DS89C387TMEA National Semiconductor, DS89C387TMEA Datasheet - Page 6

DS89C387TMEA

Manufacturer Part Number

DS89C387TMEA

Description

RS422/485 Line Driver IC

Manufacturer

National Semiconductor

Datasheets

1.DS89C387TMEAX.pdf (12 pages)

2.DS89C387TMEA.pdf (10 pages)

3.DS89C387TMEA.pdf (10 pages)

Specifications of DS89C387TMEA

Device Type

Line

No. Of Drivers

Driver Case Style

SSOP

No. Of Pins

Mounting Type

Surface Mount

No. Of Driver/receivers

12/0

Peak Reflow Compatible (260 C)

Supply Voltage

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Application Information

In Figure 2 , VX, where X is a number, is the waveform volt-

age level at which the propagation delay measurement ei-

ther starts or stops. Furthermore, V1 and V2 are normally

identical. The same is true for V3 and V4. However, as men-

tioned before, these levels are not standardized and may

vary, even with similar devices from other companies. Also

note, NC (no connection) in Figure 1 means the pin is not

used in propagation delay measurement for the correspond-

ing circuit.

The single-ended skew provides information about the pulse

width distortion of the output waveform. The lower the skew,

the less the output waveform will be distorted. For best case,

skew would be zero, and the output duty cycle would be

50%, assuming the input has a 50% duty cycle.

For differential propagation delays, V1 should equal V2. Fur-

thermore, the crossing point of DO and DO

zero volts on the differential waveform (see bottom wave-

form in Figure 9 ). This is true whether V3 equals V4 or not.

FIGURE 8. Circuit for Measuring Differential

FIGURE 9. Propagation Delay Waveforms

Propagation Delays (See Figure 9 )

for Circuit 3 (See Figure 8 )

Waveforms for Circuit 1

Waveforms for Circuit 3

FIGURE 7. Propagation Delay Waveforms for Circuit 1 and Circuit 2 (See Figure 6 )

(Circuit 3)

DS012086-13

(Continued)

corresponds to

DS012086-11

DS012086-14

However, if V3 and V4 are specified voltages, then V3 and

V4 are less likely to be equal to the crossing point voltage.

Thus, the differential propagation delays will not be mea-

sured to zero volts on the differential waveform.

The differential skew also provides information about the

pulse width distortion of the differential output waveform rela-

tive to the input waveform. The higher the skew, the greater

the distortion of the differential output waveform. Assuming

the input has a 50% duty cycle, the differential output will

have a 50% duty cycle if skew equals zero and less than a

50% duty cycle if skew is greater than zero.

Complementary skew is calculated from single-ended propa-

gation delay measurements on complementary output sig-

nals, DO and DO

ues, they are identical on DO and DO

they are relative values.

The complementary skew reveals information about the con-

tour of the rising and falling edge of the differential output

FIGURE 11. Waveforms for Circuit 4 (See Figure 10 )

FIGURE 10. Circuit for Measuring Complementary

Waveforms for Circuit 2

Waveforms for Circuit 4

. Note, when V3 and V4 are absolute val-

Skew (See Figure 11 )

(Circuit 4)

DS012086-15

; but vary whenever

DS012086-12

DS012086-16

DS89C387TMEA National Semiconductor, DS89C387TMEA Datasheet - Page 6

DS89C387TMEA

Specifications of DS89C387TMEA

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