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5P49V5908 Datasheet, PDF (25/30 Pages) Integrated Device Technology – One reference LVCMOS output clock
PCI Express Application Note
PCI Express jitter analysis methodology models the system
response to reference clock jitter. The block diagram below
shows the most frequently used Common Clock Architecture
in which a copy of the reference clock is provided to both ends
of the PCI Express Link. In the jitter analysis, the transmit (Tx)
and receive (Rx) serdes PLLs are modeled as well as the
phase interpolator in the receiver. These transfer functions are
called H1, H2, and H3 respectively. The overall system
transfer function at the receiver is:
Hts = H3s  H1s – H2s
The jitter spectrum seen by the receiver is the result of
applying this system transfer function to the clock spectrum
X(s) and is:
Ys = Xs  H3s  H1s – H2s
In order to generate time domain jitter numbers, an inverse
Fourier Transform is performed on X(s)*H3(s) * [H1(s) -
H2(s)].
5P49V5908 DATASHEET
RMS. The two evaluation ranges for PCI Express Gen 2 are
10kHz – 1.5MHz (Low Band) and 1.5MHz – Nyquist (High
Band). The plots show the individual transfer functions as well
as the overall transfer function Ht.
PCIe Gen2A Magnitude of Transfer Function
PCI Express Common Clock Architecture
For PCI Express Gen 1, one transfer function is defined and the
evaluation is performed over the entire spectrum: DC to Nyquist (e.g
for a 100MHz reference clock: 0Hz – 50MHz) and the jitter result is
reported in peak-peak.
PCIe Gen2B Magnitude of Transfer Function
For PCI Express Gen 3, one transfer function is defined and
the evaluation is performed over the entire spectrum. The
transfer function parameters are different from Gen 1 and the
jitter result is reported in RMS.
PCIe Gen1 Magnitude of Transfer Function
For PCI Express Gen2, two transfer functions are defined with
2 evaluation ranges and the final jitter number is reported in
REVISION B 07/13/15
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