- Preface
- Cisco ONS Documentation Roadmap for Release 9.2.1
- Chapter 1, CE-Series Ethernet Cards
- Chapter 2, E-Series and G-Series Ethernet Cards
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- Chapter 3, ML-Series Cards Overview
- Chapter 4, CTC Operations
- Chapter 5, Initial Configuration
- Chapter 6, Configuring Interfaces
- Chapter 7, Configuring CDP
- Chapter 8, Configuring POS
- Chapter 9, Configuring Bridges
- Chapter 10, Configuring IEEE 802.1Q Tunneling and Layer 2 Protocol Tunneling
- Chapter 11, Configuring STP and RSTP
- Chapter 12, Configuring Link Aggregation
- Chapter 13, Configuring Security for the ML-Series Card
- Chapter 14, Configuring RMON
- Chapter 15, Configuring SNMP
- Chapter 16, Configuring VLAN
- Chapter 17, Configuring Networking Protocols
- Chapter 18, Configuring IRB
- Chapter 19, Configuring IEEE 802.17b Resilient Packet Ring
- Chapter 20, Configuring VRF Lite
- Chapter 21, Configuring Quality of Service
- Chapter 22, Configuring Ethernet over MPLS
- Chapter 23, Configuring the Switching Database Manager
- Chapter 24, Configuring Access Control Lists
- Chapter 25, Configuring Cisco Proprietary Resilient Packet Ring
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- Chapter 26, ML-MR-10 Card Overview
- Chapter 27, IP Host Functionality on the ML-MR-10 Card
- Chapter 29: Configuring Security for the ML-MR-10 Card
- Chapter 30: Configuring IEEE 802.17b Resilient Packet Ring on the ML-MR-10 Card
- Chapter 31, Configuring POS on the ML-MR-10 Card
- Chapter 32, Configuring Card Port Protection on the ML-MR-10 Card
- Chapter 32, Configuring Ethernet Virtual Circuits and QoS on the ML-MR-10 Card
- Chapter 34: Configuring Link Agrregation on ML-MR-10 card
- Chapter 35, Configuring Ethernet OAM (IEEE 802.3ah), CFM (IEEE 802.1ag), and E-LMI on the ML-MR-10 Card
- Appendix A: CPU and Memory Utilization on the ML-MR-10 Card
- Appendix A, POS on ONS Ethernet Cards
- Appendix B, Command Reference
- Appendix C, Unsupported CLI Commands
- Appendix D, Using Technical Support
POS on ONS Ethernet Cards
This chapter applies to the ML-Series (ML100T-2, ML100X-8, and ML1000-2) cards and describes packet-over-SONET/SDH (POS) and its implementation on ONS Ethernet cards.
Note For information on packet-over-SONET/SDH (POS) interface configuration for the ML-MR-10 card, see Chapter 30 "Configuring POS on the ML-MR-10 Card."
This chapter contains the following major sections:
•POS Characteristics of Specific ONS Ethernet Cards
•Ethernet Clocking Versus SONET/SDH Clocking
POS Overview
Unlike Asynchronous Transfer Mode (ATM) and Frame Relay, Ethernet was not originally designed for interfacing with SONET/SDH. Ethernet data packets need to be framed and encapsulated into a SONET/SDH frame for transport across the SONET/SDH network. This framing and encapsulation process is known as POS.
Figure A-1 Ethernet to POS Process on ONS Node
ONS Ethernet cards all use POS. The Ethernet frame comes into the card on a standard Fast Ethernet or Gigabit Ethernet port and is processed through the ONS Ethernet card's framing mechanism and encapsulated into a POS frame. When the POS frame exits, the ONS Ethernet card in a POS circuit, this circuit is treated as any other SONET circuit (STS) or SDH circuit (VC) in the ONS node. It is cross-connected and rides the SONET/SDH signal out the port of an optical card and across the SONET/SDH network.
The destination of the POS circuit is an ONS Ethernet card or other device that supports a POS interface. The POS frames received by the destination card have the data packets stripped out and processed into Ethernet frames. The Ethernet frames are then sent to a standard Ethernet port of the ONS Ethernet card and transmitted onto an Ethernet network.
The G-Series, CE-Series, and E-Series (configured in port-mapper mode) ONS Ethernet cards map this SONET/SDH or POS circuit directly to one of the card's Ethernet ports. The ML-Series and E-Series (configured in EtherSwitch mode) cards include the POS port as a switchport in a switching fabric that includes the standard Ethernet ports on the card.
POS Interoperability
In addition to POS circuits between Ethernet cards of the same family, POS circuits between some Ethernet cards of different families are possible. The Cisco Transport Controller (CTC) circuit creation wizard shows available interoperable Ethernet cards under the destination card options, when a specific Ethernet card type is chosen as the circuit creation source card. You cannot mix circuits from an SDH node with circuits from a SONET node. POS circuits can be created between the mapper-type cards and the switch-type ONS Ethernet cards.
For Ethernet card POS interoperability, three main POS port characteristics must match:
•POS encapsulation
•CRC size
•Framing Mode
The CRC size option does not need to match on the two endpoints when using GFP-F framing mode.
All Ethernet cards do not interoperate or support all the POS port characteristic options. The following two tables list the interoperable Ethernet cards and characteristics. Table A-1 lists this information for cards supporting and configured with high-level data link control (HDLC) framing mode.
Table A-2 lists this information for cards supporting and configured with frame-mapped generic framing procedure (GFP-F) framing mode. With Table A-2 and GFP-F framing, the word LEX is used to represent standard mapped Ethernet over GFP-F according to ITU-T G.7041. Under GFP-F framing, the Cisco IOS CLI also uses this lex keyword to represent standard mapped Ethernet over GFP-F according to ITU-T G.7041.
Note Cisco proprietary RPR requires LEX encapsulation on all ML-Series cards. IEEE 802.17 RPR is not configurable and uses IEEE 802.17b encapsulation.
Note When over GFP-F, it is standard Mapped Ethernet over GFP-F according to ITU-T G.7041.
GFP-F framing is only supported on nodes running Software Release 5.0 and later. The ML100T-12 and ML1000-2 cards also require field programmable gate array (FPGA) version 4.0 or later for GFP-F framing.
When connecting different cards together POS-to-POS it is important to note the MTU size for each card. The following lists the MTU size and whether it is adjustable or fixed.
•CE-MR-10 - 9600 fixed
•CE-100 cards - 1500 fixed
•CE-1000 cards - 10004 fixed
•ML-100, ML-1000, and ML-MR-10 - Adjustable up to 9000
When mixing these cards together POS-to-POS you need to set the MTU of the router/switch connected to the card with the larger MTU to the maximum MTU size of the card with the smaller MTU. Here some examples:
•CE-100 to CE-1000 (must set MTU on router/switch connected to the CE-1000 to 1500)
•CE-100 to CE-MR-10 (must set MTU on router/switch connected to the CE-MR-10 to 1500)
•CE-1000 to CE-MR-10 (must set MTU on router/switch connected to the CE-1000 to 9600)
•ML-x to CE-100 (set the ML MTU to 1500)
•ML-x to CE-1000 (set the ML MTU to any value up to 9000, then set the router/switch connected to the CE-1000 to match that MTU value)
•ML-x to CE-MR-10 (set the ML MTU to any value up to 9000, then set the router/switch connected to the CE-MR-10 to match that MTU value)
POS Encapsulation Types
The ONS Ethernet cards support five POS encapsulation methods: Cisco Ethernet-over-SONET LEX (LEX), Cisco HDLC, Point-to-Point Protocol/Bridging Control Protocol (PPP/BCP), IEEE 802.17b, and E-Series proprietary. The ONS Ethernet source card and destination card must be configured with the same POS encapsulation to interoperate. All ONS Ethernet cards do not interoperate or support all types of encapsulation.
IEEE 802.17b
IEEE 802.17b encapsulation is the set encapsulation when the ML-Series card mode is 802.17. It is only supported on the ONS 15454 and ONS 15454 SDH ML-Series cards in Release 7.2 and later.
Figure A-2 illustrates the IEEE 802.17b extended data frame used by the ML-Series card. It is used with bridging. For comparison, the IEEE 802.17 basic data frame for IP only networks is also shown. The extended data frame adds an extended destination address and extended source address to the basic data frame.
Figure A-2 RPR Data Frames
LEX
The Cisco EoS LEX is the primary encapsulation of ONS Ethernet cards. This encapsulation is used under HDLC framing, and the protocol field is set to the values specified in Internet Engineering Task Force (IETF) Request For Comments (RFC) 1841. Under GFP-F framing, the Cisco IOS CLI also uses the keyword lex. With GFP-F framing, the lex keyword is used to represent standard mapped Ethernet over GFP-F according to ITU-T G.7041.
Figure A-3 illustrates EoS LEX under HDLC framing.
LEX is supported by all the ONS Ethernet cards, except the ONS 15454 and ONS 15454 SDH E-Series cards.
Figure A-3 LEX Under HDLC Framing
PPP/BCP
The PPP encapsulation is a standard implementation of RFC 2615 (PPP-over-SONET and SDH), and provides a standard implementation of RFC 3518 (BCP) to provide the transmission of 802.1Q tagged and untagged Ethernet frames over SONET. Figure A-4 illustrates BCP.
Figure A-4 BCP Under HDLC Framing
In some framing modes, the ONS 15454/ONS 15454 SDH ML-Series card supports routing functions. When this card POS port is configured to support routing with the PPP encapsulation, the IP packets are mapped into the HDLC frames that use the standard 0x0021 protocol code point. Figure A-5 illustrates PPP.
Figure A-5 PPP Frame Under HDLC Framing
Cisco HDLC
Cisco HDLC is a Cisco-standard mapping of packets into a serial interface. This encapsulation can be used to connect the interface on an ML-Series card to a POS interface on Cisco HDLC-compliant routers and switches.
When used to carry IP packets, the same HDLC frame structure is used, however the protocol field is set to 0x0800, and the payload contains the IP packet. Figure A-6 illustrates Cisco HDLC.
Figure A-6 Cisco HDLC Under HDLC Framing
E-Series Proprietary
The E-Series uses a proprietary HDLC-like encapsulation that is incompatible with LEX, Cisco HDLC, or PPP/BCP. This proprietary encapsulation prevents the E-Series from interoperating with other ONS Ethernet cards.
POS Framing Modes
The framing mode is the type of framing mechanism employed by the ONS Ethernet card to frame and encapsulate data packets into a POS signal. These data packets were originally encapsulated in Ethernet frames that entered the standard Fast Ethernet or Gigabit Ethernet interfaces of the ONS Ethernet card. All ONS Ethernet cards support HDLC framing. ML-Series and CE-Series cards also offer GFP-F framing mode.
HDLC Framing
HDLC is one of the most popular Layer 2 protocols. The framing mechanism used by the HDLC protocol, HDLC framing, is employed by a variety of other protocols, including POS on the ONS Ethernet cards. The HDLC framing mechanism is detailed in the IETF's RFC 1662, "PPP in HDLC-like Framing."
The HDLC frame uses the zero insertion/deletion process (commonly known as bit stuffing) to ensure that the bit pattern of the delimiter flag does not occur in the fields between flags. The HDLC frame is synchronous and therefore relies on the physical layer to provide a method of clocking and synchronizing the transmission and reception of frames.
GFP-F Framing
GFP defines a standard-based mapping of different types of services onto SONET/SDH. The ML-Series and CE-Series support frame-mapped GFP (GFP-F), which is the PDU-oriented client signal adaptation mode for GFP. GFP-F maps one variable length data packet onto one GFP packet.
GFP is composed of common functions and payload specific functions. Common functions are those shared by all payloads. Payload-specific functions are different depending on the payload type. GFP is detailed in the ITU recommendation G.7041.
POS Characteristics of Specific ONS Ethernet Cards
The following sections list and illustrate the various framing and encapsulation options supported by specific ONS Ethernet cards.
ONS 15454 and ONS 15454 SDH E-Series Framing and Encapsulation Options
LEX is not available on the ONS 15454 or ONS 15454 SDH E-Series cards. These cards are limited to the original proprietary E-Series encapsulation, which does not allow POS interoperability with non E-Series cards. Figure A-7 illustrates ONS 15454 and ONS 15454 SDH E-Series framing and encapsulation.
Figure A-7 ONS 15454 and ONS 15454 SDH E-Series Encapsulation and Framing Options
G-Series Encapsulation and Framing
The G-Series cards are supported on the ONS 15454 and ONS 15454 SDH platforms. They support LEX encapsulation and HDLC framing. There are no other POS framing modes or encapsulation options on this card. Figure A-8 illustrates G-Series encapsulation and framing.
Figure A-8 ONS G-Series Encapsulation and Framing Options
ONS 15454, ONS 15454 SDH, and CE-Series Cards Encapsulation and Framing
The CE-100T-8 cards are available for the ONS 15454 and ONS 15454 SDH platforms. The CE-1000-4 cards are available for the ONS 15454 and ONS 15454 SDH platforms. They support HDLC Framing and GFP-F framing. Under the GFP-F or HDLC framing mode, only LEX encapsulation is supported. Figure A-9 illustrates CE-Series card framing and encapsulation.
Figure A-9 ONS CE-100T-8 and ONS CE-1000-4 Encapsulation and Framing Options
ONS 15454 and ONS 15454 SDH ML-Series Protocol Encapsulation and Framing
The ML-Series card on the ONS 15454 and ONS 15454 SDH supports HDLC framing and GFP-F framing. Under both the HDLC framing mode and the GFP-F framing mode, LEX, Cisco HDLC, and PPP/BCP encapsulation is supported. LEX encapsulation is also the encapsulation for Cisco proprietary RPR on the ML-Series card. Cisco proprietary RPR requires LEX encapsulation in either framing mode. 802.17b encapsulation is the set encapsulation in IEEE 802.17b compliant RPR, which is only supported in GFP-F framing. Figure A-10 illustrates the ONS 15454 and ONS 15454 SDH framing and encapsulation options.
Figure A-10 ML-Series Card Framing and Encapsulation Options
Ethernet Clocking Versus SONET/SDH Clocking
Ethernet clocking is asynchronous. IEEE 802.3 clock tolerance allows some links in a network to be as much as 200 ppm (parts or bits per million) slower than other links (0.02%). A traffic stream sourced at line rate on one link may traverse other links which are 0.02% slower. A fast source clock, or slow intermediate clocks, may limit the end-to-end throughput to only 99.98% of the source link rate.
Traditionally, Ethernet is a shared media that is under utilized except for brief bursts which may combine from multiple devices to exceed line-rate at an aggregation point. Due to this utilization model, the asynchronous clocking of Ethernet has been acceptable. Some Service Providers accustomed to loss-less TDM transport may find the 99.98% throughput guarantee of Ethernet surprising.
Clocking enhancements on ONS Ethernet cards, excluding the E-Series cards, ensure Ethernet transmit rates that are at worst 50 ppm slower than the fastest compliant source clock, ensuring a worst-case clocking loss of 50 ppm - a 99.995% throughput guarantee. In many cases, the card's clock will be faster than the source traffic clock, and line-rate traffic transport will have zero loss. Actual results will depend on clock variation of the traffic source transmitter.