CY2509_05 Datasheet, PDF(3/6 Page) Cypress Semiconductor – Spread Aware™, Ten/Eleven Output Zero Delay Buffer

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CY2509_05 Datasheet, PDF (3/6 Pages) Cypress Semiconductor – Spread Aware™, Ten/Eleven Output Zero Delay Buffer

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CY2509/10

VDD

1 AGND

CLK 24

2 VDD

0.1ÂµF

3 Q0

4 Q1

AVDD23

VDD 22

0.1ÂµF

Q9 21

5 Q2

Q8 20

6 GND

GND 19

7 GND

GND 18

8 Q3

Q7 17

9 Q4

Q6 16

10 VDD

0.1ÂµF

11 OE

Q5 15

VDD 14

12 FBOUT FBIN 13

0.1ÂµF FB 3.3V

10 ÂµF

VDD

0.1ÂµF

VDD

Figure 1. Schematic

Spread Awareâ¢

Many systems being designed now utilize a technology called

Spread Spectrum Frequency Timing Generation. Cypress has

been one of the pioneers of SSFTG development, and we

designed this product so as not to filter off the Spread

Spectrum feature of the Reference input, assuming it exists.

When a zero delay buffer is not designed to pass the SS

feature through, the result is a significant amount of tracking

skew which may cause problems in systems requiring

synchronization.

For more details on Spread Spectrum timing technology,

please see the Cypress application note titled, âEMI

Suppression Techniques with Spread Spectrum Frequency

Timing Generator (SSFTG) ICs.â

How to Implement Zero Delay

Typically, Zero Delay Buffers (ZDBs) are used because a

designer wants to provide multiple copies of a clock signal in

phase with each other. The whole concept behind ZDBs is that

the signals at the destination chips are all going HIGH at the

same time as the input to the ZDB. In order to achieve this,

layout must compensate for trace length between the ZDB and

the target devices. The method of compensation is described

below.

External feedback is the trait that allows for this compensation.

Since the PLL on the ZDB will cause the feedback signal to be

in phase with the reference signal. When laying out the board,

match the trace lengths between the output being used for

feed back and the FBIN input to the PLL.

If it is desirable to either add a little delay, or slightly precede

the input signal, this may also be affected by either making the

trace to the FBIN pin a little shorter or a little longer than the

traces to the devices being clocked.

Inserting Other Devices in Feedback Path

Another nice feature available due to the external feedback is

the ability to synchronize signals up to the signal coming from

some other device. This implementation can be applied to any

device (ASIC, multiple output clock buffer/driver, etc.) which is

put into the feedback path.

Referring to Figure 2, if the traces between the ASIC/buffer

and the destination of the clock signal(s) (A) are equal in length

to the trace between the buffer and the FBIN pin, the signals

at the destination(s) device will be driven HIGH at the same

time the Reference clock provided to the ZDB goes HIGH.

Synchronizing the other outputs of the ZDB to the outputs form

the ASIC/Buffer is more complex however, as any propagation

delay in the ASIC/Buffer must be accounted for.

Reference

Signal

Feedback

Input

Zero

Delay

Buffer

ASIC/

Buffer

Figure 2. Six Output Buffers in the Feedback Path

Document #: 38-07230 Rev. *C

Page 3 of 6

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