SierraNet M1288

Fibre Channel provides a secure, bi-directional, physical or logical point-to-point, low latency connection between two devices at a time. Like other serial interfaces such as Serial Attached SCSI (SAS), in Fibre Channel data is transmitted over the physical medium in serial fashion as opposed to parallel methods, which are used in SCSI and ATA physical interfaces. Serial transmission enables much longer connection distances as compared to parallel transmission methods, because far fewer signal lines are required, thereby reducing noise created by multiple signal lines all switching at the same time (cross talk).

A primary use for Fibre Channel is in the transport of block oriented storage traffic in SAN (Storage Area Network) applications. There are also specialized upper layer Fibre Channel protocols that are used in Defense and Avionics applications, to transport video streams for heads-up displays, for example.

Fibre Channel is designed to work with either optical fiber physical medium or copper cables in many connector and cable type configurations. Copper cables are relatively inexpensive, but they are useable only for shorter distances, in the range of 5-meters at 16GbFC and 3-meters at 32GbFC. In general, the higher the transmission speed, the shorter the distance that can be reliably supported by copper cable technology. A variety of copper solutions are available, the most commonly used being Direct Attach Copper (DAC) cabling in both SFP (Small Form-factor Pluggable) and QSFP (Quad Small Form-factor Pluggable) configurations. SFP and QSFP optical cabling solutions are also available, supporting reliable transmission distances greater than 10 meters, up to about 10 kilometers.

Fibre Channel is a layered protocol, and is modeled loosely on the OSI model for networks. In the OSI model, and in the case of Fibre Channel, each layer provides specific services and makes the results available to the next layer.  Figure 1 below compares the defined OSI layer to the defined Fibre Channel layers.

The layers in the table represent different functions and services that exist within the Fibre channel protocol definition. As with the other communication standards, protocol level analysis is often focused at the link layer (FC-2) and above.

Fibre Channel, like any network architecture, transports blocks of application information, called data payloads. Before sending a payload over the physical link, additional Fibre Channel specific control bytes are added to both the start and the end of the payload data. The combination of the control bytes and the payload data is called a frame, which is the basic unit of information in Fibre Channel.

Fibre Channel transfers data through switched or direct point-to-point connections which work by creating session specific connections between the source and destination devices. These connections last only until the transfer is completed and can be temporarily preempted by higher priority transfer requests.

Connections are made on Fibre Channel systems through “interconnect components” such as switches, hubs, and bridges. The ability of Fibre Channel to use different interconnect devices makes it flexible and scalable depending on user needs. A fully switched Fibre Channel network is called a Fabric topology. Fabric topology permits multiple alternative paths to be established between any two ports in the Fabric.

Fibre Channel protocol is designed to support very low latency and high data transfer rates. The currently approved standard supporting up to 32Gb/S is generally referred to as 32GFC. Server virtualization and storage virtualization are broad trends that are driving the need for higher bandwidth. The need for high bandwidth in the network infrastructure is just now beginning to drive the replacement of previous product generations of 4,8 and 16GFC by 32GFC and soon, 64GFC.

Fibre Channel is a good choice for any environment with many servers needing lossless access to centralized storage, computer data centers for example. Because of this, Fiber Channel enjoys over 80% market share as the network interface used in external storage systems such as SAN environments.

• Capture and analyze up to 256GB of Ethernet or Fibre Channel traffic at full wire transmission rate
• QSFP-dd SFP-112 (native retimed ports)
• OSFP supported with probe
• DAC, AOC, AEC and Optical module support
• Ethernet 1, 2, 4 lane support (8 lanes with two chassis)
  • 50/100/200/400/800GE PAM4
  • 25/50/100GE NRZ
• Fibre Channel fabrics
  • 64/128GFC PAM4
• Complete bi-directional capture of line rate traffic (800GbE requires 2 Sierra M1288 units)
• API for automation of test routines
  • Python scripts for popular Linux OS environments
  • Post capture, comprehensive analysis capabilities with Verification Script Engine™ (VSE)
• Deep memory buffers and pre-capture filtering for extended analysis needs
• Advanced, multi-state triggering & filtering
• Comprehensive, multi-condition, multi-state Error Injection and Traffic Jamming capabilities (InFusion™)
• 128G or 256G recording buffers
• Dynamic memory allocation
• 2U form-factor with rack mount kits
• Extensive Ethernet and Fibre Channel protocols supported, including FCoE, NVMe-oF, ORAN, PTP 1588, RoCE and iSCSI
• Multiple trace view formats
• Seamless WireShark integration
• USB C & Gigabit Ethernet Host Interfaces for fast upload and easy management

The SierraNet M1288 offers the most cost effective, advanced and fully integrated Ethernet and Fibre Channel data capture and protocol verification systems available for developers and protocol test engineers. The M1288 protocol analysis systems provide engineers with 100% recording of all Fibre Channel and Ethernet related traffic at full line rates and offers the addition of error injection and traffic corruption with our InFusion™ tools for advanced validation and verification testing.

The SierraNet M1288 hardware platform and Net Protocol Suite graphical user interface provides the highest level of performance and flexibility available in the market for legacy and todays’ emerging high-speed network and fabric deployments.

The SierraNet M1288 provides ultimate flexibility in analysis and verification of traditional or converged Ethernet and Fibre Channel products in a single platform and the flexibility to add protocol specific features, functionality, and speed support at the time of purchase or later by the addition of license keys.

Each FlexPort SFP112 pair can probe and/or jam both Ethernet and Fibre Channel links of speeds up to 100Gbps/link for Ethernet and/or 128G FC/link on copper or optical cabling and eliminates the need for separate "single function" blades, pods, or adapters found in some competitive products providing a highly compact, extremely flexible, multi-function protocol analyzer.

The 2 SFP112 pairs may be aggregated to support 100Gbps Ethernet links, and the integrated QSFP-DD connections support all Ethernet rates – 50GbE, 100GbE, 200GbE, 400GbE link traffic – for both analysis and jamming applications. 800GbE analysis requires 2 SierraNet M1288 units.

In addition to FlexPort technology, the SierraNet M1288's sophisticated analysis and jamming software, the Net Protocol Suite, provides unmatched flexibility with customized data displays that easily identify and navigate to specific events of interest quickly. Decoding in the Net Protocol Suite's multiple trace views provide superior visibility for troubleshooting low level to application layer issues, decode per the supported specifications and their associated encoding schemes, and the zero-time search and filter capabilities easily find Ethernet and Fibre Channel events in a contextual and intuitive way.

In a multi-protocol environment, Teledyne LeCroy's CrossSync™ can synchronize and correlate traces with our other leading protocol analysis tools, such as the PCI Express Summit analyzers, to understand how traffic, stimulus, and/or errors propagate across bridges or adapters.