SATA STX-431

• Performance - Parallel ATA does not have scalability to support several more speed doublings, and it is nearing its performance capacity. By contrast, Serial ATA defines a roadmap starting at 1.5 gigabits per second (equivalent to a data rate of 150 MB/s) up to 6Gigabits per second.
• Lower Voltage - Parallel ATA's 5-volt signaling requirement will be increasingly difficult to meet as the industry continues to reduce chip core voltages. Serial ATA is better aligned with future manufacturing processes. It reduces signaling voltages to approximately 250 millivolts (1/4 volt).
• Pin Count - Currently, the parallel ATA interface has 26 signal pins going into the interface chip. Serial ATA uses only 4 signal pins, improving the pin efficiency and accommodating a highly integrated chip implementation.
• Improved Cabling - Parallel ATA bulky ribbon cables contain 40-pin header connector. Serial ATA introduces thin, flexible cabling scheme that offers longer cables and improved airflow within the chassis.
• Software Compatible - Serial ATA is compatible at the register level with parallel ATA. This means Serial ATA requires no changes to existing software and operating systems in order to function, and it provides backward compatibility with existing operating environments.
• SAS Compatibility - A significant feature offered by Serial ATA is the expectation that SATA will be form-factor compatibility with Serial Attached SCSI. SATA drives will plug directly into Serial Attached SCSI connectors and if supported in the system, will transparently operate as a SATA device. This allows systems to be deployed that can use either Serial Attached SCSI drives, for their high performance or SATA drives that will provide a lower-cost-per-megabyte storage platform.

• Serial ATA is a full duplex protocol. There is a continuous flow of signals from each device moving down the bus. The device and host are transmitting (TX) and receiving (RX) at the same time.
• Bidirectional traffic pattern eliminates the need for bus negotiation overhead
• Data characters vs Primitives - Primitives are the simplest elements within the Serial ATA protocol. Primitives are 32-bit DWORDs used to initiate control of the serial line functions (X_RDY, CONT, etc...). In addition to these "handshaking" and flow control signals, Primitives are also used to delimit or "frame" user data.
• Frame Information Structure (FIS) - A frame is an indivisible unit of information exchanged between a host and device. A frame consists of a SOF primitive, a Frame Information Structure (FIS), a CRC calculated over the contents of the FIS, and an EOF primitive. A FIS is the user payload of a frame; a frame is a group of Dwords that convey information between host and device as described previously.

• Serial ATA Working Group
• SearchStorage Serial ATA Technology
• T13 Technical Committee

The Catalyst STX-431 is configurable to individual user requirements and is field upgradeable, minimizing and preserving your test equipment investment. The STX-431 platform supports up to four full-duplex links at data rates up to 3 Gbps. The STX-431 can also be cascaded with other STX-431 and STX-460 units, increasing the number of physical links that can be monitored (up to 32 physical links) through a single GUI.

The STX-431 features several customizable options for triggering and pre-filtering ensuring that relevant data is captured. Both the triggering and filtering capabilities can be accessed either through 'Easy' mode, which features simple 'click to add' functionality, or 'Advanced' mode which features a 24-level state sequencer with 1 IF and 3 ELSE-IF conditions per state. 'Advanced' mode also supports three independent timers and the ability to change pre-filters for each state. Trace/Buffer size as well as pre- and post-trigger capture is also definable.

Captured traces can be displayed in a variety of ways to suit the analysis being performed. The Packet View decodes captured events and displays them with accurate time of occurrence and duration information. Link layer, transport layer, and application layer views are provided, using color to differentiate between each layer. Layers can be hidden, collapsed or expanded to vary the amount of data, from a meaningful summary to bit-level detail. The Spreadsheet View provides an organized chronological view of all bus events. Detailed information is provided on time stamps, duration, direction, source and destination addresses, command and/or picker contents. The Text and Column Views provide an intuitive understanding of frames, primitives, and other events, and includes at-a-glance addressing and summary indications of bus activity. The OOB Waveform View indicates OOB activities in waveform-like display. The captured OOB sequence is displayed in a graphical format, which represents the time relationships between the various OOB events.

Statistical summaries of the trace data are available at the click of a mouse button, and provide counts, timing, and performance information. Jumping from the statistical summaries to specific events is a simple mouse click, eliminating the need to search traces for events that may or may not be present. Comprehensive post-capture filters and search capabilities display relevant events with the detail necessary to isolate and solve protocol issues. When issues are found, bookmarks can be inserted in the trace to allow comments to be embedded for future reference.