English
Language : 

TLK3134_1 Datasheet, PDF (39/150 Pages) Texas Instruments – 4-Channel Multi-Rate Transceiver
www.ti.com
TLK3134
4-Channel Multi-Rate Transceiver
SLLS838D – MAY 2007 – REVISED JULY 2008
ACQ3
During this state the comma detect circuit is active but code word re-alignment is disabled.
The TLK3134 will remain in this state until either a comma is detected or a decode error
encountered. While in this state, the Lane Sync bit for the particular channel will remain
de-asserted indicating the lane is not synchronized.(1) A decode or running disparity error will
return the channel state to UNSYNC. A detected comma will cause the channel state to
transition to SYNC.
SYNC
This is the normal state for receiving data. When in this state, the TLK3134 will set the Lane
Sync bit to '1' for the particular channel in the MDIO register bits 4/5.24.3:0 indicating the
lane has been synchronized. During this state the comma detect circuit is active but code
word re-alignment is disabled. A decode or running disparity error will cause the channel
state to transition to MISS1.
MISS1
When entering this state an internal error counter is cleared. If the next four consecutive
codes are decoded without error, the channel state reverts back to SYNC. If a decode or
running disparity error is detected, the channel state will transition to MISS2.
MISS2
When entering this state an internal error counter is cleared. If the next four consecutive
codes are decoded without error, the channel state reverts back to MISS1. If a decode or
running disparity error is detected, the channel state will transition to MISS3.
MISS3
When entering this state an internal error counter is cleared. If the next four consecutive
codes are decoded without error, the channel state reverts back to MISS2. If a decode or
running disparity error is detected, the channel state will transition to UNSYNC.
2.7.21 End of Packet Error Detection
Because of their unique data patterns, /A/ (K28.3), /K/ (K28.5), and /T/ (K29.7) will catch running disparity
errors that may have propagated undetected from previous codes in a packet. Running disparity errors
detected by these control codes at the end of packets will cause the previous data codes to be reported
as errors (0xFE) to allow the protocol device to reject the packet (see Figure 2-23).
XAUI
RDP/N0 ... D D D D A
Running Disparity Error
Detected by /A/ Yields
RDP/N1 ... D D D T A
Running Disparity Error
Detected by /T/ Yields
RDP/N2 ... D D D K A
Running Disparity Error
Detected by /K/ Yields
RDP/N3 ... D D D K A
Running Disparity Error
Detected by /K/ Yields
D = Data, T = K29.7, A = K28.3, K = K28.5, E = Error (0xFE), I = Idle
XGMII
... D D D E I
... D D E T I
... D D E I I
... D D E I I
Figure 2-23. End of Packet Error Detection
2.7.22 Fault Detection and Reporting
The TLK3134 will detect and report local faults as well as forward both local and remote faults as defined
in the IEEE 802.3ae 10Gbps Ethernet Standard to aid in fault diagnosis. All faults detected by the
TLK3134 are reported as local faults to the upper layer protocols. Once a local fault is detected in the
TLK3134, MDIO register bit 4/5.1.7 is set. Fault sequences, sequence ordered sets received by the
TLK3134, either on the Transmit Data Bus or on the high speed receiver pins, are forwarded without
change to the MDIO registers in the TLK3134. Also, note that the TLK3134 is capable of performing CTC
operation where only RF and LF or any Q sequences are transported (not generated) in either the transmit
or receive direction in XAUI mode.
Submit Documentation Feedback
Detailed Description
39