Intel CHIPSET 820E User Manual

Intel

®

820E Chipset

R

Design Guide

143

A designer using components other than those listed previously must evaluate additional combinations of
driver and receiver.

Table 51. AGTL+ Parameters for Example Calculations

1,2

IC Parameters

Pentium

®

III

Processor Core at

133 MHz Bus

Intel

®

82820

MCH

Notes

Clock-to-output maximum (T

CO_MAX

) 2.7

3.6

4

Clock-to-output minimum (T

CO_MIN

) -0.1

0.5

4

Setup time (T

SU_MIN

) 1.2

2.27

3,4

Hold time (T

HOLD

) 0.8

0.28

4

NOTES:

1. All times in nanoseconds.
2. Numbers in table are for reference only. These timing parameters are subject to change. Please check the

appropriate component documentation for the valid timing parameter values.

3. T

SU_MIN

= 1.9 ns assumes the Intel 82820 MCH sees a minimum edge rate equal to 0.3 V/ns.

4. The Pentium III processor substrate’s nominal impedance is set to 65

Ω

± 15%. Future Pentium III processor

substrates may be set at 60

Ω

± 15%.

Table 51 lists the AGTL+ component timings of the processors and Intel

82820 MCH defined at the pins.

These timings are for reference only.

Table 52 gives an example AGTL+ initial maximum flight time and Table 53 contains an example
minimum flight time calculation for a 133 MHz, 2-way Pentium III processor/Intel 820E chipset system
bus. Note that assumed values for clock skew and clock jitter were used. Clock skew and clock jitter
values depend on the clock components and distribution method chosen for a particular design and must
be budgeted into the initial timing equations as appropriate for each design.

Intel highly recommends adding margin, as shown in the M

ADJ

column, to offset the degradation caused

by SSO push-out and other multi-bit switching effects. The Recommended T

FLT_MAX

column contains the

recommended maximum flight time after incorporating the M

ADJ

value. If the edge rate, ringback, and

monotonicity requirements are not met, flight time correction must first be performed as documented in
the Intel

®

Pentium

®

II Processor Developer’s Manual, with the additional requirements noted in Section

3.5. The commonly used “textbook” equations used to calculate the expected signal propagation rate of a
board are included in Section 3.2.

Simulation and control of baseboard design parameters can ensure that the signal quality and maximum
and minimum flight times are met. Baseboard propagation speed is highly dependent on the transmission
line geometry configuration (stripline vs. microstrip), dielectric constant, and loading. This layout
guideline includes high-speed baseboard design practices that may improve the amount of timing and
signal quality margin. The magnitude of M

ADJ

is highly dependent on the baseboard design

implementation (stack-up, decoupling, layout, routing, reference planes, etc.) and must be characterized
and budgeted appropriately for each design.