ETC PM5365?

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PM5365
02
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TEMAP
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TEMAP
Errata
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VT/TU Mapper and M13 Multiplexer
Proprietary and Confidential
Released
Issue 3: August, 2002
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
PM
TEMAP Production Release Errata
Released
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Legal Information
:43
Copyright
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© 2002 PMC-Sierra, Inc.
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The information is proprietary and confidential to PMC-Sierra, Inc., and for its customers’
internal use. In any event, you cannot reproduce any part of this document, in any form, without
the express written consent of PMC-Sierra, Inc.
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PMC-2001480 (R3)
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Disclaimer
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None of the information contained in this document constitutes an express or implied warranty by
PMC-Sierra, Inc. as to the sufficiency, fitness or suitability for a particular purpose of any such
information or the fitness, or suitability for a particular purpose, merchantability, performance,
compatibility with other parts or systems, of any of the products of PMC-Sierra, Inc., or any
portion thereof, referred to in this document. PMC-Sierra, Inc. expressly disclaims all
representations and warranties of any kind regarding the contents or use of the information,
including, but not limited to, express and implied warranties of accuracy, completeness,
merchantability, fitness for a particular use, or non-infringement.
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In no event will PMC-Sierra, Inc. be liable for any direct, indirect, special, incidental or
consequential damages, including, but not limited to, lost profits, lost business or lost data
resulting from any use of or reliance upon the information, whether or not PMC-Sierra, Inc. has
been advised of the possibility of such damage.
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Trademarks
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TEMAP, SBI, and PMC-Sierra are trademarks of PMC-Sierra, Inc.
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Patents
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The technology discussed is protected by one or more Patents. Relevant patent applications and
other patents may also exist.
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
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Contacting PMC-Sierra
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PMC-Sierra
8555 Baxter Place Burnaby, BC
Canada V5A 4V7
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Tel: +1.604.415.6000
Fax: +1.604.415.6204
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Document Information: [email protected]
Corporate Information: [email protected]
Technical Support: [email protected]
Web Site: http://www.pmc-sierra.com
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Revision History
Issue Date
Details of Change
3
August 2002
Notification of additional information and errors to TEMAP Data Sheet
Issue R3, TEMAP Register Description R2 and TEMAP Programmer’s
Reference Guide R3.
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Issue No.
Added items 2.2 to 2.5, 3.7 to 3.20.
October 1, 2001
Updated to reflect new PM5365 TEMAP Datasheet issued August 2001
(PMC-1991148 r3) and the PM5365 TEMAP Register Description issued
July 2001 (PMC-1990682 r2).
1
July 12, 2001
This document is a notice of additional information and error corrections
to be inserted into the PM5365 TEMAP Datasheet, document number
PMC01991148, Issued February 2000 and the PM5365 TEMAP Register
Description, document number PMC-1990682, Issued March 2000.
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Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
3
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TEMAP Production Release Errata
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Table of Contents
:43
Legal Information ................................................................................................................ 2
Contacting PMC-Sierra ....................................................................................................... 3
02
Device Identification............................................................................................ 6
1.2
References ......................................................................................................... 6
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1.1
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Device Functional Deficiency List ............................................................................... 7
VT-AIS Tributary Corruption................................................................................ 7
2.2
DS3 PRGD block limits useable repeating patterns in unchannelized M23 mode
............................................................................................................................ 7
Workaround............................................................................................ 8
2.2.3
Performance with Workaround .............................................................. 8
2.2.4
Performance without Workaround ......................................................... 9
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Description ............................................................................................. 9
2.3.2
Workaround............................................................................................ 9
2.3.3
Performance with Workaround .............................................................. 9
2.3.4
Performance without Workaround ......................................................... 9
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2.3.1
Incorrect Link Rate Octet generated when demapping DS3 from SONET ...... 10
2.4.1
Description ........................................................................................... 10
2.4.2
Workaround.......................................................................................... 10
2.4.3
Performance with Workaround ............................................................ 10
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Performance without Workaround ....................................................... 10
TEMAP Not Recommended for E1 Applications Requiring G.783 Jitter Compliance
.......................................................................................................................... 10
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Demapping DS3 when CLK52M = 51.84 MHz is not recommended ................. 9
2.4.4
2.5
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2.2.2
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Description ............................................................................................. 7
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2.2.1
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Introduction.................................................................................................................. 6
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Table of Contents ................................................................................................................ 4
Documentation Deficiency List .................................................................................. 12
3.1
Duplication of Ground Pin Descriptions............................................................ 12
3.2
Connecting to the Telecom ADD bus via an External MUX.............................. 12
3.3
Telecom ADD Bus Parity Generation................................................................ 12
3.4
Telecom DROP Bus Parity Detection ............................................................... 12
3.5
AIS Insertion in DS3 Diagnostic Loopback....................................................... 13
3.6
Path Signal Label Mismatch State.................................................................... 13
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
Released
Transmultiplexing Mode Clarification................................................................ 14
3.8
CENT bit description of TJAT and RJAT Configuration registers are incorrect 15
3.9
M13 TJAT and RJAT settings incorrect in Programmer’s Guide ...................... 15
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3.7
3.10 IILPU max spec limit has been revised ............................................................ 15
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3.11 Tolerance of TICLK not stated in pin description .............................................. 16
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3.12 CLK52M Clarification ........................................................................................ 16
20
3.13 Recommended RTDM Leak Rate incorrect...................................................... 16
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3.14 Behavior of FIFO status handling needs clarification ....................................... 16
3.15 RJAT SYNC bit description in EXSBI CLK_MODE field clarified ..................... 17
3.16 Miscellaneous Pins Incorrect............................................................................ 17
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3.17 Missing Diagrams ............................................................................................. 18
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3.18 Revision ID Bits Section clarification. ............................................................... 23
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3.19 Byte Deletion/Insertion in VT/TU Mapping Mode ............................................. 23
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Notes ................................................................................................................................. 24
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
5
Introduction
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TEMAP Production Release Errata
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In this document:
Section 2 lists the known functional errata for the Production Released Version of the
PM5365 TEMAP.
·
Section 3 lists documentation errors found in the PM5365 TEMAP Datasheet issued August
2001 (PMC-1991148, Issue 3) and the PM5365 TEMAP Register Description issued July
2001 (PMC-1990682, Issue 2).
Device Identification
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The information contained in Section 2 relates to the Production Released version of the PM5365
TEMAP device only. This version is identified by the letter E at the end of the wafer batch code,
which is the device revision code, and the designation –PI at the end of the part number instead of
the designation –PI-P.
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Register 0002H: Revision/Global PMON Update identifies the Production Release revision of the
PM5365 TEMAP using ID[3:0]=0101.
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Note: This errata only applies to issues specific to the production released PM5365-PI TEMAP
device. It does not apply to any of the prototype TEMAP devices.
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Figure 1 PM5365 Branding Diagram
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Ball A1
Index Marks
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Country of
Origin
1.2
PMC Logo
TEMAP Logo
TM
TEMAP
PM5365-PI
C
E
Myyww
Philippines
Part Number
Wafer Batch Code
Assembly Date Code
References
·
·
Issue 3 of the PM5365 TEMAP Datasheet (PMC-1991148).
Issue 2 of the PM5365 TEMAP Register Description (PMC-1990682).
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
6
Device Functional Deficiency List
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TEMAP Production Release Errata
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This section lists the known functional deficiencies for the Production Released version of the
PM5365 TEMAP as of the publication date of this document.
VT-AIS Tributary Corruption
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Please report any functional deficiencies not covered in this errata to PMC-Sierra.
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An issue in the TEMUX demapper results in the VT-AIS causing corruption to the previous
tributary of SPE#3 only.
DS3 PRGD block limits useable repeating patterns in
unchannelized M23 mode
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2.2
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To circumvent this issue, apply the software workaround outlined in Section 16 of the
Programmer’s Reference Guide (PMC-1991268).
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2.2.1 Description
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84 bits
84 bits
84 bits
84 bits
F2
C2
F3
C3
F4
C1
F2
C2
F3
C3
F4
C1
C1
F2
C2
F3
C3
F4
F1
C1
F2
C2
F3
C3
F4
F1
C1
F2
C2
F3
C3
F4
F1
C1
F2
C2
F3
C3
F4
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F1
F2
C2
F3
C3
F4
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M-subframe 7 M3
84 bits
C1
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M-subframe 4 P 2
M-subframe 5 M1
M-subframe 6 M2
84 bits
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M-subframe 1 X 1
M-subframe 2 X 2
M-subframe 3 P 1
84 bits
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84 bits
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As described in the TEMAP Data Sheet, Section 12.1: DS3 Framing Format, the TEMAP device
provides support for both the C-bit parity and M23 DS3 framing formats. The DS3 frame format
is shown in Figure 17 of the Data Sheet (copied below):
The C-bit Parity ID bit is the first C-bit (C1) of the M-subframe 1. In the receive direction, the
CBITV register bit in the DS3 FRMR Status register is used to report the state of this C-bit Parity
ID. If the ID bit is 1, the DS3 frame received is assumed to be C-bit parity. If the C-bit Parity ID
is 0 or toggling, the DS3 signal stream received is assumed to be M23.
Unchannelized repeating patterns are regenerated each time the PRGD Pattern Insertion Register
#4 is written to (Register 103BH). In M23 mode, the DS3 PRGD always sets all C-bits to the
same value based on the last transmitted bit. For an all-1’s pattern, all C-bits will be 1. Similarly
for an all-0’s pattern, all C-bits will be 0. For an alternating 10101010 pattern for instance, there
is a 50/50 chance of all C-bits being 1.
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
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An issue arises when attempting to generate an unchannelized all-1’s M23 pattern. Recall that an
M23 signal stream requires the C-bit Parity ID to be 0 or toggling. However, the DS3 PRGD will
set all C-bits (and hence the C-Bit Parity ID) to 1 when generating an all-1’s pattern. The
receiver will therefore interpret the DS3 frame to be C-bit parity rather than the correct M23
format. As a result, a frame mismatch is declared if an all-1’s is generated in M23 mode.
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Similarly, an alternating 10101010 M23 pattern has a 50/50 chance of being misinterpreted as a
C-bit parity DS3 stream while in unchannelized DS3. For patterns containing one or more 0’s,
the occurrence of this problem is related to the 1’s density of the pattern. An example is a 31ones, 1-zero pattern in M23 mode. On average, this pattern will work without frame mismatch
one every 32 tries, as there is a 1/32 chance of C-bit parity ID being 0.
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In C-bit parity mode, there are no problems passing all-1’s because the ID bit is always
overwritten with a 1.
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2.2.2 Workaround
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There is no way to generate an all-1s pattern while in unchannelized M23 mode without seeing
frame mismatch errors. Because the DS3 PRGD block limitation applies to unchannelized DS3
only, utilizing C-bit parity mode (instead of M23) allows the generation of an all-1’s pattern.
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In the event that unchannelized M23 mode must be used, several other patterns can be used
without declaring DS3 frame mismatch. For patterns containing one or more 0’s, the occurrence
of this mistaken M23 signal for C-bit parity is related to the 1’s density of the pattern.
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The following algorithm can be used to generate patterns other than all-1’s in M23 mode:
Write to PRGD Pattern Insertion Register #4 (Register 103BH) to generate unchannelized
repeating patterns.
·
At the receiver, check the framer for a DS3 frame mismatch. If using a loopback or
another TEMAP, the DS3 framing circuitry of the TEMAP reports the frame mismatch
using DS3 FRMR status bit CBITV.
·
If frame mismatch has occurred, repeat. Else, transmitted pattern is correct.
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An all-0’s pattern can always be transmitted correctly while the TEMAP is in unchannelized M23
mode.
2.2.3 Performance with Workaround
There is no workaround to implement the generation of an all-1s pattern while in unchannelized
M23 mode. Using C-bit parity DS3 framing format is recommended to generate all-1’s.
The TEMAP device will operate normally in DS3 testing scenarios with the suggested
workaround in place for M23 mode.
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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2.2.4 Performance without Workaround
Demapping DS3 when CLK52M = 51.84 MHz is not recommended
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2.3
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DS3 Frame Mismatch will be declared when attempting to generate all-1’s pattern in
unchannelized M23 mode.
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TEMAP Production Release Errata
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2.3.1 Description
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In the TEMAP Data Sheet, there is a choice between two clock frequencies for CLK52M input
(Pin P3):
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" The 52 MHz clock reference is used to generate a gapped DS3 clock when demapping a
DS3 from the SONET stream and also to generate a gapped DS3 clock when receiving a
DS3 from the SBI bus interface. This clock has two nominal values.
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The first is a nominal 51.84 MHz 50% duty cycle clock. The second is a nominal 44.928
MHz 50% duty cycle clock.
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When this clock is not used this input must be connected to ground."
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Repetitive data corruption with demapped DS3 may occur in systems using the 51.84 MHz clock.
It has been confirmed that this is not an issue if the alternate clock frequency, 44.928 MHz, is
used.
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When 51.84 MHz is synchronized to LREFCLK, errors still occur as long as the incoming DS3
ppm offset is greater than the relative offset of the 51.84 MHz. The data corruption is
theoretically possible with or without incoming STS level pointer movements. At this time
however, no errors have been observed in the absence of STS level pointer movements. Also,
standard test equipment used as the mapped DS3 source has yet to produce the error condition.
Only a TEMAP device mapping the DS3 causes the errors.
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2.3.2 Workaround
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When configured to demap DS3 payloads from SONET STS1/SDH AU3, the CLK52M input at
44.928 MHz would avoid this possible data corruption to the DS3 stream. Thus, the
FASTCLKFREQ bit of Register 1209H must be cleared to logic 0. Using the 44.928 MHz clock
has always been a fully supported mode of the TEMAP.
2.3.3 Performance with Workaround
If the 44.928 MHz clock frequency is used for CLK52M while demapping DS3s from SONET
STS1/SDH AU3, the risk of data corruption in this mode no longer exists. PMC-Sierra highly
recommends using this clock frequency when demapping DS3s in new TEMAP designs.
2.3.4 Performance without Workaround
When demapping DS3s from SONET/SDH payloads, if the CLK52M input is set to 51.84 MHz,
there is a risk of data corruption. PMC-Sierra highly recommends using 44.928 MHz crystals for
new designs.
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TEMAP Production Release Errata
Released
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Incorrect Link Rate Octet generated when demapping DS3 from
SONET
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2.4
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2.4.1 Description
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When the TEMAP device is in DS3 framer-only mode, the linkrate clock rate field over the SBI
bus tolerates approximately 4 UI of jitter in a 500uS (2kHz) period. When demapping a DS3
from SONET, gapping the CLK52M reference clock generates the serial DS3 clock. The gapping
procedure utilizes FIFO depth to control the gapping algorithm.
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The gapping algorithm used by the DS3 demapper exceeds the jitter tolerance of the SBI linkrate.
Data taken by the link layer SBI devices via their EXSBI FIFO is derived from these faulty
linkrate values. These values no longer match the actual data rate. With the clock rate octet
enabled in layer 2 SBI devices, the DS3 clock could only be varied by a few ppm before the
EXSBI FIFO underflows or overflows. As a result, data corruption can occur.
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Therefore, when demapping DS3s from SONET in the TEMAP, the layer 2 SBI devices cannot
rely upon link rate octet to regenerate clocking. Rather, the DS3 serial clocks need to be routed
around the SBI bus.
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2.4.2 Workaround
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In data applications involving FREEDM packet processing and IMA ATM, the FIFO method is
used to pass data across the SBI bus when demapping DS3 from SONET. Hence, an incorrect
link rate octet does not affect these applications.
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However, for AAL1 circuit emulation (CES) applications that demap DS3 from SONET, the
serial DS3 clocks (generated by gapping CLK52M) need to be routed around the SBI bus. This is
normally done for serial DS3 but in addition, a DS3 JAT is required for demapping applications.
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Refer to PMC-1990887 “AAL1gator-32 CES Reference Design”, Issue 5 for details.
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2.4.3 Performance with Workaround
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If the serial DS3 clocks are routed around the SBI bus in DS3 demapping CES applications, there
will be no excess jitter introduced.
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2.4.4 Performance without Workaround
Data corruption may occur when demapping DS3s from SONET in AAL1 circuit emulation.
2.5
TEMAP Not Recommended for E1 Applications Requiring G.783
Jitter Compliance
TEMAP does not meet G.783 Jitter specification for demapping E1 from SDH in the presence of
pointer movements. Specification allows 0.4 UIpp jitter between 20 Hz and 100 kHz and 0.075
UIpp between 18 kHz and 100 kHz.
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
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Preliminary testing has shown that values greater than 0.4 UI pp and 0.075 UI pp can be
measured for their respective frequency bands when using either the PM4314 QDSX connected
to the TEMAP’s clock and data interface or the PM4318 OCTLIU connected to the TEMAP’s
SBI bus.
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At no time are there any data corruption issues.
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If customer designs require these specifications to be met, consideration should be given to
migrating these designs to PMC-Sierra’s PM5366, TEMAP-84.
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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Documentation Deficiency List
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3
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TEMAP Production Release Errata
Released
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This section of the document is a notification of additional information and known documentation
deficiencies for Issue 3 of the PM5365 TEMAP Datasheet and Issue 2 of the PM5365 TEMAP
Register Description, as of the publication date of this document.
Duplication of Ground Pin Descriptions
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Please report any documentation deficiencies not covered in this errata to PMC-Sierra.
Connecting to the Telecom ADD bus via an External MUX
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The description of ground pins N3, Y12, L20 and B12 has been duplicated in two rows of the pin
description section, pins VSSQ[1:4] and VSS3.3[19:22]. These pins should only be described in
the VSS3.3 row. The VSSQ row should be eliminated. In any event these pins should be
connected to GND as described.
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Telecom ADD Bus Parity Generation
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3.3
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The pin description for LAC1J1V1 may need clarification. When connecting the TEMAP to the
TelecomBus via an external MUX (instead of simply tri-stating the bus), the LAC1J1V1 signal
should not be muxed. This means that when there are three TEMAPs connected to a Spectra’s
TelecomBus through the MUX, the LAC1J1V1 signal from only one of the three TEMAPs should
be connected to the SPECTRA. The other two LAC1J1V1 signals should remain unconnected.
All TEMAPs must have the LOCK0 bit in registers 1202H and 15E5H set the same.
Telecom DROP Bus Parity Detection
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The TEMAP device cannot generate parity on the Telecom ADD bus when LAC1J1V1 is set to
participate in the egress parity generation. Parity generation only helps check integrity of the bus
connections and has no effect on the data path or with control of the device. If egress parity
needs to be generated, LAC1J1V1 should not be used.
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The TEMAP device can correctly detect parity on the Telecom DROP bus when LDC1J1V1 is set
to participate in the ingress parity detection. The Register Description documentation is
erroneously missing this optionally selectable feature.
Accordingly, Register 1201H of the Register Description document should be amended as
follows:
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
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PM
TEMAP Production Release Errata
Released
Type
Function
Default
Bit 7
R/W
LDPE
0
Bit 6
R/W
ITMFEN
0
Bit 5
R/W
IVTPPBYP
0
Bit 4
R/W
ITSEN
0
Bit 3
R/W
INCLDPL
0
Bit 2
R/W
INCLDC1J1V1
0
LDOP
0
R/W
ICONCAT
0
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R/W
Bit 0
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Bit 1
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Bit
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Register 1201H: SONET/SDH Master Ingress Configuration
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INCLDC1J1V1:
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AIS Insertion in DS3 Diagnostic Loopback
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The INCLDC1J1V1 bit controls whether the LDC1J1V1 input signal participates in the
incoming parity calculations. When INCLDC1J1V1 is set high, the parity signal set includes
the LDC1J1V1 input. When INCLDC1J1V1 is set low, parity is calculated without regard to
the state of LDC1J1V1. Selection of odd or even parity is controlled by the LDOP bit.
Path Signal Label Mismatch State
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In the datasheet, Figure 25: DS3 Diagnostic Loopback Diagram states that AIS can optionally be
inserted into the transmit datapath when a DS3 is in diagnostic loopback. This is incorrect. AIS
cannot be inserted in the transmit path when in DS3 diagnostic loopback mode.
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In the datasheet, Table 2: Path Signal Label Mismatch State is incorrect. It incorrectly references
PDI code.
- Path Signal Label Mismatch State
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Table 2
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The table should read as follows:
Accepted PSL
PSLM State
000
000
MATCH
000
001
MISMATCH
000
XXX ¹ 000
MISMATCH
001
000
MISMATCH
001
001
MATCH
001
XXX ¹ 001
MATCH
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Expected PSL
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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Accepted PSL
PSLM State
XXX ¹ 000, 001
000
MISMATCH
XXX ¹ 000, 001
001
MATCH
XXX ¹ 000, 001
XXX
MATCH
XXX ¹ 000, 001
YYY
MISMATCH
Transmultiplexing Mode Clarification
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Expected PSL
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TEMAP Production Release Errata
Released
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Transmultiplexing mode (“transmux”) is not adequately described in the current TEMAP
datasheet. This mode enables the exchange of 1.544 Mbps tributaries between SONET/SDH
TelecomBus and DS3 line interface.
ay
,1
The following excerpt should be added to Section 9: Functional Description:
io
nT
hu
rsd
Transmultiplexing (“transmux”) is the operating mode that enables 1.544 Mbps clearchannel tributaries to be exchanged between the SONET/SDH Telecom Bus and the DS3
line interface. It is enabled by setting the TEMAP Configuration register’s
OPMODE[1:0] bits to 10 and its LINEOPT [1:0] bits to 00. The system interface is
unused in this mode.
uo
fo
liv
ett
The TEMAP will receive a channelized DS3 stream from the serial DS3 interface. It will
frame up to the DS3 and de-multiplex the individual 1.544 Mbps tributaries. The
tributaries are jitter attenuated, bit asynchronously mapped into VT1.5/TU11s and
presented on the Telecom Add bus.
yV
inv
ef
In the reverse direction, VT1.5/TU11s are bit asynchronously de-mapped from the
Telecom Drop bus. The 1.544 Mbps tributaries are jitter attenuated and multiplexed into
a DS3, which is presented on the serial DS3 interface.
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Performance monitoring of T1 framing status and errors can be performed on the
tributaries. On a per-tributary basis, the TXPMON context bit programmed through
Register 000H+80H*N: T1/E1 Master Configuration register selects either the
SONET/SDH mapper transmit or DS3 transmit T1 tributary for performance monitoring.
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Document ID: PMC-2001480, Issue 3
14
CENT bit description of TJAT and RJAT Configuration registers
are incorrect
:43
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TEMAP Production Release Errata
Released
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The following text should be ignored from the CENT bit description of the T1/E1 TJAT and
RJAT Configuration Registers, Register 0017H + 80H*N and Register 0013H + 80H*N
respectively:
20
“It is recommended to set this bit to 1”.
ep
M13 TJAT and RJAT settings incorrect in Programmer’s Guide
9S
3.9
tem
be
r,
For the recommended setting of the TJAT and RJAT Configuration Register bits, refer to Section
16 of the Programmer’s Guide for VT/TU mapping modes and to Errata item 3.9, below, for the
DS3 M13 operational modes.
ay
,1
The TJAT and RJAT Configuration Register recommendations are incorrect in the TEMAP
Programmer’s Guide for channelized DS3 applications.
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hu
rsd
Sections 6.2.1 (T1) and 7.1.1 (E1) state the TJAT and RJAT manual centering procedures setting
Register 0017H + 80H*N TJAT Configuration and Register 0013H + 80H*N RJAT Configuration
to values of 0x20.
fo
liv
ett
io
Neither centering procedure should be followed for channelized DS3 T1 or E1 applications.
Rather, these two registers should be programmed with values of 0x31 upon initialization for all
modes. The only exception is where PM73122 AAL1gator-32 is connected to the TEMAP’s
system side SBI bus and operating in SRTS mode. In this particular application, the RJAT
Configuration Register 0013H + 80H*N must be set to 0x23.
inv
ef
uo
The TEMAP Programmers Guide’s TU mapping mode recommendations for TJAT and RJAT
Configuration registers in Section 16 are correct and should be followed. This includes the
manual centering routine for the TJAT and RJAT in Section 16.1.1.
yV
3.10 IILPU max spec limit has been revised
Do
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In Table 33, the D.C. Characteristics table, the input low current parameter, IILPU maximum has
been changed from +100 mA to +150 mA.
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Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
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:05
3.11 Tolerance of TICLK not stated in pin description
:43
The following Text should be added to the TICLK pin description:
02
11
TICLK input pin AA6:
- This input requires a 44.736 MHz +/- 20ppm clock source.
20
3.12 CLK52M Clarification
tem
be
r,
In Section 9.19.3 DS3 Desynchronizer of the TEMAP Data Sheet, the following statement is
misleading:
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“The Desynchronizer monitors the Elastic Store level to control the de-stuffing algorithm
to avoid overflow and underflow conditions. The Desynchronizer assumes either a
51.84 MHz clock (provided internally) or a 44.928 MHz clock (provided via input
CLK52M).”
rsd
ay
The 51.84MHz clock option is not provided internally within the TEMAP device. Hence, DS3
signals cannot be transported without connecting CLK52M.
hu
Refer also to Errata Section 2.3 for CLK52M discussion when demapping DS3s.
io
nT
3.13 Recommended RTDM Leak Rate incorrect
liv
ett
It was incorrectly recommended in the TEMAP Programmer’s Guide, Section 16.4 b) “Register
12E0H: RTDM Pointer Justification Rate Control” that E1RATE[1:0] be set to 10.
uo
fo
The recommended settings should read E1RATE[1:0]=00, the default and slowest leak rate
settings to ensure no degradation of jitter performance.
inv
ef
3.14 Behavior of FIFO status handling needs clarification
Do
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In the extract and insert SBI (EXSBI, INSBI) FIFOs, the TEMAP has a priority mechanism for
reporting underruns and overruns on certain tributaries. In general, lower-numbered tributaries
can seemingly block the reporting of FIFO events on higher-numbered tributaries.
Consider an example where all tributaries underrun continuously. After reading status register
errors for the first few tributaries, it may be the case that new underrun events are registered. In
this case, errors will appear again for lower number tributaries before errors for higher number
tributaries can be read.
In general, errors for a particular tributary cannot be read from the status register if an error on
any lower numbered tributary has not been read.
This behavior will only become evident in the rare event that several tributaries are
simultaneously exhibiting FIFO errors. Note that this priority mechanism does not inhibit normal
behavior of the TEMAP device.
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Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
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3.15 RJAT SYNC bit description in EXSBI CLK_MODE field clarified
:43
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In Register 1716H: EXSBI Tributary Control Indirect Access Data, the CLK_MODE[1:0] bit
description includes the following statement:
02
11
"When using the phase field of the Link Rate octet, the SYNC bit in the RJAT
configuration register needs to be set."
tem
be
r,
20
For clarification, the TEMAP RJAT is not usually connected to the TEMAP EXSBI. Hence, this
comment about the “phase field” is more relevant to the device that uses this information,
PM73122 AAL1gator-32’s EXSBI, rather than TEMAP.
ep
3.16 Miscellaneous Pins Incorrect
Do
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ett
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ay
,1
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In Section 8, the Pin Description section, of the Datasheet, Pin AA22 was wrapped and read AA2
and 2. The Miscellaneous Pins table should read:
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Document ID: PMC-2001480, Issue 3
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20
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:43
No Connect. These pins are not connected to any internal logic.
liv
A1
B2
AA2
V3
W20
AA22
Y21
W21
K22
K21
Y1
W1
F4
G1
V20
Y22
K20
J19
W4
V1
E1
U19
R22
J22
J20
K1
K2
T4
A1
B2
uo
fo
NO CONNECT
:05
Miscellaneous Pins
inv
ef
3.17 Missing Diagrams
Do
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db
yV
Several diagrams were omitted from the TEMAP Data Sheet. These diagrams are reproduced here
with the associated Data Sheet Figure Number.
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Document ID: PMC-2001480, Issue 3
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40
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Figure 11 DJAT Minimum Jitter Tolerance vs. XCLK Accuracy E1 Modes
20
34
29
250
0
32
300
354
Hz
100
± ppm
hu
Figure 12 DJAT Jitter Transfer T1 Modes
io
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0
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liv
62411
min
-20
62411
max
43802
max
DJAT
response
inv
ef
-30
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db
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-40
-50
ett
-10
Jitter Gain
(dB)
rsd
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XCLK Accuracy
200
9S
25
100
ep
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30
,1
Max frequency
offset (PLL Ref
to XCLK)
02
35
DJAT Minimum
Jitter Tolerance
UI pp
36
1
10
6.6
100
1k
Jitter Frequency, Hz
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Document ID: PMC-2001480, Issue 3
10k
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Figure 13 DJAT Jitter Transfer E1 Modes
F1
C1
84 bits
84 bits
84 bits
84 bits
C2
F3
C3
F4
F2
C2
F3
C3
F4
C1
F2
C2
F3
C3
F4
C1
F2
C2
F3
C3
F4
F1
C1
F2
C2
F3
C3
F4
F1
C1
F2
C2
F3
C3
F4
F1
fo
ef
F1
C1
F2
C2
F3
C3
F4
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M-subframe 6 M2
M-subframe 7 M3
84 bits
F2
ett
C1
liv
F1
F1
M-subframe 4 P 2
M-subframe 5 M1
84 bits
uo
M-subframe 1 X 1
M-subframe 2 X 2
M-subframe 3 P 1
84 bits
io
84 bits
nT
Figure 17 DS3 Frame Structure
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Figure 18 FER Count vs. BER (E1 mode)
:43
8
6
11
Average Count Over
Many 1 Second Intervals
7
02
5
20
4
r,
3
2
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Bit Error Rate (x 10 -3 )
9
1
50
100
150
200
250
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Figure 25 DS3 Diagnostic Loopback Diagram
,1
Framing Bit Error Count Per Second
RCLK
RPOS/
RDAT
RNEG/
RLCV
MX23
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DS3
FRMR
UNI
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Optional
AIS
Insertion
DS3
TRAN
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TCLK
TPOS/
TDAT
TNEG/
TMFP
F MX12 #7
F R MX12 #6
RM
F R
MX12 #5
M
R
F MR
MX12 #4
R
F MR
MX12 #3
RR
F M MX12 #2
R
F R
MX12 #1
RM
MR
R
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Figure 26 DS3 Line Loopback Diagram
F MX12 #7
F R MX12 #6
RM
F R
MX12 #5
M
R
F MR
MX12 #4
R
F MR
MX12 #3
R
F MR
MX12 #2
F RR
MX12 #1
RM
MR
R
:43
RCLK
RPOS/
RDAT
RNEG/
RLCV
TCLK
TPOS/
TDAT
TNEG/
TMFP
tem
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MX23
20
02
11
DS3
FRMR
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DS3
TRAN
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Figure 30 PRGD Pattern Generator
2
3
32
ef
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LENGTH
PS
TAP
db
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inv
Figure 44 RSTB Timing
tV RSTB
Do
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RSTB
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Figure 65 XCLK Input Timing
:43
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t H XCLK
11
XCLK
20
02
t XCLK
t L XCLK
tem
be
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3.18 Revision ID Bits Section clarification.
ep
The TEMAP Revision ID is located in ID[3:0] bits of Register 0x02. In the TEMAP, this field
will have a value of “0101”.
,1
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(Issue 1 of this document, PMC-2001480, TEMAP Datasheet Errata, Issue 1, Section 7,
incorrectly stated that TYPE[3:0] contained the Revision ID).
rsd
ay
3.19 Byte Deletion/Insertion in VT/TU Mapping Mode
inv
ef
uo
fo
liv
ett
io
nT
hu
While rare, it is possible for jitter on XCLK or the selected T1/ E1 transmit clock to cause an
overflow or underflow in the transmit mapper (TTMP) FIFO. The T1/E1 transmit timing can be
sourced from the two clock master sources, the CTCLK input or the recovered T1/E1 clock, or
from the two clock slave sources, an ECLK[x] input or the SBI tributary rate received on the SBI
add bus. By design, underflow or overflow will result in the loss of a byte of data. The
initialization procedure shown in Section 16 of the Programmer’s Reference Guide will push the
FIFO closer to the center such that it can withstand more jitter from these clocks to reduce any
impact on the datapath. If the FIFO is close to an underflow or overflow condition and jitter does
push it over or under, the FIFO will insert or delete a byte of data, pushing itself away from these
states and giving itself at least another 8 UI of margin against future jitter events on XCLK or the
selected T1/E1 transmit clock.
Do
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db
yV
You should use the initialization sequence shown in Section 16 of the Programmer’s Reference
Guide (PMC-1991268).
Proprietary and Confidential to PMC-Sierra, Inc., and for its Customers’ Internal Use
Document ID: PMC-2001480, Issue 3
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TEMAP Production Release Errata
Released
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Notes
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