HCPL9000 Datasheet, PDF(11/12 Page) Agilent(Hewlett-Packard) – High Speed Digital Isolators

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HCPL9000 Datasheet, PDF (11/12 Pages) Agilent(Hewlett-Packard) – High Speed Digital Isolators

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Propagation Delay, Pulse Width

Distortion and Propagation Delay Skew

Propagation Delay is a figure of

merit, which describes how

quickly a logic signal propagates

through a system as illustrated in

Figure 3.

The propagation delay from low to

high, tPLH, is the amount of time

required for an input signal to

propagate to the output, causing

the output to change from low to

high. Similarly, the propagation

delay from high to low, tPHL, is the

amount of time required for the

input signal to propagate to the

output, causing the output to

change from high to low.

Pulse Width Distortion, PWD, is

the difference between tPHL and

tPLH and often determines the

maximum data rate capability of

a transmission system. PWD can

be expressed in percent by

dividing the PWD (in ns) by the

minimum pulse width (in ns)

being transmitted. Typically, PWD

on the order of 20 â 30% of the

minimum pulse width is tolerable.

Propagation Delay Skew, tPSK,

and Channel-to-Channel Skew,

tCSK, are critical parameters to

consider in parallel data trans-

mission applications where

synchronization of signals on

parallel data lines is a concern.

INPUT

VIN

OUTPUT

VOUT

tPLH

90%

10%

50%

tPHL

90%

10%

Figure 3. Timing Diagrams to Illustrate Propagation Delay, t and t .

PLH

PHL

5 V CMOS

0V

VOH

2.5 V CMOS

VOL

VIN

VOUT

VIN

VOUT

50%

2.5 V

CMOS

tPSK

50%

DATA

INPUTS

CLOCK

2.5 V

CMOS

DATA

OUTPUTS

CLOCK

tPSK

tPSK

Figure 5. Parallel Data Transmission.

Figure 4. Timing Diagrams to Illustrate

Propagation Delay Skew.

If the parallel data is being sent

through channels of the digital

isolators, differences in propaga-

tion delays will cause the data to

arrive at the outputs of the

digital isolators at different

times. If this difference in

propagation delay is large

enough, it will limit the maxi-

mum transmission rate at which

parallel data can be sent through

the digital isolators.

tPSK is defined as the difference

between the minimum and

maximum propagation delays,

either tPLH or tPHL, among two or

more devices which are operating

under the same conditions (i.e.,

the same drive current, supply

voltage, output load, and operat-

ing temperature). tCSK is defined

as the difference between the

minimum and maximum propaga-

tion delays, either tPLH or tPHL,

among two or more channels

within a single device (applicable

to dual and quad channel de-

vices) which are operating under

the same conditions.

As illustrated in Figure 4, if the

inputs of two or more devices are

switched either ON or OFF at the

same time, tPSK is the difference

between the minimum propaga-

tion delay, either tPLH or tPHL, and

the maximum propagation delay,

either tPLH or tPHL.

As mentioned earlier, tPSK, can

determine the maximum parallel

data transmission rate. Figure 5

shows the timing diagram of a

typical parallel data transmission

application with both the clock

and data lines being sent through

the digital isolators. The figure

shows data and clock signals at

the inputs and outputs of the

digital isolators. In this case, the

data is clocked off the rising edge

of the clock.

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