AM7969-175JC AMD (ADVANCED MICRO DEVICES), AM7969-175JC Datasheet - Page 69

AM7969-175JC

Manufacturer Part Number

AM7969-175JC

Description

Manufacturer

AMD (ADVANCED MICRO DEVICES)

Datasheet

1.AM7969-175JC.pdf (127 pages)

Specifications of AM7969-175JC

Operating Supply Voltage (typ)

Operating Supply Voltage (min)

4.5V

Operating Supply Voltage (max)

5.5V

Operating Temp Range

0C to 70C

Operating Temperature Classification

Commercial

Package Type

PLCC

Mounting

Surface Mount

Pin Count

Lead Free Status / Rohs Status

Not Compliant

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Figure 5-5

as baseline wander effect and is illustrated in Figure 5-5. In Figure 5-5a, the average DC

fluctuates between 40% and 60% of the maximum level (+10% of midpoint). After the

signal is capacitively coupled (Figure 5-5b), the average DC component is lost due to

high-pass filtering, causing an undesired shift in the signal levels. This shift in the signal

levels, coupled with non-zero rise and fall times of the serial stream cause pulse width

distortion and thus apparent jitter and possible increased error rates.

This DC shifting effect can be minimized if the values of the AC coupling components

are chosen appropriately. The DC level of the data will fluctuate at a data-dependent

frequency, f

AC coupling, f

frequency of the data. This allows most DC variations to pass through the AC coupling

high-pass filtering, minimizing the DC shift in the signal.

To minimize f

either by the termination required by the transmission line or by biasing requirements on

both sides of the link. Hence, only the coupling capacitor C can be maximized to keep

that it must be an RF capacitor. RF capacitors are generally of the ceramic type (NPO

and X7R dielectrics) and are limited to a maximum value of approximately 1.0 F.

0.1 F capacitors have proven to be sufficient in laboratory tests of TAXIchip set

systems.

For a 0.1 F capacitor, we must verify that the capacitive reactance at the lowest

fundamental frequency possible is less than 1 . The lowest fundamental frequency

possible is the frequency that results when the TAXIchip set is running at it’s lowest

BAUD rate (40 Mbaud) and the command or data pattern with the least number of

transitions is being sent. This pattern turns out to be the HQ command (FDDI terminol-

ogy) which has only 1 transition per command, or 1 transition per 10 bits when the

command is encoded. If a continuous stream of HQ commands are sent at 40 Mbaud,

the resultant fundamental frequency of the signal is 2 MHz. At 2 MHz, the capacitive

reactance of a 0.1 F capacitor is calculated as follows:

Hence, in the worst case a 0.1 F capacitor will give a reactance of less than 1

desired.

In summary, the largest value RF capacitor available should be used to optimize the

performance of the TAXlchip link.

Baseline Wander

3dB

a) Data Before AC Coupling

b) Data After AC Coupling

as low as possible. The largest value capacitor that can be used is limited by the fact

, called the baseline wander frequency. The 3 dB corner frequency of the

3dB

XC =

3dB

TAXIchip Integrated Circuits Technical Manual

=1/(2 RC), should be chosen below the minimum baseline wander

we must maximize R and C. The resistance R is generally determined

2 fC

2 (2*10

) (0.1*10

-6

)

0.8

Average DC Level Varies

with Data Pattern

Varying DC is Filtered Out

Causing an Undesired DC

Shift in the Data

12330E-12

AMD

, as

AM7969-175JC AMD (ADVANCED MICRO DEVICES), AM7969-175JC Datasheet - Page 69

AM7969-175JC

Specifications of AM7969-175JC

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