HIPPI

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Serial HIPPI fibre optic cable SerialHIPPIfibre optic cable.jpg
Serial HIPPI fibre optic cable

HIPPI, short for High Performance Parallel Interface, is a computer bus for the attachment of high speed storage devices to supercomputers, in a point-to-point link. [1] It was popular in the late 1980s and into the mid-to-late 1990s, but has since been replaced by ever-faster standard interfaces like Fibre Channel and 10 Gigabit Ethernet.

Contents

HIPPI was the first “near-gigabit” (0.8 Gbit/s) (ANSI) standard for network data transmission. It was specifically designed for supercomputers and was never intended for mass market networks such as Ethernet. Many of the features developed for HIPPI were integrated into such technologies as InfiniBand. What is remarkable about HIPPI is that it came out when Ethernet was still a 10 Mbit/s data link and SONET at OC-3 (155 Mbit/s) was considered leading edge technology.

The first HIPPI standard (HIPPI-PH) defined a 50-pair (100-wire) unidirectional twisted pair cable, running at 800 Mbit/s (100 MB/s) with maximum range limited to 25 metres (82 ft). A bidirectional connection therefore required two separate cables. 32 bits are transferred in parallel with a 25 MHz clock. [2] [3] Later standards included a 1600 Mbit/s (200 MB/s) mode (using two cables running at the same 25 MHz clock in parallel) as well as Serial HIPPI using fibre optics with a maximum range of 10 kilometres (6.2 mi). [4]

HIPPI usage dwindled in the late 1990s. This was partly because Ultra3 SCSI offered rates of 320 MB/s and was available at almost any computer store at commodity prices.[ citation needed ] Meanwhile, Fibre Channel offered simple interconnect with both HIPPI and SCSI (it can run both protocols) and speeds of up to 400 MB/s on fibre and 100 MB/s on a single pair of twisted pair copper wires.[ when? ] Both of these systems have since been supplanted by even higher performance systems during the 2000s.

GSN - HIPPI-6400

From 1996 on an effort to improve the speed resulted in HIPPI-6400, [5] which was later renamed to GSN (for Gigabyte System Network), but GSN saw little use due to competing standards and high cost. GSN has a full-duplex bandwidth of 6400 Mbit/s or 800 MB/s in each direction. GSN was developed by Silicon Graphics and Los Alamos National Laboratory. It uses a parallel interface for higher speeds.

GSN copper cables (HIPPI-6400-PH) are limited to 40 metres (130 ft). [6] Like HiPPI-800, GSN uses two separate simplex channels (one in each direction). Unlike HiPPI-800, they are combined in a single cable and connector. Each channel consists of 16 data lines, four control lines, one framing line and two clock lines, for a total of 23 lines, all of which are differential. The connectors (Berg Micropax 100 [7] ) have 100 pins total, of which 92 (23×2×2) are used. [8] [9]

Fiber-optic cables (HIPPI-6400-OPT) are limited to 1 km. It uses the same principal signals as the copper interface, but runs everything at twice the clock rate, which halves the number of data and control fibers. Each channel thus consists of 8 data fibers, two control fibers and one clock and framing fiber each. All 12 fibers of a channel are bundled in a single multi-fiber connector and cable. A full-duplex connection thus consists of two separate cables. [3]

See also

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References

  1. "HIPPI FAQs". High Performance Networking Forum. 1999-02-26. Archived from the original on 2009-09-16. Retrieved 2009-06-02.
  2. Van Praag, Arie (1994-09-14). "Introduction to the Hippi Specifications". CERN. Retrieved 2023-11-10.
  3. 1 2 Tolmie, D.; Boorman, T.M.; Dubois, A.; Dubois, D.; Feng, W.; Philp, I. (1999-10-19). "From HiPPI-800 to HiPPI-6400: A changing of the guard and gateway to the future". Proceedings. 6th International Conference on Parallel Interconnects (PI'99) (Formerly Known as MPPOI). pp. 194–201. doi:10.1109/PI.1999.806412. ISBN   0-7695-0440-X. S2CID   57080285.
  4. Tech Target, HIPPI (High-Performance Parallel Interface), March 2011, by Rosario D'Elia, Mark Motsko, and Stephen C. Tenbrink
  5. "HiPPI-6400/Gigabyte System Network". Los Alamos National Laboratory. 2001. Retrieved 2015-01-12.
  6. CERN Courier, The Gigabyte System Network is demonstrated at CERN, Nov 2, 1999
  7. Van Praag, Arie (1997-02-18). "A SHORT Introduction to The GSN Specifications". CERN. Retrieved 2023-11-11.
  8. Hoffman, James R. (1996-11-13). "HIPPI-6400 Technology Dissemination". Los Alamos National Laboratory. Retrieved 2023-11-10.
  9. "SGI GSN Hardware Owner's Guide" (PDF). SGI. Retrieved 2023-11-10.
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