PCK2023DGG Philips Semiconductors, PCK2023DGG Datasheet - Page 22

PCK2023DGG

Manufacturer Part Number

PCK2023DGG

Description

CK408 66/100/133/200 MHz spread spectrum differential system clock generator

Manufacturer

Philips Semiconductors

Datasheet

1.PCK2023DGG.pdf (30 pages)

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

PCK2023DGG

Manufacturer:

PHILIPS/飞利浦

Quantity:

20 000

Current page: 22 of 30
Download datasheet (178Kb)

Most of these values can be determined from the usage in the board

drives at a time, so the current is really steered rather than switched.

LC circuit (the IC leads act as inductors). Also, it is possible to cause

Philips Semiconductors

Component decoupling

Decoupling is another important consideration to ensure optimum

operation of the PCK2023. A first pass decoupling capacitor value

may be determined by applying the following equation:

adequate

The maximum current may be determined by considering the

switching of the clock outputs and the capacitive load on these

outputs. The following equation may be used to determine the

current per output. Once the current for each clock output is

determined, they can be summed to determine the total switching

current.

design. For example, the IOCLK has a specified edge rate of

1.25 ns typical when slewing between 0.7 and 2.4 volts and the

maximum C

since, although the output either drives current or is off, only one

The act of steering the current reduces switching noise on these

supplies, therefore the HOST supplies require less decoupling. As a

starting point, assume the supply current for each HOST output is

equal to 1/2 the programmed output current.

Decoupling capacitors should be located as close to the power pins

on the IC as possible. The use of too much decoupling should be

avoided since it could cause oscillations on the part because of the

oscillations from resonance between the board inductance and

board capacitance. Two capacitors may be placed in parallel to

effectively extend the capacitance range of the decoupling since the

larger capacitor will have a self-resonance at a lower frequency than

the smaller capacitor. When using this method, the split between

values should be 100 (i.e., 0.1 F and 0.001 F).

Another consideration when selecting the decoupling capacitors is

the dielectric material of the capacitor. This will depend on the

frequency range of concern. For lower frequencies, Z5U material

may be used since this type of capacitor has a self-resonance in the

1 MHz to 20 MHz range. Capacitors of NPO have a self-resonance

much higher and are more for high frequency decoupling. Consult a

2001 Sep 07

CK408 (66/100/133/200 MHz) spread

spectrum differential system clock generator

V is the maximum supply noise permitted (20 mV, for example)

I is the maximum current draw for the clock

psw

max

bypass

is the power supply lead inductance

is the frequency below which the power supply wiring is

load

2pL

2pF

max

psw

load

psw

is 30 pF. The HOST outputs are a special case

max

where

on the pin side while rejecting the digital switching noise. A spectrum

capacitor manufacture’s datasheet to determine the optimum

material type to use.

Additional filtering on the Analog supplies (AV

reduce the noise coupled from the circuit board global V

internal V

The specific values should be selected to allow proper decoupling

analyzer can provide considerable insight to ensure optimum values

are selected. Measure the frequency content of the supply on either

side of the inductor to verify the values selected reduce the noise on

the component side of the filter. To provide the maximum isolation,

each AV

circuitry using these lines have very different switching

requirements. In general, pin 25 is strictly a static current draw and

should not have any switching noise. Great care has been taken to

reduce the sensitivity to supply noise, but there is a finite limit to the

capability to do this, therefore added filtering on the board should

enhance performance. Pin 46 is used as a supply to the internal

PLLs. This node will contain some high frequency switching noise

since the internal PLLs operate up to 200 MHz. Again, additional

filtering will improve the performance of the part. If a single filter is

used for both supplies, noise from the PLL supply (pin 46) can

couple int the I

outputs.

Filtering on the I

additional filtering can be added on the I

additional filtering of the reference current. This reference current is

critical to the performance of the HOST outputs since variation in

this current is directly proportional to jitter on the HOST outputs.

On-die decoupling has been included to reduce noise on this node,

but additional decoupling could also be used to further reduce any

noise. Care must be taken with this approach to ensure the

capacitor and reference resistor share the same ground. Placing

both components side by side is an optimum configuration. This

external capacitor should not exceed TBD pF to ensure the current

source inside the PCK2023 can supply enough charge for this node

to reach reference value (1.1 volt).

ref

decoupling

line should have a separate filter since the internal

Figure 12. PI filter for all analog V

of the PCK2023. One way to do this is to use a PI filter.

ref

supply (pin 25) and increase the jitter of the HOST

supply has already been discussed, but

ref

DD3.3

pin (pin 26) to perform

) may be used to

PCK2023

lines

SW00858

Product data

to the

PCK2023DGG Philips Semiconductors, PCK2023DGG Datasheet - Page 22

PCK2023DGG

Available stocks

Related parts for PCK2023DGG