MK2069-01GITR IDT, Integrated Device Technology Inc, MK2069-01GITR Datasheet - Page 10

MK2069-01GITR

Manufacturer Part Number

MK2069-01GITR

Description

IC VCXO CLK SYNCHRONIZER 56TSSOP

Manufacturer

IDT, Integrated Device Technology Inc

Type

Clock Synchronizerr

Datasheet

1.MK2069-01GILF.pdf (21 pages)

Specifications of MK2069-01GITR

Pll

Yes

Input

LVCMOS

Output

LVCMOS

Number Of Circuits

Ratio - Input:output

3:3

Differential - Input:output

No/No

Frequency - Max

160MHz

Divider/multiplier

Yes/No

Voltage - Supply

3.15 V ~ 3.45 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

56-TSSOP

Frequency-max

160MHz

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Current page: 10 of 21
Download datasheet (212Kb)

previously selected input. The phase compensation circuit

allows the VCXO PLL to quickly lock to the new input phase

without producing extra clock cycles or clock wander,

assuming the new clock is at the same frequency.

Input pin CLR controls the phase compensation circuit. CLR

must remain high for normal operation. When used in

conjunction with the input MUX select pins, CLR should be

brought low prior to MUX reselection, then returned high

after MUX reselection. This prevents the VCXO PLL from

attempting to lock to the new input clock phase associated

with the input clock.

When CLR is high, the VCXO PLL operates normally.

When CLR is low, the VCXO PLL charge pump output is

inactivated which means that no charge pump correction

pulses are provided to the loop filter. During this time, the

VCXO frequency is held constant by the residual charge or

voltage on the PLL loop filter, regardless of the input clock

condition. However, the VCXO frequency will drift over time,

eventually to the minimum pull range of the crystal, due to

leak-off of the loop filter charge. This means that CLR can

provide a holdover function, but only for a very short

duration, typically in milliseconds.

Upon bringing CLR high, the FV Divider is reset and begins

counting upon with the first positive edge of the new input

clock, and the charge pump is re-activated. By resetting the

FV Divider, the memory of the previous input clock phase is

removed from the feedback divider, eliminating the

generation of extra VCLK clock cycle that would occur if the

loop was to re-lock under normal means. Lock time is also

reduced, as is the generation of clock wander.

By using CLR in this fashion VCLK will align to the input

clock phase with only one or two VCLK cycle slips resulting.

When CLR is not used, the number of VCLK cycle slips can

be as high the FV Divider value.

TCLK is always locked to VCLK regardless of the state of

the CLR input.

Lock Detection

The MK2069-01 includes a lock detection feature that

indicates lock status of VCLK relative to the selected input

reference clock. When phase lock is achieved (such as

following power-up), the LD output goes high. When phase

lock is lost (such as when the input clock stops, drifts beyond

the pullable range of the crystal, or suddenly shifts in

IDT® VCXO-BASED LINE CARD CLOCK SYNCHRONIZER

MK2069-01

VCXO-BASED LINE CARD CLOCK SYNCHRONIZER

phase), the LD output goes low.

The definition of a “locked” condition is determined by the

user. LD is high when the VCXO PLL phase detector error

is below the user-defined threshold. This threshold is set by

external components RLD and CLD shown in the Lock

Detection Circuit Diagram, below.

To help guard against false lock indications, the LD pin will

go high only when the phase error is below the set threshold

for 8 consecutive phase detector cycles. The LD pin will go

low when the phase error is above the set threshold for only

1 phase detector cycle.

The lock detector threshold (phase error) is determined by

the following relationship:

Lock Detector Application example:

Under ideal conditions, where the VCXO is phase- locked to

a low-jitter reference input, loop phase error is typically

maintained to within a few nanoseconds.

(LD Threshold) = 0.6 x R x C

Where:

The desired maximum allowable loop phase error for a

generated 19.44MHz clock is 100UI which is 5.1 s.

Solution: 5.1 s = (0.001 F) x (8.5 k

1 k < R < 1 M (to avoid excessive noise or leakage)

C > 50 pF (to avoid excessive error due to stray

capacitance, which can be as much as 10 pF

including Cin of LDC)

VCXO AND SYNTHESIZER

MK2069-01

REV K 051310

MK2069-01GITR IDT, Integrated Device Technology Inc, MK2069-01GITR Datasheet - Page 10

MK2069-01GITR

Specifications of MK2069-01GITR

Related parts for MK2069-01GITR