 TheJupiter-C rocket made its maiden flight in 1956 | |
| Rockets | |
|---|---|
| Maiden flights |  Aerobee AJ10-34Nike-CajunTerrapinJupiter-C R-1UKR-5RDR-5R Kappa 1 |
| Retirements | Aerobee XASR-SC-1Aerobee RTV-A-1aDeaconrockoonNike-Nike-T40-T55R-1ER-1UKR-5RDR-5R |
Preparation for the 18-monthInternational Geophysical Year (IGY), scheduled to begin July 1957, became a truly international endeavor in 1956. The American IGY satellite program,Project Vanguard, saw its first test launch at the end of the year, while theArmy Ballistic Missile Agency testedRedstone-derived rockets, culminating in theJupiter-C capable of orbiting a satellite. The Soviet Union developed the engines and tested vital components for its firstICBM, theR-7 Semyorka, which would fly the USSR's first artificial satellite, "Object D:
Japan developed theKappa 1 sounding rocket with an eye toward an advanced version that would fly during the IGY, and Canada, with the assistance of the United States, established asounding rocket range inChurchill, Manitoba. In Italy, Rome hosted the Seventh International Aeronautical Congress, which saw 400 delegates from the scientific community and representatives of (mostly American) industry gather to discuss the technical aspects of spaceflight.
Both superpowers conducted a multitude of sounding rocket flights, probing the upper atmosphere with increasing sophistication and cadence. In addition, the Soviets completed a series of capsule launches, each with two dog passengers—a prelude to human missions in space.
The primary sounding rocket of the United States for 1956 was theAerobee in a variety of models. Launched mostly (but not exclusively) from sites inNew Mexico, missions were conducted by a myriad of agencies, both military and civilian, to probe and return information about the upper atmosphere. TheUniversity of Michigan utilized theNike-Cajun sounding rocket, launched from theUSS Rushmore in theLabrador Sea, to conductaeronomy research. The Air Force launched itsX-17 rocket a number of times, mostly testingreentry vehicles for ballistic missile use.
The year saw the completion of the second series of Soviet suborbital flights with dogs as payloads. After the completion of the nine-launch series, conducted with variations of theR-1 rocket, the results were published as "Vital Activity of Animals during Rocket Flights into the Upper Atmosphere" in December 1956 at an international conference in Paris. These flights made it clear that advanced animals could survive the rigors of space launch, reentry, and weightlessness. They also tested spacesuits, parachute recovery of space travelers, and radio telemetry.[1]: 21
Also completed this year was the second series ofAcademik flights, which involved 18 sounding rocket launches between 1953 and 1956. These missions returned scientific data oncosmic rays, the atmosphere, the content and temperature of theionosphere as well as information useful to engineers: winds, temperature, pressure and radio wave propagation at high altitudes.[1]: 15, 19
Organized by the Italian rocket society under the auspices of theInternational Astronautical Federation, it was held 17–22 September[2] at thePalazzo dei Congressi, 15 km (9.3 mi) fromRome. 400 delegates from astronautical societies and research institutes, as well as representatives of (mostly American) large industrial interests attended. The first day of the conference and a quarter of the 45 papers read before the conference were directly related to artificial Earth satellites.[3]: 451
Work continued apace onProject Vanguard, the civilian satellite project initiated in fall 1955. Vanguard consisted of a tiny satellite and a rocket launcher, the latter comprising aViking (rocket) first stage mated with two smaller rocket stages. Starting in 1956, John T. Mengel and hisNaval Research Laboratory Tracking and Guiding Branch began designing theMinitrack system, a worldwide network of stations that would receive data on 108MHz broadcast by Vanguard's tiny transmitter. In April 1946, work began on a global optical tracking network as well, whose task would be to locate the satellite in the sky so that Minitrack could maintain continuous tracking. In addition to twelve observation stations around the world, amateurs were also recruited to assist. While it would have been logistically useful to have Minitrack and optical stations at the same site, the two types of stations had different requirements—the radio stations requiring flat ground away from interference, and the visual stations needing clear skies. In the end, onlyWoomera in Australia had a combined tracking station.[4]: 146–150
The first Vanguard test flight took place in the early morning of 8 December 1956 and involved the launch of an unmodified Viking rocket (#13). The purpose ofVanguard TV-0 was to familiarize the Vanguard team with launch operations, and to test the range safety and tracking systems atCape Canaveral's Air Force Missile Test Center (AFMTC). TV-0 reached an altitude of 126.5 mi (203.6 km) and a range of 97.6 mi (157.1 km). 120 seconds into the flight, the rocket ejected a small sphere equipped with a Minitrack transmitter. Its broadcasts were picked up without difficulty by AFMTC's tracking stations before the little device hit theAtlantic Ocean. A post-flight evaluation conducted mid-December determined that the rocket's performance had been "either satisfactory or superior", that rocket-borne instrumentation and telemetry had been "excellent", and that ground coverage of the instrumentation had been "adequate". This successful flight paved the way for Vanguard's first multi-stage launch, scheduled for the following year.[4]: 170–176
In 1956, theArmy Ballistic Missile Agency (ABMA) continued trying to gain support of Project Orbiter, an Army plan to use a slightly modifiedRedstone (a 200 miles (320 km) range surface-to-surface missile developed the prior year)[5] combined with upper stages employing 31Loki solid-propellant rockets to put a 5 lb (2.3 kg) satellite into orbit, which could be tracked optically. Though Orbiter had been officially rejected the year before in favor of Vanguard, ABMA hoped Redstone-Orbiter could still be used as a backup orbital system. Reentry tests that year conducted with the newly developed, Redstone-basedJupiter-C, further strengthened ABMA confidence in their vehicle as an orbital launcher. Though Orbiter remained unapproved, late in the year the Army did authorize production and firing of 12 Jupiter-Cs for nosecone reentry tests. This set the stage for the Jupiter-C to be the de facto backup in the event of Vanguard's failure.[4]: 74, 199–200
Development of anICBM was given paramount importance by the United States government on the heels of a secret report made in February 1955 byJames Rhyne Killian to theNational Security Council on Soviet rocket progress. Not only was the 5,500 km (3,400 mi)-rangeAtlas, America's firstICBM, made the highest-priority project in the nation, butTitan, a more capable ICBM, was authorized for development as well.[6] By late 1956, theConvair-produced Atlas was being configured for launch operations. On 10 October 1956, a non-flying Atlas arrived atCape Canaveral inFlorida, where it was checked for compatibility with the Cape's existing launch facilities. Test flights of the first "Series A" run of missiles would begin in 1957.[7]
With development of the Atlas expected to take some time, theThorIntermediate-range ballistic missile (IRBM), with a range of 2,500 km (1,600 mi), had been authorized in 1955 to be developed and deployed in Europe in just three years. TheDouglas-produced Thor, the first missile to useinertial guidance, had its basic configuration and size frozen in January 1956. Engine testing began in March 1956 with the first engine delivered byRocketdyne in August, by which time theinertial guidance system was finished as well. The same month, warhead data was provided toGeneral Electric, which had been contracted to produce the missile's nose cone. The size of the nose cone was fixed in September. Test launches of the completed missile would take place in 1957.[6]
The US Army'sWernher von Braun-led Guided Missile Development Division team, that had recently developed the Redstone, was working on its own IRBM, dubbed Jupiter in April 1956.United States Secretary of DefenseCharles Wilson authorized this missile in September 1955, to be jointly developed by the Army and theUS Navy. ThePGM-19 Jupiter would have the same range as the Thor, and it was planned to be deployed by 1961.[8]
All of these missiles were ultimately adapted into orbital delivery rockets.[9]: 131–137
Full-scale tests of the RD-108 rocket engines that would power theR-7 Semyorka, the Soviet Union's first ICBM, began in January 1956. That same month,[10]: 137–138 work began in earnest on "Site 1", the launch pad at Ministry of Defense Scientific-Research and Test Firing Range No.5 (NIIP-5), located in theKazakh Soviet Socialist Republic (nowKazakhstan) near theSyr-Darya river.[11]: 308 Completed by the end of May, the platform measured 250 m (820 ft) by 100 m (330 ft) by 45 m (148 ft). An exact duplicate was set up for testing and validation purposes inLeningrad, and a full-scale test version of the R-7 was subjected to wind tests thereon. On 5 October, workers finished the road connecting Site 1 and the living settlement at Site 10, nicknamed Zarya.[10]: 136–137
On 2 February 1956, anR-5MMedium-range ballistic missile (MRBM) was the first rocket to fly carrying a live nuclear warhead.[12] In May and June 1956, three R-5R missiles—R-5Ms with their nuclear payloads replaced with radio control instrument packages—were the first Soviet missiles to be launched with radio guidance. The ground stations developed to control these missiles served as prototypes for those being built to support R-7 operations. A series of ten launches of another R5 variant, the M-5RD, tested other R-7 components including guidance, stabilization, and propellant feed. All of these launches were successful.[10]: 138
On 30 January 1956, the Soviet government approved Resolution #149-88, authorizing "Object D". This was a satellite massing 1,000 kg (2,200 lb) to 1,400 kg (3,100 lb), about a fourth of which would be devoted to scientific instruments. This proposal, created in 1955 by engineerMikhail Tikhonravov, had been endorsed by Soviet leaderNikita Khrushchev upon learning that Object D would outmass the announced American satellite by nearly 1,000 times. Work on the project began in February 1956 with a planned launch date of latter 1957. The design was finalized on 24 July.[1]: 25
By the 1956, it had become clear that the complicated Object D would not be finished in time for a 1957 launch. Thus, in December 1956,OKB-1 headSergei Korolev proposed the development of two simpler satellites: PS, Prosteishy Sputnik, or Preliminary Satellite. The two PS satellites would be simple spheres massing 83.4 kg (184 lb) and equipped solely with a radio antenna. The project was approved by the government on 25 January 1957.[1]: 27
In 1955, Japan developed its first experimental rocket, the 23 cm (9.1 in) long Pencil.[13] With an eye toward developing a sounding rocket that could meet the 60 km (37 mi) to 100 km (62 mi) minimum altitude requirement for the IGY, the Japanese began development of theKappa series of rockets, the last of which would fulfill the IGY height limit. Kappa 1, first in this series, 128 mm in diameter and with an initial acceleration of 25gees,[14] was launched seven times in 1956.[15]
Under the aegis of Canada's Defense Research Board, the United States Army built theChurchill Rocket Research Range 24 km (15 mi) east ofChurchill, Manitoba. Due to its proximity to thenorth magnetic pole, it offered an excellent vantage from which to exploreauroral activity. Sounding rocket launches began in October 1956, and the facility would become the nation's premier upper atmosphere research center.[16]
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 11 January | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 11 January | Successful[12] | |||
| 17 January | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 17 January | Successful[12] | |||
| 20 January | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | Test flight | 20 January | Successful | |||
| Apogee: 132 kilometres (82 mi)[17] | |||||||
| 21 January | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 21 January | Successful[18] | |||
| 21 January | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 21 January | Successful[12] | |||
| 24 January | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 24 January | Successful[18] | |||
| 24 January | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 24 January | Launch failure[18] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 2 February | R-5M | Kapustin Yar | OKB-1 | ||||
| Baykal | MVS | Suborbital | Nuclear weapon test | 2 February | Successful | ||
| First launch of a missile carrying a live nuclear warhead[12] | |||||||
| 6 February | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 6 February | Successful[12] | |||
| 13 February | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 13 February | Successful[18] | |||
| 14 February | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 14 February | Successful[18] | |||
| 16 February | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 16 February | Successful | |||
| Maiden flight of the R-5RD (or M5RD)[12] | |||||||
| 17 February | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 17 February | Successful[19] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 5 March | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | Test flight | 5 March | Successful | |||
| Apogee: 116 kilometres (72 mi)[17] | |||||||
| 7 March | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 7 March | Successful[12] | |||
| 9 March | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 9 March | Successful[19] | |||
| 12 March 21:15 | Aerobee RTV-A-1a | USAF 62 | HollomanLC-A | US Air Force | |||
| AFCRC | Suborbital | Ionospheric | 12 March | Successful | |||
| Apogee: 95 kilometres (59 mi)[20]: 166–167 | |||||||
| 14 March 08:45 | Aerobee RTV-A-1a | USAF 63 | Holloman LC-A | US Air Force | |||
| AFCRC | Suborbital | Ionospheric / Aeronomy | 14 March | Successful | |||
| Apogee: 106 kilometres (66 mi)[20]: 168–169 | |||||||
| 15 March | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 15 March | Successful[12] | |||
| 17 March | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 17 March | Successful[12] | |||
| 23 March | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 23 March | Successful[12] | |||
| 28 March | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 28 March | Successful[18] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 9 April | HJ-Nike | Wallops Island | NACA | ||||
| NACA | Suborbital | Test flight | 9 April | Successful | |||
| Apogee: 10 kilometres (6.2 mi)[21] | |||||||
| 12 April 02:05 | Aerobee RTV-A-1a | USAF 64 | HollomanLC-A | US Air Force | |||
| Sodium Release 3 | AFCRC | Suborbital | Ionospheric / Aeronomy | 12 April | Successful | ||
| Apogee: 106 kilometres (66 mi)[20]: 170–171 | |||||||
| 16 April | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 16 April | Successful[18] | |||
| 17 April | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 17 April | Successful | |||
| Apogee: 100 kilometres (62 mi)[17] | |||||||
| 29 April | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 29 April | Successful[19] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 1 May 22:05 | Aerobee Hi | NRL 39 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Test flight | 1 May | Launch failure | |||
| Apogee: 4 kilometres (2.5 mi), Navy variant designation: RV-N-13a[22] | |||||||
| 8 May | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 8 May | Successful[23] | |||
| 8 May | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 8 May | Successful[19] | |||
| 8 May 14:54 | Aerobee AJ10-34 | USAF 65 | HollomanLC-A | US Air Force | |||
| AFCRC /University of Colorado | Suborbital | Solar UV | 8 May | Successful | |||
| Apogee: 143 kilometres (89 mi), maiden flight of the Aerobee AJ10-34;[20]: 172–173 at apogee, several photographs were taken of the Sun in Lyman-alpha (1215 angstroms) wavelength using lithium fluoride optics. The low resolution pictures revealed "considerably enhanced Lyman a radiation in the active spot and plage areas on the sun at the time of the flight." A spectrogram of the Sun was also taken.[24] | |||||||
| 8 May 15:15 | Aerobee Hi | NRL 42 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Test flight | 8 May | Launch failure | |||
| Apogee: 188 kilometres (117 mi), Navy variant designation: RV-N-13a[22] | |||||||
| 10 May | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 10 May | Successful[23] | |||
| 14 May | R-1E | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Biological | 14 May | Successful | |||
| Carried dogs, all recovered[25] | |||||||
| 16 May | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 16 May | Successful[23] | |||
| 16 May 15:40 | Aerobee Hi | USAF 66 | Holloman LC-A | US Air Force | |||
| AFCRC | Suborbital | Test flight | 16 May | Launch failure | |||
| Apogee: 169 kilometres (105 mi)[20]: 174–175 | |||||||
| 31 May 02:57 | R-1E | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Biological / Solar UV | 31 May | Successful | |||
| Carried dogs Malyshka and Linda,[1]: 23 all recovered[25] | |||||||
| 31 May | R-5R | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | Radio guidance test | 31 May | Successful | |||
| Maiden flight of the R-5R[12] | |||||||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 4 June 14:13 | Aerobee Hi | NRL 46 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Solar UV | 4 June | Launch failure | |||
| Apogee: 58 kilometres (36 mi), Navy variant designation: RV-N-13a[22] | |||||||
| 6 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 6 June | Successful[23] | |||
| 7 June | R-1E | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Biological | 7 June | Successful | |||
| carried dogs Albina and Kozyavka[1]: 23 on final(?) flight of the R-1E; dogs recovered[26] | |||||||
| 7 June | R-5R | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | Radio guidance test | 7 June | Successful[12] | |||
| 7 June | Nike-Nike-T40-T55 | Wallops Island | NACA | ||||
| NACA | Suborbital | REV test | 7 June | Successful | |||
| Apogee: 100 kilometres (62 mi), final flight of the Nike-Nike-T40-T55[27] | |||||||
| 8 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 8 June | Successful[23] | |||
| 12 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 12 June | Successful[23] | |||
| 12 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 12 June | Successful[23] | |||
| 13 June 20:51 | Aerobee AJ10-34 | USAF 67 | HollomanLC-A | US Air Force | |||
| AFCRC /University of Utah | Suborbital | Ionospheric | 13 June | Successful | |||
| Apogee: 137.8 kilometres (85.6 mi)[20]: 176–177 | |||||||
| 14 June | R-1E | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Biological | 14 June | Unknown | |||
| carried dogs Albina and Kozyavka[1]: 23 on final(?) flight of the R-1E (flight not listed on Mark Wade's site—see reference)[26] | |||||||
| 15 June | R-5R | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | Radio guidance test | 15 June | Successful | |||
| Final flight of the R-5R[12] | |||||||
| 18 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 18 June | Successful[23] | |||
| 18 June 20:42 | Aerobee AJ10-34 | USAF 68 | Holloman LC-A | US Air Force | |||
| AFCRC / University of Utah | Suborbital | Ionospheric | 18 June | Successful | |||
| Apogee: 137 kilometres (85 mi)[20]: 178–179 | |||||||
| 20 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 20 June | Successful[23] | |||
| 21 June | R-1UK | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Project T-3 | 21 June | Successful | |||
| Final flight of the R-1UK[23] | |||||||
| 21 June 18:48 | Aerobee AJ10-34 | USAF 69 | Holloman LC-A | US Air Force | |||
| AFCRC / University of Utah | Suborbital | Ionospheric | 21 June | Successful | |||
| Apogee: 146 kilometres (91 mi)[20]: 180–181 | |||||||
| 22 June 19:42 | Aerobee RTV-N-10 | NRL 22 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Ionospheric | 22 June | Launch failure | |||
| Apogee: 5 kilometres (3.1 mi)[22] | |||||||
| 26 June | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | Test flight | 26 June | Successful | |||
| Apogee: 140 kilometres (87 mi)[17] | |||||||
| 26 June 18:26 | Aerobee AJ10-34 | USAF 70 | Holloman LC-A | US Air Force | |||
| AFCRC / University of Utah | Suborbital | Ionospheric | 26 June | Successful | |||
| Apogee: 111 kilometres (69 mi)[20]: 182–183 | |||||||
| 29 June 19:09 | Aerobee Hi | NRL 50 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Ionospheric | 29 June | Successful | |||
| Apogee: 263.7 kilometres (163.9 mi), Navy variant designation: RV-N-13b[22] (Rocket #50); measured electron densities in the ionosphere by sending radio signals on two frequencies (7.75 and 46.5Mhz) and determining how their Doppler shift was affected by the refractive index of the material near the rocket.[28] The results confirmed "the general structure of the daytime ionosphere above White Sands as deduced from previous NRL flights": that "the ionosphere remains dense between the E and F2 regions, with only minor valleys in the electron-density profiles."[29] | |||||||
| 30 June | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 30 June | Successful[18] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 5 July 07:52 | Aerobee RTV-N-10c | NRL 33 | White Sands LC-35 | US Navy | |||
| NRL | Suborbital | Airglow / Aeronomy | 5 July | Successful | |||
| Apogee: 162 kilometres (101 mi)[22] | |||||||
| 6 July 18:00 | Nike-Cajun | AM6.01 | Wallops Island | NACA | |||
| NACA /University of Michigan | Suborbital | Aeronomy | 6 July | Successful | |||
| Apogee: 129 kilometres (80 mi), maiden flight of the Nike-Cajun[30] | |||||||
| 12 July | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 12 July | Successful[19] | |||
| 17 July | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 17 July | Successful | |||
| Apogee: 142 kilometres (88 mi)[17] | |||||||
| 17 July 15:40 | DeaconRockoon | NN5.27 | USS Colonial,Pacific Ocean, southwest ofSan Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 17 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 18 July 15:46 | Deacon Rockoon | NN5.28 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 18 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 19 July 15:21 | Deacon Rockoon | NN5.29 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 19 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 20 July | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 20 July | Launch failure[18] | |||
| 20 July | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 20 July | Successful[12] | |||
| 20 July 19:15 | Deacon Rockoon | NN5.30 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 20 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 21 July 17:18 | Deacon Rockoon | NN5.31 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Aeronomy | 21 July | Launch failure | |||
| Apogee: 11 kilometres (6.8 mi)[31] | |||||||
| 22 July 17:57 | Deacon Rockoon | NN5.32 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 22 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 24 July | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 24 July | Successful[18] | |||
| 24 July | Nike-Cajun | Wallops Island | US Navy | ||||
| HUGO | US Navy | Suborbital | Hurricane Photography / Aeronomy | 24 July | Successful | ||
| Apogee: 112 kilometres (70 mi)[30] | |||||||
| 24 July 14:07 | Deacon Rockoon | NN5.33 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 24 July | Launch failure | |||
| Apogee: 11 kilometres (6.8 mi)[31] | |||||||
| 25 July 15:15 | Deacon Rockoon | NN5.34 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 25 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 26 July | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 26 July | Successful[18] | |||
| 26 July 15:28 | Deacon Rockoon | NN5.35 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 26 July | Successful | |||
| Apogee: 120 kilometres (75 mi)[31] | |||||||
| 27 July | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 27 July | Launch failure | |||
| Apogee: 0 kilometres (0 mi)[17] | |||||||
| 27 July 15:30 | Deacon Rockoon | NN5.36 | USSColonial, Pacific Ocean, southwest of San Diego | US Navy | |||
| NRL | Suborbital | Solar UV / X-ray | 27 July | Successful | |||
| Apogee: 120 kilometres (75 mi), final flight of the Deacon rockoon[31] | |||||||
| 28 July | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 28 July | Successful[18] | |||
| 28 July | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 28 July | Successful[19] | |||
| 28 July | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 28 July | Successful[19] | |||
| 31 July 00:56 | Aerobee AJ10-34 | USAF 71 | HollomanLC-A | US Air Force | |||
| AFCRC | Suborbital | Airglow | 31 July | Successful | |||
| Apogee: 129 kilometres (80 mi)[20]: 184–185 | |||||||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 3 August 12:56 | Aerobee RTV-A-1a | USAF 72 | HollomanLC-A | US Air Force | |||
| AFCRC | Suborbital | Solar UV | 3 August | Launch failure | |||
| Apogee: 2.4 kilometres (1.5 mi), fail safe cutoff at 4.6 seconds[20]: 186–187 | |||||||
| 7 August | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 7 August | Successful[12] | |||
| 8 August 22:00 | Nike-Cajun | AM6.30 | White Sands | US Air Force | |||
| University of Michigan | Suborbital | Aeronomy | 8 August | Successful | |||
| Apogee: 100 kilometres (62 mi)[30] | |||||||
| 9 August 15:53 | Aerobee XASR-SC-1 | SC 34 | White Sands LC-35 | US Army | |||
| SCEL / University of Michigan | Suborbital | Aeronomy | 9 August | Successful | |||
| Apogee: 85.5 kilometres (53.1 mi); carried three bottles for sampling air at apogee: two leaked, one recovered and analyzed.[20]: 255–256 | |||||||
| 9 August 22:47 | Nike-Cajun | OB6.00 | White Sands | US Air Force | |||
| BRL | Suborbital | Aeronomy | 9 August | Successful | |||
| Apogee: 164 kilometres (102 mi)[30] | |||||||
| 10 August | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 10 August | Successful[12] | |||
| 10 August 15:22 | Aerobee XASR-SC-1 | SC 35 | White Sands LC-35 | US Army | |||
| SCEL / University of Michigan | Suborbital | Aeronomy | 10 August | Successful | |||
| Apogee: 85.9 kilometres (53.4 mi), final flight of the Aerobee XASR-SC-1[20]: 257–258 | |||||||
| 18 August | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 18 August | Launch failure | |||
| Apogee: 0 kilometres (0 mi)[17] | |||||||
| 23 August | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC /NACA | Suborbital | REV test | 23 August | Successful | |||
| Apogee: 142 kilometres (88 mi)[17] | |||||||
| 25 August | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 25 August | Successful[12] | |||
| 28 August | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 28 August | Successful | |||
| Apogee: 100 kilometres (62 mi)[17] | |||||||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 8 September | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 8 September | Launch failure | |||
| Apogee: 394 kilometres (245 mi)[17] | |||||||
| 16 September | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 16 September | Successful[12] | |||
| 19 September | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 19 September | Successful[12] | |||
| 20 September 06:45 | Jupiter-C | Cape CanaveralLC-5 | ABMA | ||||
| ABMA | Suborbital | REV test | 20 September | Successful | |||
| Apogee: 1,094 kilometres (680 mi), maiden flight of the Jupiter-C, carried a 39.2 kilograms (86 lb) payload in a three-stage configuration[32] | |||||||
| 21 September | Terrapin | Wallops Island | NACA /NSA | ||||
| University of Maryland | Suborbital | Test flight | 21 September | Launch failure | |||
| Apogee: 16 kilometres (9.9 mi), maiden flight of the Terrapin[33] | |||||||
| 21 September | Terrapin | Wallops Island | NACA / NSA | ||||
| University of Maryland | Suborbital | Test flight | 21 September | Successful | |||
| Apogee: 120 kilometres (75 mi)[33] | |||||||
| 25 September | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 25 September | Successful[12] | |||
| 26 September | R-5RD | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | R-7 component test | 26 September | Successful | |||
| Final flight of the R-5RD[12] | |||||||
| 29 September | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 29 September | Successful[19] | |||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 1 October | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 1 October | Successful | |||
| Apogee: 145 kilometres (90 mi)[17] | |||||||
| 5 October | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 5 October | Successful | |||
| Apogee: 117 kilometres (73 mi)[17] | |||||||
| 11 October | HJ-Nike | Wallops Island | NACA | ||||
| NACA | Suborbital | REV test | 11 October | Successful | |||
| Apogee: 70 kilometres (43 mi)[21] | |||||||
| 13 October | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 13 October | Successful | |||
| Apogee: 102 kilometres (63 mi)[17] | |||||||
| 18 October | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 18 October | Successful | |||
| Apogee: 155 kilometres (96 mi)[17] | |||||||
| 20 October 22:01 | Nike-Cajun | AM6.31 |  Churchill | US Air Force | |||
| University of Michigan | Suborbital | Aeronomy | 20 October | Successful | |||
| Apogee: 113 kilometres (70 mi), first spaceflight launched fromCanadian soil[30] | |||||||
| 23 October 08:40 | Aerobee AJ10-34 | AM2.21 | Churchill | US Army | |||
| SCEL /University of Michigan | Suborbital | Aeronomy | 23 October | Successful | |||
| Apogee: 145 kilometres (90 mi)[22] | |||||||
| 24 October | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 24 October | Successful[18] | |||
| 25 October | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 25 October | Successful[18] | |||
| 25 October | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 25 October | Successful[19] | |||
| 25 October | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 25 October | Successful[19] | |||
| 26 October | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 26 October | Successful[18] | |||
| 25 October | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 25 October | Successful | |||
| Apogee: 124 kilometres (77 mi)[17] | |||||||
| 27 October 21:24 | Nike-Cajun | AM6.08 | USS Rushmore,Atlantic Ocean, nearNew York City | US Air Force / US Navy | |||
| University of Michigan | Suborbital | Aeronomy | 27 October | Successful | |||
| Apogee: 161 kilometres (100 mi)[30] | |||||||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 1 November 12:57 | Aerobee AJ10-34 | USAF 73 | HollomanLC-A | US Air Force | |||
| AFCRC | Suborbital | Aeronomy | 1 November | Successful | |||
| Apogee: 66 kilometres (41 mi)[22] | |||||||
| 2 November 05:39 | Aerobee AJ10-34 | USAF 74 | Holloman LC-A | US Air Force | |||
| Sodium Release 4 | AFCRC | Suborbital | Aeronomy | 2 November | Successful | ||
| Apogee: 146 kilometres (91 mi);[22] Three minutes into flight, starting at 60 km (37 mi) and ending at 140 km (87 mi) altitude, 2 kg (4.4 lb) of sodium metal were ejected in vapor form. At 60 km (37 mi), a yellow glow was easily visible, and a dim persistent trail was photographed. Photometric measurements and simultaneous two-site photograph with Super-Schmidt cameras measured the intensity of the emission all along the 80 km (50 mi) of emission.[34] | |||||||
| 2 November 18:40 | Nike-Cajun | AM6.09 | USS Rushmore, Atlantic Ocean, east ofNewfoundland | US Air Force / US Navy | |||
| University of Michigan | Suborbital | Aeronomy | 2 November | Successful | |||
| Apogee: 131 kilometres (81 mi)[30] | |||||||
| 3 November | R-2 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 3 November | Successful[19] | |||
| 3 November | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 3 November | Successful[12] | |||
| 4 November 18:54 | Nike-Cajun | AM6.10 | USSRushmore,Labrador Sea | US Air Force / US Navy | |||
| University of Michigan | Suborbital | Aeronomy | 4 November | Successful | |||
| Apogee: 162 kilometres (101 mi)[30] | |||||||
| 5 November | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 5 November | Successful | |||
| Apogee: 118 kilometres (73 mi)[17] | |||||||
| 5 November 07:50 | Aerobee Hi | NRL 45 | Churchill | US Navy | |||
| NRL | Suborbital | Auroral | 5 November | Unknown | |||
| Navy variant designation: RV-N-13b; Altitude not reported, possible failure[22] | |||||||
| 7 November 15:02 | Nike-Cajun | AM6.11 | USSRushmore,Davis Strait | US Air Force / US Navy | |||
| University of Michigan | Suborbital | Aeronomy | 7 November | Successful | |||
| Apogee: 169 kilometres (105 mi)[30] | |||||||
| 10 November 15:17 | Nike-Cajun | AM6.12 | USSRushmore, Davis Strait | US Air Force / US Navy | |||
| University of Michigan | Suborbital | Aeronomy | 10 November | Successful | |||
| Apogee: 161 kilometres (100 mi)[30] | |||||||
| 12 November | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 12 November | Successful[18] | |||
| 12 November 11:47 | Aerobee RTV-A-1a | SM1.01 | Churchill | US Army | |||
| Grenades | SCEL / University of Michigan | Suborbital | Aeronomy | 12 November | Successful | ||
| Apogee: 67 kilometres (42 mi)[22] | |||||||
| 13 November | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 13 November | Successful[12] | |||
| 15 November 19:32 | Aerobee Hi | NRL 47 | Churchill | US Navy | |||
| NRL | Suborbital | Ionospheric | 15 November | Successful | |||
| Apogee: 129 kilometres (80 mi), Navy variant designation: RV-N-13b[22] | |||||||
| 16 November | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 16 November | Successful[12] | |||
| 16 November | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 16 November | Successful | |||
| Apogee: 107 kilometres (66 mi)[17] | |||||||
| 17 November 16:48 | Aerobee Hi | NRL 43 | Churchill | US Navy | |||
| NRL | Suborbital | Aeronomy / Solar UV / Solar X-Ray | 17 November | Successful | |||
| Apogee: 209 kilometres (130 mi), Navy variant designation: RV-N-13b[22] | |||||||
| 21 November 05:21 | Aerobee Hi | NRL 48 | Churchill | US Navy | |||
| NRL | Suborbital | Ionospheric / Auroral | 21 November | Successful | |||
| Apogee: 251 kilometres (156 mi), Navy variant designation: RV-N-13c;[22] equipped with a Bennett radio-frequency ion-mass spectrometer, launched "at night, into an overcast which prevented observations of the overhead sky", succeeded by flights carrying identical instruments in February and March 1958.[35] | |||||||
| 23 November | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 23 November | Successful | |||
| Apogee: 143 kilometres (89 mi)[17] | |||||||
| 24 November | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | ABM target | 24 November | Successful[12] | |||
| First R-5 to launch as an anti-ballistic missile target for theV-1000 system[36] | |||||||
| Date and time (UTC) | Rocket | Flight number | Launch site | LSP | |||
|---|---|---|---|---|---|---|---|
| Payload | Operator | Orbit | Function | Decay (UTC) | Outcome | ||
| Remarks | |||||||
| 3 December | X-17 | Cape CanaveralLC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 3 December | Successful | |||
| Apogee: 125 kilometres (78 mi)[17] | |||||||
| 6 December | R-1 | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 6 December | Successful[18] | |||
| 6 December | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | Missile test | 6 December | Successful[12] | |||
| 7 December | Nike-Cajun | Wallops Island | NACA | ||||
| NACA | Suborbital | REV test | 7 December | Successful | |||
| Apogee: 30 kilometres (19 mi)[30] | |||||||
| 8 December 06:03 | Viking (second model) | Cape CanaveralLC-18A | US Navy | ||||
| Vanguard TV-0 | NRL | Suborbital | Test flight | 8 December | Successful | ||
| Apogee: 203.6 kilometres (126.5 mi), firstProject Vanguard test flight using a single-stage Viking (No. 13)[37] | |||||||
| 11 December | X-17 | Cape Canaveral LC-3 | US Air Force | ||||
| ARDC | Suborbital | REV test | 11 December | Successful | |||
| Apogee: 144 kilometres (89 mi)[17] | |||||||
| 12 December | R-5M | Kapustin Yar | OKB-1 | ||||
| OKB-1 | Suborbital | ABM target | 12 December | Successful[12][36] | |||
| 13 December 21:44 | Aerobee Hi | USAF 75 | HollomanLC-A | US Air Force | |||
| AFCRC | Suborbital | Test flight | 13 December | Successful | |||
| Apogee: 193 kilometres (120 mi)[22] | |||||||
| 20 December | A-1 | Kapustin Yar | OKB-1 | ||||
| MVS | Suborbital | Ionospheric | 20 December | Successful[38] | |||
| Country | Launches | Successes | Failures | Partial failures | Unknown | |
|---|---|---|---|---|---|---|
| Soviet Union | 69 | 67 | 2 | 0 | 1 | |
| United States | 76 | 63 | 12 | 0 | 1 | |
| World | 145 | 130 | 14 | 0 | 2 | |
| Rocket | Country | Launches | Successes | Failures | Partial failures | Unknown | Remarks |
|---|---|---|---|---|---|---|---|
| Viking (second model) | United States | 1 | 1 | 0 | 0 | 0 | |
| Aerobee RTV-N-10 | United States | 1 | 0 | 1 | 0 | 0 | |
| Aerobee RTV-N-10c | United States | 1 | 1 | 0 | 0 | 0 | |
| Aerobee Hi (NRL) | United States | 8 | 4 | 3 | 0 | 1 | |
| Aerobee XASR-SC-1 | United States | 2 | 2 | 0 | 0 | 0 | Retired |
| Aerobee RTV-A-1a | United States | 5 | 4 | 1 | 0 | 0 | |
| Aerobee Hi (USAF) | United States | 2 | 1 | 1 | 0 | 0 | |
| Aerobee AJ10-34 | United States | 9 | 9 | 0 | 0 | 0 | Maiden flight |
| Deaconrockoon (NRL) | United States | 10 | 8 | 2 | 0 | 0 | Retired |
| Nike-Nike-T40-T55 | United States | 1 | 1 | 0 | 0 | 0 | Retired |
| Nike-Cajun | United States | 11 | 11 | 0 | 0 | 0 | Maiden flight |
| Terrapin | United States | 2 | 1 | 1 | 0 | 0 | Maiden flight |
| X-17 | United States | 20 | 17 | 3 | 0 | 0 | |
| HJ-Nike | United States | 2 | 2 | 0 | 0 | 0 | |
| Jupiter-C | United States | 1 | 1 | 0 | 0 | 0 | Maiden flight |
| R-1 | Soviet Union | 17 | 15 | 2 | 0 | 0 | |
| A-1 | Soviet Union | 1 | 1 | 0 | 0 | 0 | |
| R-1E | Soviet Union | 4 | 3 | 0 | 0 | 1 | Retired |
| R-1UK | Soviet Union | 10 | 10 | 0 | 0 | 0 | Maiden flight, retired |
| R-2 | Soviet Union | 11 | 11 | 0 | 0 | 0 | |
| R-5M | Soviet Union | 14 | 14 | 0 | 0 | 0 | |
| R-5RD | Soviet Union | 10 | 10 | 0 | 0 | 0 | Maiden flight, retired |
| R-5R | Soviet Union | 3 | 3 | 0 | 0 | 0 | Maiden flight, retired |