INFINEON PEB1757E

PRELIMINARY PRODUCT FLYER
Semiconductor Solutions for
High Speed Communications
and Fiber Optic Applications
Tethys™ 4192 is optimized for SONET/SDH applications as a full-duplex four STS-192/STM-64
MUX/DEMUX with full framer functionality including
pointer processing, and overhead termination; ideal for
aggregation, ADM and DWDM applications. In the
demultiplex ingress direction, Tethys™ 4192 accepts
four STS-192/STM-64 signals in SFI-4.2/SFI-4.1 format.
Tethys locates the incoming SONET/SDH frame,
optionally de scrambles the data, monitors the TOH
and POH, and provides STS-1 level pointer processing.
In addition, Tethys supports TOH and POH overhead
transparency.
In the multiplex direction, Tethys™ 4192 accepts four
STS-192/STM-64 or sixteen STS-48/STM-16 signals in
either 4 x 2.5 Gbit/s or serial 2.5 Gbit/s format. Further
Tethys provides corresponding functionality in the
DEMUX direction.
Applications
■ ADM
■ Metro Aggregation
■ Digital Cross connects
■ Repeaters
■ DWDM Equipment
■ Test Equipment
Tethys™ 4192
■
■
■
Features
■ Complies with OIF specifications
SFI-4.2, SFI-4.1 or provides serial
STS-48/STM-16 links
■ Differential CML 2.5 G I/O interface
to optics
■ Differential CML 2.5 G I/O interface
to system/backplane
■ TFI-5 Support
■ Processes SONET/SDH quad
STS-192/STM-64 on the line side
interface
■ Processes SONET/SDH quad
STS-192/STM-64 or sixteen
■
■
■
■
■
STS-48/STM-16 on the system/client side serial 2.5 Gbit/s interface
Provides line timing of all line and
system side interfaces
Processes SONET/SDH flexible
concatenation streams of STS-2c,
3c, 4c, … to 192c
Supports auto-detection of concatenation streams STS-3c/STM-1,
STS-12c/STM-4, STS-48c/STM-16
and STS-192c/STM-64
Supports STS-1 level pointer processing of STS-192/STM-64 or
STS-48/STM-16 streams
Provides interfaces for dropping
alarm and status information, and
for forcing alarm conditions
Provides de skew of up to ± 250 ns
for quad STS-192/STM-64
Power dissipation of 15 W, depending on mode of operation
Terminates and generates SONET
section, line, and path layers
■
■
■
■
■
■
■
■
■
Provides TOH and POH
transparency
Provides monitoring of POH bytes
B3 and N1/Z5
Provides B2 SF/SD capability for
Poisson and bursty error
distribution
Provides full TOH/POH add/drop
Provides STS-1 level POH
add/drop
Supports more than ± 746 UI
programmable output skew on
STS-192/STM-64 or
STS-48/STM-16 output links to
external cross-connects
For diagnostic purposes, Tethys
provides PRBS generator/checker
and loop backs
Provides B1, B2, H1 and H2 bit
error generation for both receive
and transmit direction diagnostics
Provides 1 second performance
monitors
Te t h y s ™ 4 1 9 2
PEB1757E
Quad STS-192/STM-64 MUX/DEMUX
N e v e r
s t o p
t h i n k i n g .
PRELIMINARY PRODUCT FLYER
Features (cont’d)
■ Provides B1, B2, H1 and H2 bit
error generation for both receive
and transmit direction diagnostics
■ Provides 1 second performance
monitors
■ 0.13 µm process, 1.2 V core, 3.3 V
I/O
■ Motorola 32-bit synchronous
microprocessor interface for configuration, control, and status
monitoring
■
■
■
P-FCHBGA-1397 CBGA
Complies with GR-253, GR-1377,
ITU-T G.707, and ANSI T1.105
Provides a standard 5 signal IEEE
1149.1 JTAG test port for boundary scan board test purposes
Standards
■ ANSI T1.105-2000-193R2
(DRAFT)
■ ANSI T1.105.05-1994
■ T1X1.3/93-005RI -1993 preliminary
■ GR-253-CORE Sept. 2000
■ ITU-T G.707 10/2000
Specifications
■ OIF SFI-4.1
■ OIF SFI-4.2
■ OIF TFI-5
Type
Sales Code
Description
Package
1397 ball BGA
–
–
P-FCHBGA-1397
TOH/POH
Drop
STS-192 #1
Alarm
Drop
Alarm
Force
1 x STS-192
De-Framers
STS-192
Pointer Processor
PRBS Gen/Chk
#1
STS-192 #2
TOH/POH
Add
Tethys 4192
#1
#1
1 x STS-192/
4 x STS-48
Framers
STS-192 #1
STS-48 #1 - #4
1 x STS-192
De-Framers
Mux
DeMux
STS-192 #3
1 x STS-192
STS-192
Pointer Processor
PRBS Gen/Chk
De-Framers
#4
STS-192 #4
#4
#16
1 x STS-192/
4 x STS-48
Framers
STS-192 #4
STS-48 #13 - #16
1 x STS-192
De-Framers
RX
TX
STS-192 #1
1x STS-192
Framers
#1
STS-192 #2
1x STS-192
STS-192/ 4xSTS-48
Pointer Interpreter
PRBS Gen/Chk
#1 #1
1 x STS-192/
4 x STS-48
De-Framers
STS-192 #1
STS-48 #1 - #4
Framers
De-Mux/
Mux
STS-192 #3
iMux
1 x STS-192
De-skew
Framers
STS-192 #4
#16
STS-192/ 4xSTS-48/
Pointer Interpreter
PRBS Gen/Chk
#16 #4
1 x STS-192/
4 x STS-48
De-Framers
STS-192 #4
STS-48 #13 - #16
1 x STS-192
Framers
Alarm
Force
TOH/POH
Add
32 bit data
u-proc I/F
Tethys™ 4192 PEB1757E Block Diagram
Published by Infineon Technologies AG
JTAG I/F
TOH/POH
Drop
Alarm
Drop
PRELIMINARY PRODUCT FLYER
Overview
Tethys™ 4192 is a highly integrated device that implements
full duplex SONET/SDH processing at STS-192/STM-64 or
STS-48/STM-16 rates. In the rest of this document, only
SONET terminology will be stated. However, SDH terminology
applies equally well unless otherwise written.
Tethys™ 4192 supports up to 40 Gbit/s bandwidth or 80 Gbit/s
full-duplex. It provides section, line, and path overhead processing and supports framing, scrambling/de scrambling,
alarm signal insertion/detection, bit interleaved parity
(B1/B2/B3) processing, path overhead processing, pointer processing and TOH and POH transparency. It also provides substantial performance monitoring of TOH/POH overhead for the
receive direction with 1 second count accumulation.
On the line side, quad STS-192 are supported. The interface
utilizes SFI-4.2 or SFI-4.1. The STS-192 interfaces can be
received at differing clock frequencies, depending on the
SONET line clock variation of ± 20 ppm. Similarly, the STS-192
outputs can be line timed to the corresponding incoming
STS-192’s.
On the system/client side, quad STS-192 or sixteen STS-48
can be interfaced. In this case, a 4 × 2.5 Gbit/s or serial
2.5 Gbit/s is utilized for the respective interfaces.
The System side can support 16 independent STS-48 links or
four groups of STS-192 links, where each group of an
STS-192 link consists of four 2.488 Gbit/s links. This means for
instance that 8 STS-48’s and two STS-192’s can be supported
at the same time. Or alternatively, three STS-192’s and four
STS-48’s. In fact, any legal mix of interfaces can be supported.
The selection/configuration of the system and line side interfaces is completely independent.
All TOH (A1 … E2) bytes can be added/dropped onto the parallel TOH/POH interfaces. This applies in both receive and
transmit directions.
All POH passing through the device can be added or dropped
onto the TOH/POH ports. The TOH and POH ports are physically shared.
Detected alarms like LOS, LOF, SEF, AIS-L can be dropped
onto the parallel Alarm Drop Interfaces. This applies in both
the receive and transmit directions. In addition, Tethys™ 4192
can drop the payload concatenation configuration onto the
same interface.
In TOH Transparency mode, J0, B1, E1, F1, K1, K2, D1-D12,
S1, M0/M1 and E2 bytes are transparent through the device.
In POH Transparency mode, all POH bytes, including the B3
bytes, are transparent as is. TOH/POH transparency can be
implemented through the TOH/POH ADD/DROP ports using
the dropped overhead and bit error masks on these interfaces.
This applies to both the receive and transmit directions.
Published by Infineon Technologies AG
Tethys™ 4192 can process any legal mix of flexible concatenated signals ranging from STS-1, STS-2c, STS-3c … up to
STS-192c. Each set of concatenated signals must fit inside an
STS-48 or STS-192 boundary (depending on whether the
pointer processor is configured as an STS-48 or STS-192
block) and must be formatted as an STS-Nc frame as defined
in GR-253-CORE.
Tethys™ 4192 provides the ability for certain frame structures
to be automatically detected and configured into the device.
This feature allows the user to interface to systems with
unknown standard payload concatenation configurations.
Various diagnostic features are provided. Framed PRBS-32
can be generated and checked on any channel via loop backs.
Errors can be inserted into B1, B2, H1 and H2 bytes on a bitby-bit basis.
To support asynchronous timing between different physical
ports, Tethys™ 4192 provides STS-1 level pointer processing
for quad STS-192 interfaces in the receive direction. On the
line side receive interface, all inputs can be asynchronous with
frequency differences of ± 20 ppm.
The pointer processor on the receive side adjusts for these differences and outputs the STS-192 or STS-48 streams based
on the line timed or system frequencies selected on the system side. In the transmit direction, the system side ingress
ports and line side egress ports must be locked to the same
frequency.
Tethys™ 4192 aggregates all STS-48 or STS-192 ports from
the system side to the line side in the transmit/multiplex direction. In the case of quad STS-192 interfaces on the line side,
any one of the STS-48 ports can be aggregated into any one
of the STS-192 line side ports.
To select the best timing available in the system, the S1 bytes
are processed and the system has the option to select either
timing from the line or timing from the local reference source.
On the system side, the receive outputs can be line timed to
their respective system side transmit inputs.
When interfacing the system side physical ports to different
transmission paths, the ports can have skew of up to ± 250 ns.
This skew must be tolerated in order to support the normal
multiplex of STS-48 streams to higher rate signals to the line
side. For this purpose, Tethys™ 4192 includes de skew buffers
for desks of up to ± 250 ns between the ports on the system
side.
Tethys™ 4192 generates and detects all SONET/SDH relevant alarms and defects, including LOS, LOF, RDI-L, REI-L,
AIS-P, AIS-L and LOC on each line side and system side interface.
PRELIMINARY PRODUCT FLYER
Applications
The application below shows how a quad STS-192 signal can be connected to a Tethys™ 4192 device.
In the transmit direction, Tethys™ 4192 performs the
reverse operation.
Tethys™ 4192 receives an SFI-4.2’s format STS-192
frame from the optical device. It then performs framing,
performance monitoring, and rate adaptation in the
receive direction, and finally outputs an STS-48 single
2.5 Gbit/s differential pair to the STS-48 link cross connect or the STS-48 optics transceivers.
TOH and POH interfaces may be added and dropped as
required through the respective Tethys™ 4192 ports
(not shown).
10G
Many other configuration options are possible that cannot be shown in this diagram. Please refer to the data
sheet for more detailed information.
#1
STS-48
1x2.5G
#8
STS-48
1x2.5G
STS-192
#1
4x2.5G
STS-192
10G
Optics
STS-48 Link
STS-192
Cross
4x2.5G
#1
STS-48
1x2.5G
#8
STS-48
1x2.5G
Connect
Infineon
Tethys 4192
#1
10G
STS-48
1x2.5G
STS-192
#4
STS-48
2.5G
2.5G
Optics
4x2.5G
STS-192
10G
Optics
STS-192
4x2.5G
#8
STS-48
1x2.5G
STS-48
2.5G
2.5G
Optics
40G - STS-48 Cross Connect and Aggregation
How to reach us:
http://www.infineon.com
Published by
Infineon Technologies AG,
St.-Martin-Strasse 53,
D-81669 München
© Infineon Technologies AG 2003. All Rights Reserved.
Tethys™ is a trademark of Infineon Technologies AG.
Template: pb_tmplt.fm/4/2003-07-01
Attention please!
The information herein is given to describe certain components
and shall not be considered as a guarantee of characteristics.
Terms of delivery and rights to technical change reserved.
We hereby disclaim any and all warranties, including but not
limited to warranties of non-infringement, regarding circuits,
descriptions and charts stated herein.
Information
For further information on technology, delivery terms
and conditions and prices please contact your nearest
Infineon Technologies Office.
Published by Infineon Technologies AG
Warnings
Due to technical requirements components may contain dangerous substances. For information on the types in question
please contact your nearest Infineon Technologies Office.
Infineon Technologies Components may only be used in lifesupport devices or systems with the express written approval
of Infineon Technologies, if a failure of such components can
reasonably be expected to cause the failure of that life-support
device or system, or to affect the safety or effectiveness of that
device or system. Life support devices or systems are intended
to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons
may be endangered.
2003-07-01
R&L