AN/FSQ-7 Combat Direction Central

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AN/FSQ-7 Combat Direction Central
Military command, control and coordination system
SAGE computer room.jpg
The AN/FSQ-7 included a Maintenance Intercom System (phone on end of cabinet).
Country United States
Command 1958-1968: Airdefensecommand-logo.jpgAir Defense Command
1968-1979: USAF - Aerospace Defense Command.pngAerospace Defense Command
State/
Installation/
Data center		 AL: Gunter Annex (DC-09)
AZ: Luke Air Force Base[1]
CA: Norton Air Force Base (DC-17)
ME: Bangor Air National Guard Base (DC-15)
MI: Custer Air Force Station (DC-06)
MI: K.I. Sawyer AFB (DC-14)
MN: Duluth Air National Guard Base (DC-10)
MO: Richards-Gebaur Air Force Base (DC-08)
MT: Malmstrom Air Force Base (DC-20)
ME: Topsham Air Force Station (BaADS)(DC-05)
ND: Grand Forks Air Force Base (DC-11)
ND: Minot Air Force Base (DC-19)
NJ: McGuire Air Force Base (DC-01)
NV: Stead AFB (DC-16)
NY: Hancock Field (Syracuse AFS) (DC-03)
NY: Stewart Air Force Base (DC-02)
VA: Fort Lee Air Force Station (DC-04)
WA: McChord Air Force Base (DC-12)
WI: Truax Field (DC-07)
OT: Northbay Canada
This list is incomplete; you can help by expanding it.
Part of Semi-Automatic Ground Environment
Area 0.5 acres (0.2 ha) [citation needed] — floor space
Research
Design
Prime[4]
   contractor		 USAF Cambridge Research Laboratory[2]
MIT Lincoln Laboratory[3]
IBM Military Products Division (renamed IBM Federal Systems in 1959) [5]
Cost $10 billion (in 1954;[6] $88.12 billion in today's dollars)

The AN/FSQ-7 Combat Direction Central (colloq. Q7) was a computerized command and control system for Cold War ground-controlled interception used in the USAF Semi-Automatic Ground Environment (SAGE) air defense network.[3] The largest computer system ever built, each of the 24 installed machines[7]:9 weighed 250 tons and had two computers.[8] The AN/FSQ-7 used a total of 60,000 vacuum tubes[8] (49,000 in the computers)[7]:9 and up to 3 megawatts of electricity, performing about 75,000 instructions per second for networking regional radars.

The AN/FSQ-7 calculated one or more[3] predicted interception points[4] for assigning manned aircraft or CIM-10 Bomarc missiles to intercept an intruder using the Automatic Target and Battery Evaluation (ATABE) algorithm.[9] Also used in the Nike AN/FSG-1 system, ATABE automated the Whiz Wheel (Felsenthal CPU-73 A/P Air Navigation Attack Computer)[10] method used in manual command post operations.[11]

Equipment at Computer History Museum

The Q7 fire button launched the Bomarc,[12] and an additional Q7 algorithm automatically directed the missile during climb and cruise to the beginning of its supersonic dive on the target when guidance transferred to the missile seeker system for the homing dive.[4]:30–3 Later improvements allowed transmission of Q7 guidance to autopilots of manned fighters for vectoring to targets[13] via the SAGE Ground to Air Data Link Subsystem (cf. bomber vectoring to a Bomb Release Point in 1965-73 Vietnam via vacuum-tube analog computers.)

History

The first US radar network used voice reporting to the 1939 Twin Lights Station in New Jersey, and the post-WWII experimental Cape Cod System used a Whirlwind I computer at Cambridge to network long-range and several short-range radars. The key Whirlwind modification for radar netting was the development of magnetic core memory that vastly improved reliability, operating speed (×2), and input speed (×4) over the original Williams tube memory of the Whirlwind I.[citation needed] The AN/FSQ-7 (“AN/FSQ” derives from Army-Navy / Fixed Special eQuipment)[14] was based on the larger and faster Whirlwind II design, which was not completed[3] and was too much for MIT's resources[citation needed] (Lincoln Laboratory Division 6 still participated in AN/FSQ-7 development).[15] Similar to the Q7, the smaller AN/FSQ-8 Combat Control Central was produced without an Automatic Initiation Area Discriminator and other equipment.[16]:151

The experimental SAGE subsector, located in Lexington, Mass., was completed in 1955, equipped with a prototype AN/FSQ-7 known as XD-1[17] in Building F. The third evaluation run with the XD-1 was in August[15] and the prototype was complete in October 1955 except for displays.[18] By 1959, the 2000th simulated BOMARC intercept had been completed by the Q7, while the Cape Canaveral BOMARC 624-XY1's intercept of a target drone in August 1958 used the Kingston, New York, Q7[4]:57 1500 miles away.[19] DC-1 at McGuire AFB was the first operational site of the AN/FSQ-7[3]:11:10 with consoles scheduled for delivery Aug-Oct 1956.[20] Groundbreaking at McChord Air Force Base was in 1957[21] where the "electronic brain" began arriving in November 1958.[22]

The SAGE/Missile Master test program conducted large-scale field testing of the ATABE mathematical model using radar tracks of actual Strategic Air Command and Air Defense Command aircraft conducting mock penetrations into defense sectors[9] (cf. Operation Skyshield). The vacuum-tube SAGE network was completed (and obsolete) in 1963, and a system ergonomic test at Luke Air Force Base in 1964. According to Harold Sackman, it "showed conclusively that the wrong timing of human and technical operations was leading to frequent truncation of the flight path tracking system."[7]:9 Backup Interceptor Control Systems (BUIC) were used to replace the AN/FSQ-7s:[7]:10 two remained at SAGE sites until 1983[7]:9 including McChord AFB,[23] and the Q7 at Luke AFB was demolished in February 1984.[24]

The SABRE airline reservation system used AN/FSQ-7 technology.[6] Q7 components were used in numerous films TV series and TV series needing futuristic looking computers, despite the fact they were built in the 1950s. Q7 components were used in The Time Tunnel, The Towering Inferno, Logan's Run, WarGames and Independence Day amongst many others.[25] The Computer History Museum displays several AN/FSQ-7 components.

Equipment

MIT selected IBM as the prime contractor for equipment construction.[26] The Central Computer System of the AN/FSQ-7 had two computers for redundancy each with Arithmetic, Core Memory, Instruction Control, Maintenance Control, Selection & IO Control, and Program elements.[27] The Q7 had input/output devices such as:

  • IBM 723 card punch and IBM 713 punched card reader
  • IBM 718 line printer (64 print positions)
  • drum auxiliary memory (50 "fields" of 2048 words each) and IBM 728 magnetic tape drives (32-bit words)
  • Crosstelling Input (XTL) from other AN/FSQ sites[28]
  • Display and Warning Light System with dozens of consoles in various rooms having Situation Display Tubes, Digital Display Tubes, and controls (e.g., push buttons and light gun) including:
    • Duplex Maintenance Console (two), each DMC operated one of the Central Computer Systems[29] and allowed diagnostics (a speaker was available)[23]
    • Tracker Initiator Consoles for designating a "blip" (radar return) to be tracked (assign a track number and to relay speed, direction, and altitude)[30]
    • Command Post Digital Display Desk[16]:149
    • Senior Director's keyed console with the Bomarc fire button[12]
    • LRI Monitor Console[28] for monitoring Long Range Radar data
    • Large Board Projection Equipment[31] Operator displays were directly copied on 35 mm film which were projected on the board.[32]

Punched card data was transferred to and from the core memory as binary images. Only the right 64 columns were transferred, with each row containing two 32-bit words. (The left columns could be punched using a special instruction.) Data was transferred to the line printer as a card image as well.[16]:125

Core memory element

The FSQ-7 and -8 used core memory with 32-bit words plus a parity bit, operating at a 6-microsecond cycle time. Both machines had two banks of memory, memory 1 and memory 2. On the FSQ 7 memory 1 had 65,536 words and memory 2 had 4096 words. On the FSQ-8, each bank had 4096 words.

For data storage, each word was divided into two halves, each half was a 15-bit number with a sign bit. Arithmetic operations were performed on both halves simultaneously. Each number was treated as a fraction between -1 and 1. This restriction is placed on data primarily so that the multiplication of two numbers will always result in a product smaller than either of the numbers, thus positively avoiding overflow. Properly scaling calculations was the responsibility of the programmer.

Instructions used the right half word plus the left sign bit to form addresses, yielding a 17-bit address space. The remainder of the left half word specified the operation. The first three bits after the sign specified an index register. The following bits specified an instruction class, class variation and instruction-dependent auxiliary information. Addresses were written in octal notation, with the two sign bits forming a prefix, so 2.07777 would be the highest word in memory 2.

Arithmetic registers were provided for both halves of the data word and included an accumulator, an A register that held the data value retrieved from memory, and a B register that held the least significant bits of a multiplication, the magnitude of a division, as well as shifted bits. There was also a program counter, four index registers, and a 16-bit real time clock register which was incremented 32 times a second.[16]:27 Trigonometric sine and cosine functions used 1.4 degree precision (256 values) via look-up tables.[16]:67

External video
video icon "On Guard! The Story of SAGE"
video icon AN/FSQ-7 used for Bomarc launch
video icon "In Your Defense" (Col. John Morton, narrator)

See also

References

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  18. http://dome.mit.edu/bitstream/handle/1721.3/40545/MC665_r15_M-3864.pdf?sequence=1
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  26. Bash, Charles J. and others (1986) IBM's Early Computers, MIT, pp.240-248
  27. Lua error in package.lua at line 80: module 'strict' not found.:57 (one of various SAGE documents at BitSavers.org)
  28. 28.0 28.1 http://dome.mit.edu/bitstream/handle/1721.3/40519/MC665_r15_M-3851-7.pdf?sequence=1
  29. Lua error in package.lua at line 80: module 'strict' not found.
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  31. http://dome.mit.edu/bitstream/handle/1721.3/40643/MC665_r16_M-4348.pdf?sequence=1
  32. Lua error in package.lua at line 80: module 'strict' not found.
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Records
Preceded by World's most powerful computer
1958 - 1959		 Succeeded by
IBM 7090
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