Project Nike Explained

Project Nike (Greek: Νίκη, "Victory") was a U.S. Army project, proposed in May 1945 by Bell Laboratories, to develop a line-of-sight anti-aircraft missile system. The project delivered the United States' first operational anti-aircraft missile system, the Nike Ajax, in 1953. A great number of the technologies and rocket systems used for developing the Nike Ajax were re-used for a number of functions, many of which were given the "Nike" name (after Nike, the goddess of victory from Greek mythology).The missile's first-stage solid rocket booster became the basis for many types of rocket including the Nike Hercules missile and NASA's Nike Smoke rocket, used for upper-atmosphere research.

History

Project Nike began during 1944 when the War Department demanded a new air defense system to combat new jet aircraft, as existing gun-based systems proved largely incapable of dealing with the speeds and altitudes at which jet aircraft operated. Two proposals were accepted. Bell Laboratories offered Project Nike while General Electric proposed a much longer-ranged, collision-course system named Project Thumper, which eventually delivered the BOMARC missile.[1]

Bell Labs' proposal would have to deal with bombers flying at 500 mph (800 km/h) or more, at altitudes of up to 60,000 ft (20,000 m).At these speeds, even a supersonic rocket is no longer fast enough to be simply aimed at the target. The missile must "lead" the target to ensure the target is hit before the missile depletes its fuel. This means that the missile and target cannot be tracked by a single radar, increasing the complexity of the system. By this point, the US had considerable experience with lead-calculating analog computers, starting with the British Kerrison Predictor and a series of increasingly capable U.S. designs.[1]

For Nike, three radars were used. The acquisition radar (such as the AN/GSS-1 Electronic Search Central with the AN/TPS-1D radar) searched for a target to be handed over to the Target Tracking Radar (TTR) for tracking. The Missile Tracking Radar (MTR) tracked the missile by way of a transponder, as the missile's radar signature alone was not sufficient. The MTR also commanded the missile by way of pulse-position modulation, the pulses were received, decoded and then amplified back for the MTR to track. Once the tracking radars were locked the system was able to work automatically following launch, barring any unexpected occurrences. The computer compared the two radars' directions, along with information on the speeds and distances, to calculate the intercept point and steer the missile. The entirety of this system was provided by the Bell System's electronics firm, Western Electric.

The Douglas-built missile was a two-stage missile using a solid fuel booster stage and a liquid fueled (IRFNA/UDMH) second stage. The missile could reach a maximum speed of 1,000 mph (1,600 km/h), an altitude of 70,000 ft (21 km) and had a range of 25 miles (40 km). The missile contained an unusual three part payload, with explosive fragmentation charges at three points down the length of the missile to help ensure a lethal hit. The missile's limited range was seen by critics as a serious flaw, because it often meant that the missile had to be situated very close to the area it was protecting.[1]

Consolidated Western Steel produced the launcher loaders. Fruehauf Trailer Corporation produced the trailers.

After disputes between the Army and the Air Force (see the Key West Agreement), all longer-range systems were assigned to the Air Force during 1948. They merged their own long-range research with Project Thumper, while the Army continued to develop Nike. During 1950 the Army formed the Army Anti-Aircraft Command (ARAACOM) to operate batteries of anti-aircraft guns and missiles. ARAACOM was renamed the US Army Air Defense Command (USARADCOM) during 1957. It adopted a simpler acronym, ARADCOM, in 1961.[1]

Nike Ajax

See main article: MIM-3 Nike Ajax.

The first successful Nike test was during November 1951, intercepting a drone B-17 Flying Fortress. The first type, Nike Ajax (MIM-3), were deployed starting in 1953. The Army initially ordered 1,000 missiles and 60 sets of equipment. They were placed to protect strategic and tactical sites within the US. As a last-line of defense from air attack, they were positioned to protect cities as well as military installations. The missile was deployed first at Fort Meade, Maryland during December 1953. A further 240 launch sites were built up to 1962. They replaced 896 radar-guided anti-aircraft guns, operated by the National Guard or Army to protect certain key sites. This left a handful of 75 mm Skysweeper emplacements as the only anti-aircraft artillery remaining in use by the US. By 1957 the Regular Army AAA units had been replaced by missile battalions. During 1958 the Army National Guard began to replace their guns and adopt the Ajax system.[2]

Each launch site had three parts, separated by at least 1,000 yards (914 m). One part (designated C) of about six acres (24,000 m2) contained the IFC (Integrated Fire Control) radar systems to detect incoming targets (acquisition and target tracking) and direct the missiles (missile tracking), along with the computer systems to plot and direct the intercept. The second part (designated L), around forty acres (160,000 m2), held 1–3 underground missile magazines each serving a group of four launch assemblies and included a safety zone. The site had a crew of 109 officers and men who ran the site continuously. One launcher would be on 15 minutes alert, two on 30 minutes and one on two hour alert. The third part was the administrative area (designated A), which was usually co-located with the IFC and contained the battery headquarters, barracks, mess, recreation hall, and motor pool. The actual configuration of the Nike sites differed depending on geography. Whenever possible the sites were placed on existing military bases or National Guard armories; otherwise land had to be purchased.[2]

The Nike batteries were organized in Defense Areas and placed around population centers and strategic locations such as long-range bomber bases, nuclear plants, and (later) ICBM sites. The Nike sites in a Defense Area formed a circle around these cities and bases. There was no fixed number of Nike batteries in a Defense Area and the actual number of batteries varied from a low of two in the Barksdale AFB Defense Area to a high of 22 in the Chicago Defense Area. In the Continental United States the sites were numbered from 01 to 99 starting at the north and increasing clockwise. The numbers had no relation to actual compass headings, but generally Nike sites numbered 01 to 25 were to the northeast and east, those numbered 26 to 50 were to the southeast and south, those numbered 51 to 75 were to the southwest and west, and those numbered 76 to 99 were to the northwest and north. The Defense Areas in the Continental United States were identified by a one- or two-letter code which were related to the city name. Thus those Nike sites starting with C were in the Chicago Defense Area, those starting with HM were in the Homestead AFB/Miami Defense Area, those starting with NY were in the New York Defense Area, and so forth. As an example Nike Site SF-88L refers to the launcher area (L) of the battery located in the northwestern part (88) of the San Francisco Defense Area (SF).[2]

During the early-to-mid-1960s the Nike Ajax batteries were upgraded to the Hercules system. The new missiles had greater range and destructive power, so about half as many batteries provided the same defensive capability. Regular Army batteries were either upgraded to the Hercules system or decommissioned. Army National Guard units continued to use the Ajax system until 1964, when they too upgraded to Hercules. Eventually, the Regular Army units were replaced by the National Guard as a cost-saving measure, since the Guard units could return to their homes when off duty.[2]

A Nike Ajax missile accidentally exploded at a battery in Leonardo, New Jersey on 22 May 1958, killing six soldiers and four civilians. A memorial can be found at Fort Hancock in the Sandy Hook Unit of Gateway National Recreation Area.[2]

Nike Hercules

See main article: MIM-14 Nike-Hercules. Even as Nike Ajax was being tested, work started on Nike-B, later renamed Nike Hercules (MIM-14). It improved speed, range and accuracy, and could intercept ballistic missiles. The Hercules had a range of about 100 miles (160 km), a top speed in excess of 3,000 mph (4,800 km/h) and a maximum altitude of around 150,000 ft[3] (30 km). It had solid fuel boost and sustainer rocket motors. The boost phase was four of the Nike Ajax boosters strapped together. In the 70's some (foreign)users replaced vacuum tube guidance circuits in the missile with more reliable solid-state components but electron tube circuits were still used well into the 80's.[4] The electron tube's resistance to EMP effects over earlier non EMP hardened solid state circuits played a major part in the retention of 'obsolete' technology until hardened circuits were developed.

The missile also had an optional nuclear warhead to improve the ability to defend against mass formations. The W-31 warhead had four variants offering 2, 10, 20 and 30 kiloton yields. The 20 kt version was used in the Hercules system. At sites in the United States the missile almost exclusively carried a nuclear warhead. Sites in foreign nations typically had a mix of high explosive and nuclear warheads. The fire control of the Nike system was also improved with the Hercules and included a surface-to-surface mode which was successfully tested in Alaska. The mode change was accomplished by changing a single plug on the warhead from the "Safe Plug" to "Surface to Air" or "Surface to Surface" [4] and a range setting in the TRR.

The Nike Hercules was deployed starting in June 1958. First deployed to Chicago, 393 Hercules ground systems were manufactured. By 1960 ARADCOM had 88 Hercules batteries and 174 Ajax batteries, defending 23 zones across 30 states. Peak deployment was in 1963 with 134 Hercules batteries not including the US Army Hercules batteries deployed in Germany, Greece, Greenland, Italy, Korea, Okinawa, Taiwan, and Turkey.[4]

In 1961, SAC and the U.S. Army began a joint training mission with benefits for both parties. SAC needed fresh (simulated) targets which the cities ringed by Nike/Hercules sites provided, and the Army needed live targets to acquire and track with their radar. SAC had many Radar Bomb Scoring (RBS) sites across the country which had very similar acquisition and tracking radar, plus similar computerized plotting boards which were used to record the bomber tracks and bomb release points. Airmen from these sites were assigned TDY to Nike sites across the country to train the Nike crews in RBS procedures. The distances from the simulated bomb landing point and the "target" were recorded on paper, measured, encoded, and transmitted to the aircrews. The results of these bomb runs were used to promote or demote air crews. ECM activity also took place between the bombers and the Nike sites. The performance of the NIKE crews improved remarkably with this "live target" practice.

Many Nike Hercules batteries were manned by Army National Guard troops, with a single active Army officer assigned to each battalion to account for the unit's nuclear warheads. The National Guard air defense units shared responsibility for defense of their assigned area with active Army units in the area, and reported to the active Army chain of command. This is the only known instance of Army National Guard units being equipped with operational nuclear weapons.

Nike Zeus

See main article: LIM-49 Nike Zeus. Development continued, producing Improved Nike Hercules and then Nike Zeus A and B. The Zeus was aimed at intercontinental ballistic missiles (ICBMs).[5]

Zeus, with a new 400,000 lbf (1.78 MN) thrust solid-fuel booster, was first test launched during August 1959 and demonstrated a top speed of 8,000 mph (12,875 km/h). The Nike Zeus system utilized the ground-based Zeus Acquisition Radar (ZAR), a significant improvement over the Nike Hercules HIPAR guidance system. Shaped like a pyramid, the ZAR featured a Luneburg lens receiver aerial weighing about 1,000 tons. The first successful intercept of an ICBM by Zeus was in 1962, at Kwajalein in the Marshall Islands. Despite its technological advancements, the Department of Defense terminated Zeus development in 1963. The Zeus system, which cost an estimated $15 billion, still suffered from several technical flaws that were believed to be uneconomical to overcome.[6]

Still, the Army continued to develop an anti-ICBM weapon system referred to as "Nike-X" – that was largely based on the technological advances of the Zeus system. Nike-X featured phased-array radars, computer advances, and a missile tolerant of skin temperatures three times those of the Zeus. In September 1967, the Department of Defense announced the deployment of the LIM-49A Spartan missile system, its major elements drawn from Nike X development.[5]

In March 1969. the Army started the anti-ballistic missile Safeguard Program, which was designed to defend Minuteman ICBMs, and which was also based on the Nike-X system. It became operational in 1975, but was shut down after just three months.[7]

Nike-X

See main article: Nike-X.

Nike-X was a proposed US Army anti-ballistic missile (ABM) system designed to protect major cities in the United States from attacks by the Soviet Union's ICBM fleet. The name referred to its experimental basis, it was intended to be replaced by a more appropriate name when the system was put into production. This never came to pass; the original Nike-X concept was replaced by a much more limited defense system known as the Sentinel program that used some of the same equipment.

Nike-X was a response to the failure of the earlier Nike Zeus system. Zeus had been designed to face a few dozen Soviet ICBMs in the 1950s, and its design would mean it was largely useless by mid-1960s when it would be facing hundreds. It was calculated that a salvo of only four ICBMs would have a 90% chance of hitting the Zeus base, as their radars could only track a few warheads at the same time. Worse, the attacker could use radar reflectors or high-altitude nuclear explosions to obscure the warheads until they were too close to attack, making a single warhead attack highly likely to succeed.

Nike-X addressed these concerns by basing its defense on a very fast, short-range missile known as Sprint. Large numbers would be clustered near potential targets, allowing successful interception right up to the last few seconds of the warhead's re-entry. They would operate below the altitude where decoys or explosions had any effect. Nike-X also used a new radar system that could track hundreds of objects at once, allowing salvoes of many Sprints. It would require dozens of missiles to overwhelm the system. Nike-X considered retaining the longer range Zeus missile, and later developed an extended range version known as Zeus EX. It played a secondary role in the Nike-X system, intended primarily for use in areas outside the Sprint protected regions.

Nike-X required at least one interceptor missile to attack each incoming warhead. As the USSR's missile fleet grew, the cost of implementing Nike-X began to grow as well. Looking for lower-cost options, a number of studies carried out between 1965 and 1967 examined a variety of scenarios where a limited number of interceptors might still be militarily useful. Among these, the I-67 concept suggested building a lightweight defense against very limited attacks. When the Chinese exploded their first H-bomb in 1967, I-67 was promoted as a defense against a Chinese attack, and this system became Sentinel in October. Nike-X development, in its original form, ended.

Production

The figures do not include approximately 1 billion dollars for research and development, paid to Western Electric.[8]

Company Production
cost
Producer
profit
Douglas
subcontract
profit
Western Electric
subcontract profit
Tier 3, subcontractors to Douglas Aircraft
49.3 4.5 3.7 3.3
146.2 9.3 10.4 9.8
others 286.6 23.2 16.3
Tier 2, subcontractors to Western Electric
103 8.3 5.9
others 428.8 42
Tier 1, contractor to the Army
359.3 35.2
Totals
1,373.2 57.3 37.3 77.3

Total cost to Army: 1,545.1

Decommissioning

Soviet development of ICBMs decreased the value of the Nike (aircraft) air defense system. Beginning around 1965, the number of Nike batteries was reduced. Thule air defense was reduced during 1965 and SAC air base defense during 1966, reducing the number of batteries to 112. Budgetary cuts reduced that number to 87 in 1968, and 82 in 1969.

Some small-scale work to use Nike Zeus as an anti-satellite weapon (ASAT) was carried out from 1962 until the project was canceled in favor of the Thor based Program 437 system during 1966.In the end, neither development would enter service. However, the Nike Zeus system did demonstrate a hit to kill capability against ballistic missiles during the early 1960s. See National Missile Defense and anti-ballistic missile systems.

Nike Hercules was included in SALT I discussions as an ABM. Following the treaty signed during 1972, and further budget reduction, almost all Nike sites in the continental United States were deactivated by April 1974. Some units remained active until the later part of that decade in a coastal air defense role.

Specifications

MissileNike AjaxNike HerculesNike Zeus ANike Zeus B (XLIM-49A)Spartan (LIM-49A)
Length10.36abbr=onNaNabbr=on overall
6.41abbr=onNaNabbr=onsecond stage
12.53abbr=onNaNabbr=on overall
8.18abbr=onNaNabbr=on second stage
13.5abbr=onNaNabbr=on14.7abbr=onNaNabbr=on16.8abbr=onNaNabbr=on
Diameter0.3abbr=onNaNabbr=on0.8abbr=onNaNabbr=on booster
0.53abbr=onNaNabbr=on second stage
0.91abbr=onNaNabbr=on0.91abbr=onNaNabbr=on1.09abbr=onNaNabbr=on
Fin span1.22abbr=onNaNabbr=on3.5abbr=onNaNabbr=on booster
1.88abbr=onNaNabbr=on second stage
2.98abbr=onNaNabbr=on2.44abbr=onNaNabbr=on2.98abbr=onNaNabbr=on
Mass1116abbr=onNaNabbr=on at launch
523abbr=onNaNabbr=on second stage
4850abbr=onNaNabbr=on at launch
2505abbr=onNaNabbr=on second stage
4980abbr=onNaNabbr=on10300abbr=onNaNabbr=on13100abbr=onNaNabbr=on
Maximum speedMach 2.25 (ca. 1485 mph true airspeed @ 50k ft; 2390 km/h)Mach 3.65 (ca. 2094 mph true airspeed @ 65k ft; 3877 km/h)Mach 4 > (ca. 2800+ mph; 4,900 km/h arbitrary)
Range40abbr=onNaNabbr=on140km (90miles)320abbr=onNaNabbr=on400abbr=onNaNabbr=on740abbr=onNaNabbr=on
Ceiling21300abbr=onNaNabbr=on45700abbr=onNaNabbr=on?280abbr=onNaNabbr=on560abbr=onNaNabbr=on
First stageSolid-fuel
(59,000 lbf or 263 kN static thrust for 2.5 seconds)
Hercules M42 solid-fueled rocket cluster
(4x M5E1 Nike boosters)
220,000 lbf (978 kN) total
Thiokol TX-135
400,000 lbf (1,800 kN)
Thiokol TX-135
450,000 lbf (2,000 kN)
Thiokol TX-500
500,000 lbf (2,200 kN)
Second stageLiquid-fuel
(2,600 lbf or 11.6 kN static thrust for 21 seconds)
Thiokol M30 solid-fueled rocket
10,000 lbf (44.4 kN)
?Thiokol TX-238Thiokol TX-454
Third stageNoneNoneNoneThiokol TX-239Thiokol TX-239
Warhead conventional3 warheads each surrounded with
2 layers of in (6 mm) hardened steel cubes
Nose: M2: 4.5 lb (2.0 kg) Composition B 12 lb (5.4 kg) total
Mid-body: M3: 92 lb (42 kg) Comp. B, 176.8 lb (80.2 kg) total
Aft: M4: 59 lb (27 kg) Comp B, 121.3 lb (55.0 kg) total
T-45 HE warhead weighed
1106 lb (500 kg) and contained 600 lb (272 kg) of HBX-6
M17 blast-fragmentation
Nuclear warhead onlyNuclear warhead onlyNuclear warhead only
Warhead nuclearConventional warhead onlyW-31 nuclear 20 kt (M-22)W-31 nuclearW50 (400 kt)
thermonuclear
W71 (5 Mt)
thermonuclear

Support vehicles

These trucks and trailers were used with the Nike system.

M254 truck, missile rocket motor, Nike Ajax

M255 truck, body section, Nike Ajax

M256 truck, inert, Nike Ajax

M257 truck, inert, Nike Ajax

M442 truck, guided missile, rocket motor, Nike Hercules

M451 truck, guided missile test set, Nike Hercules

M473 truck, guided missile body section, Nike Hercules

M489 truck, missile nose section, Nike Hercules

M242 trailer, M33 fire control, radar dish van mount, 2-ton,

M243 trailer, M33 fire control, antenna hauler, 2-ton,

M244 trailer, M33 fire control, computer van, 2-ton,

M258 van, radar tracking central

M259 van, guided missile directors trailer

M260 low bed antenna mount

M261 flat bed, guided missile

M262 van, launch control station

M304 van, electronic shop, Nike Ajax

M359 van, electronic repair shop

M382 van, electronic repair shop

M383 van, electronic repair shop

M406 low bed antenna mount

M424 van, guided missile directors trailer

M428 van, guided missile tracking station

M429 dolly, for Nike trailers

M430 dolly, trailer, rear, for Nike trailers

M431 dolly, trailer, front, for Nike trailers

M432 dolly, trailer, rear, for Nike trailers

M529 trailer, low bed, 7-ton, missile, Nike

M564 trailer van, electronic shop, 9-ton,

M565 dolly, trailer, front,

M573 dolly, front, launch control station,

M582 van, shop

M583 van, shop

M584 dolly, trailer, front,

M589 dolly, trailer, front, electronic,

M595 dolly, trailer, front, antenna,

M657 trailer, van radar simulator test station,

M699 dolly trailer, rear,

M802 trailer, electric shop, radar course direct central, Nike Hercules

Deployment

See also: List of Nike missile locations. By 1958, the Army deployed nearly 200 Nike Ajax batteries at 40 "Defense Areas" within the United States (including Alaska and Hawaii) in which Project Nike missiles were deployed. Within each Defense Area, a "Ring of Steel" was developed with a series of Nike Integrated Firing and Launch Sites constructed by the Corps of Engineers.

The deployment was designed to initially supplement and then replace gun batteries deployed around the nation's major urban areas and vital military installations. The defense areas consisted of major cities and selected United States Air Force Strategic Air Command bases which were deemed vital to national defense. The original basing strategy projected a central missile assembly point from which missiles would be taken out to prepared above-ground launch racks ringing the defended area. However, the Army discarded this semimobile concept because the system needed to be ready for instantaneous action to fend off a "surprise attack." Instead, a fixed-site scheme was devised.

Due to geographical factors, the placement of Nike batteries differed at each location. Initially, the planners chose fixed sites well away from the defended area and the Corps of Engineers Real Estate Offices began seeking tracts of land in rural areas. However, Army planners determined that close-in perimeter sites would provide enhanced firepower. Staggering sites between outskirt and close-in locations to urban areas gave defenders a greater defense-in-depth capability.

Each Nike missile battery was divided into two basic parcels: the Battery Control Area and the Launch Area.

The Battery Control Area contained the radar and computer equipment. Housing and administration buildings, including the mess hall, barracks, and recreation facilities, were sometimes located in a third parcel of land. More likely, however, the housing and administration buildings were located at either the Battery Control Area or the Launch Area, depending upon site configuration, obstructions, and the availability of land.

The Launch Area provided for the maintenance, storage, testing, and firing of the Nike missiles. The selection of this area was primarily influenced by the relatively large amount of land required, its suitability to extensive underground construction, and the need to maintain a clear line-of-sight between the missiles in the Launch Area and the missile-tracking-radar in the Battery Control Area.

The first Nike sites featured above-ground launchers. This quickly changed as land restrictions forced the Army to construct space-saving underground magazines. Capable of hosting 12 Nike Ajax missiles, each magazine had an elevator that lifted the missile to the surface in a horizontal position. Once above ground, the missile could be pushedmanually along a railing to a launcher placed parallel to the elevator. Typically, four launchers sat atop the magazine.Near the launchers, a trailer housed the launch control officer and the controls he operated to launch missiles. In addition to the launch control trailer, the launch area contained a generator building with three diesel generators, frequency converters, and missile assembly and maintenance structures.

Because of the larger size of the Nike Hercules, an underground magazine's capacity was reduced to eight missiles. Thus, storage racks, launcher rails, and elevators underwent modification to accept the larger missiles. Two additional features that readily distinguished newly converted sites were the double fence and the kennels housing dogs that patrolled the perimeter between the two fences.

The Nike Hercules was designed to use existing Nike Ajax facilities. With the greater range of the Nike Hercules allowing for wider area coverage, numerous Nike Ajax batteries were permanently deactivated. In addition, sites located furtheraway from target areas were desirable due to the nuclear warheads carried by the missile. Unlike the older Ajax sites, these batteries were placed in locations that optimized the missiles' range and minimized the warhead damage. Nike Hercules batteries at SAC bases and in Hawaii were installed in an outdoor configuration. In Alaska, a unique above-ground shelter configuration was provided for batteries guarding Anchorage and Fairbanks. Local Corps of Engineer Districts supervised the conversion of Nike Ajax batteries and the construction of new Nike Hercules batteries.

Nike missiles remained deployed around strategically important areas within the continental United States until 1974. The Alaskan sites were deactivated in 1978 and Florida sites stood down during the following year. Although the missile left the U.S. inventory, other nations maintained the missiles in their inventories into the early 1990s and sent their soldiers to the United States to conduct live-fire exercises at Fort Bliss, Texas.

Leftover traces of the approximately 265[9] Nike missile bases can still be seen around cities across the country. As the sites were decommissioned they were first offered to federal agencies. Many were already on Army National Guard bases who continued to use the property. Others were offered to state and local governments while others were sold to school districts. The left-overs were offered to private individuals. Thus, many Nike sites are now municipal yards, communications and FAA facilities (the IFC areas), probation camps, and even renovated for use as Airsoft gaming and MilSim training complexes. Several were obliterated and turned into parks. Some are now private residences. Only a few remain intact and preserve the history of the Nike project. There are also a few sites abroad, notably in Germany, Turkey and Greece.

Defense areas within the United States were:

Nike booster motor as sounding rocket stage

The Nike boosters were also used as stages in sounding rockets as they became surplus starting in the 1950s in the following versions:

Survivors

Bases

Missiles

See also

Sources

External links

Notes and References

  1. Book: Kendrick . Gregory . First Line of Defense, Nike Missile Sites in Illinois . 1996 . Rocky Mountain System Support Office, National Park Service . Denver, Colorado . 19–26 . 1st .
  2. Book: Kendrick . Gregory . First Line of Defense, Nike Missile Sites in Illinois . 1996 . Rocky Mountain System Support Office, National Park Service . Denver, Colorado . 31 . 1st .
  3. Book: FM 44-1. U. S. GOVERNMENT PRINTING OFFICE: 1962-650514. 8. 1962-650514. Department of the Army Field Manual 44-1.
  4. Book: Kendrick . Gregory . First Line of Defense, Nike Missile Sites in Illinois . 1996 . Rocky Mountain System Support Office, National Park Service . Denver, Colorado . 32–35 . 1st .
  5. Book: Kendrick . Gregory . First Line of Defense, Nike Missile Sites in Illinois . 1996 . Rocky Mountain System Support Office, National Park Service . Denver, Colorado . 36–38 . 1st .
  6. http://www.flightglobal.com/pdfarchive/view/1962/1962%20-%201337.html "NIKE ZEUS – Seventeen years of growth"
  7. Missile defences have a long history. Bulletin of the Atomic Scientists. Jan 1997. 53. 9 February 2011. 69. Educational Foundation for Nuclear Science, Inc.. 0096-3402.
  8. Book: Pyramiding of Profits and Costs in the Missile Procurement Program . 14 . March 31, 1964 . Committee on Government Operations, United States Senate.
  9. https://web.archive.org/web/20040220061155/http://www.redstone.army.mil/history/nikesite/sites/summary.pdf Summary of Nike Missile Batteries
  10. Corliss 1972 pp. 52-54
  11. Book: Origins of NASA Names. 1976. NASA. 133.
  12. Corliss 1972 pp. 32, 80
  13. Corliss 1972 pp. 24-25
  14. Corliss 1972 pp. 54-24
  15. Corliss 1972 p. 82
  16. Web site: Miscellaneous Nike-Boosted Rockets. 2016-03-03. Parsch. Andreas. Directory of U.S. Military Rockets and Missiles. Appendix 4.
  17. Web site: Nike With Upperstage. 2016-03-03. Krebs. Gunter. Gunter's Space Page. Nike Nike Combinations.
  18. Corliss 1972 pp. 63-64
  19. Web site: Nike. 2016-03-03. Krebs. Gunter. Gunter's Space Page. Nike.
  20. Web site: Nike Missile Site . National Park Service . 2015-08-26.
  21. Web site: NY-56 History . Fort Hancock Nike Association . 2015-08-26.
  22. Web site: HM69 Nike Missile Base . National Park Service . 2015-08-28.
  23. Web site: Everglades National Park Nike Missile Tours . National Park Service . 2015-08-28.
  24. Web site: Nike Zeus Missile - US Space & Rocket Center, Huntsville, AL - Static Aircraft Displays on Waymarking.com. waymarking.com. 2019-01-23.
  25. Web site: Nike Ajax Missile - Webster B. Harrison American Legion Post - Hancock MD - Military Ground Equipment Displays on Waymarking.com. waymarking.com. 2019-01-27.
  26. Nike Hercules-raket met afvuurinstallatie – Zoeken in de collectie – Nationaal Militair Museum. Nmm.nl. Retrieved on 2015-11-08.
  27. News: Former Nike Hercules missile in St. Bonifacius stands as a reminder of the Cold War . 15 April 2021 . Star Tribune . Star Tribune.
  28. http://www.montgomeryschoolsmd.org/schools/rmhs/aboutus/rocket.aspx Richard Montgomery HS – History of the RM Rocket