

or pulling it to mid supply (between 1/3 and 2/3*V

mode, lock is achieved much faster than in normal mode, but

the clock divisor is modified on the fly to achieve this. If the

phase detector detects an error of enough magnitude, the

clock is either inhibited or reset to attempt a “fast lock” of the

signals. Forcing the clock to be synchronized to the H

input this way allows a lock in approximately 2 H-cycles, but

the clock spacing will not be regular during this time. Once

the near lock condition is attained, charge pump output

should be very close to its lock-on value, and placing the

device into normal mode should result in a normal lock very

quickly. Fast lock mode is intended to be used where H

becomes irregular, until a stable signal is again obtained.

Coast Mode

Coast mode is enabled by pulling COAST (pin 9) high

(above 2/3*V

is disabled and filter out remains in high impedance mode to

keep filter out voltage and VCO frequency as constant as

possible. VCO frequency will drift as charge leaks from the

filter capacitor, and the voltage changes the VCO operating

point. Coast mode is intended to be used when noise or

signal degradation result in loss of horizontal sync for many

cycles. The phase detector will not attempt to adjust to the

resultant loss of signal so that when horizontal sync returns,

sync lock can be re-established quickly. However, if much

VCO drift has occurred, it may take as long to re-lock as

when restarting.

Lock Detect

Lock detect (pin 12) will go low when lock is established. Any

DC current path from charge pump out will skew EXT DIV

relative to HSYNC in, tending to offset or add to the 200ns

internal delay, depending on which way the extra current is

flowing. This offset is called static phase error, and is always

present in any PLL system. If, when the part stabilizes in a

locked mode, lock detect is not low, adding or subtracting

from the loop filter series resistor R2 will change this static

phase error to allow LDET to go low while in lock. The goal is

to put the rising edge of EXT DIV in sync with the falling

edge of HSYNC + 200ns (see “Timing Diagrams” on

page 5). Increasing R2 decreases phase error, while

decreasing R2 increases phase error. (Phase error is

SYNC

input. When the phase and frequency match (with

). In coast mode the internal phase detector

September 3, 2009

SYNC

). In this

SYNC

FN7175.4

SYNC

EL4585CSZ Intersil, EL4585CSZ Datasheet - Page 8

EL4585CSZ

Specifications of EL4585CSZ

Available stocks

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