Figure 10, Table 9 – Texas Instruments TMS320TCI648x User Manual
Page 31
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SRIO Functional Description
The clock recovery algorithms listed in the CDR bits operate to adjust the clocks used to sample the
received message so that the data samples are taken midway between data transitions. The second order
algorithm can be optionally disabled, and both can be configured to optimize their dynamics. Both
algorithms use the same basic technique for determining whether the sampling clock is ideally placed, and
if not whether it needs to be moved earlier or later. When two contiguous data samples are different, the
phase sample between the two is examined. Eight data samples and nine phase samples are taken with
each result counted as a vote to move the sample point either earlier or later. These eight data bits
constitute the voting window. The eight votes are then counted, and an action to adjust the position of the
sampling clock occurs if there is a majority of early or late votes. The first order algorithm makes a single
phase adjustment per majority vote. The second order algorithm acts repeatedly according to the net
difference between early and late majority votes, thereby adjusting for the rate of change of phase.
Setting the ALIGN field to 01 enables alignment to the K28 comma symbols included in the 8b:10b data
encoding scheme defined by the IEEE and employed by numerous transmission standards. For systems
which cannot use comma based symbol alignment, the single bit alignment jog capability provides a
means to control the symbol realignment features of the receiver directly from logic implemented in the
ASIC core. This logic can be designed to support whatever alignment detection protocol is required.
The EQ bits allow for enabling and configuring the adaptive equalizer incorporated in all of the receive
channels, which can compensate for channel insertion loss by attenuating the low frequency components
with respect to the high frequency components of the signal, thereby reducing inter-symbol interference.
Above the zero frequency, the gain increases at 6dB/octave until it reaches the high frequency gain. When
enabled, the receiver equalization logic analyzes data patterns and transition times to determine whether
the low frequency gain of the equalizer should be increased or decreased. For the fully adaptive setting
(EQ = 0001), if the low frequency gain reaches the minimum value, the zero frequency is then reduced.
Likewise, if it reaches the maximum value, the zero frequency is then increased. This decision logic is
implemented as a voting algorithm with a relatively long analysis interval. The slow time constant that
results reduces the probability of incorrect decisions but allows the equalizer to compensate for the
relatively stable response of the channel.
•
No adaptive equalization. The equalizer provides a flat response at the maximum gain. This setting
may be appropriate if jitter at the receiver occurs predominantly as a result of crosstalk rather than
frequency dependent loss.
•
Fully adaptive equalization. Both the low frequency gain and zero position of the equalizer are
determined algorithmically by analysing the data patterns and transition positions in the received data.
This setting should be used for most applications.
•
Partially adaptive equalisation. The low frequency gain of the equalizer is determined algorithmically by
analysing the data patterns and transition positions in the received data. The zero position is fixed in
one of eight zero positions. For any given application, the optimal setting is a function of the loss
characteristics of the channel and the spectral density of the signal as well as the data rate, which
means it is not possible to identify the best setting by data rate alone, although generally speaking, the
lower the line rate, the lower the zero frequency that will be required.
Figure 10. SERDES Receive Channel Configuration Register n (SERDES_CFGRXn_CNTL)
31
26 25
24
23
22
19 18
16
Reserved
Reserved
—
EQ
CDR
(write 0s)
R-0
R/W-0
R-0
R/W-0
R/W-0
15
14 13
12
11
10
8
7
6
5 4
2
1
0
TERM
—
LOS
ALIGN
—
INVPAIR
RATE
BUSWIDTH
ENRX
(write 001b)
(write 0)
R/W-0
R/W-0
R-0
R/W-0
R/W-0
R/W-0
R/W-0
R/W-0
R/W-0
LEGEND: R/W = Read/Write; R = Read only; -n = Value after reset
Table 9. SERDES Receive Channel Configuration Register n (SERDES_CFGRXn_CNTL) Field
Descriptions
Bit
Field
Value
Description
31–26
Reserved
000000b
These read-only bits return 0s when read.
SPRUE13A – September 2006
Serial RapidIO (SRIO)
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