Proposals and precursors In 1923
Hermann Oberth, considered a father of modern rocketry along with
Robert H. Goddard and
Konstantin Tsiolkovsky, published '''' ("The Rocket into Planetary Space"), which mentioned how a telescope could be propelled into
Earth orbit by a rocket. played a major role in the birth of the Hubble Space Telescope project.|alt= The history of the Hubble Space Telescope can be traced to 1946, to
astronomer Lyman Spitzer's paper "Astronomical advantages of an extraterrestrial observatory". In it, he discussed the two main advantages that a space-based observatory would have over ground-based telescopes. First, the
angular resolution (the smallest separation at which objects can be clearly distinguished) would be limited only by
diffraction, rather than by the turbulence in the atmosphere, which causes stars to twinkle, known to astronomers as
seeing. At that time ground-based telescopes were limited to resolutions of 0.5–1.0
arcseconds, compared to a theoretical diffraction-limited resolution of about 0.05 arcsec for an optical telescope with a
mirror in diameter. Second, a space-based telescope could observe
infrared and ultraviolet light, which are strongly absorbed by the
atmosphere of Earth. In 1962, a report by the U.S.
National Academy of Sciences recommended development of a
space telescope as part of the
space program, and in 1965, Spitzer was appointed as head of a committee given the task of defining scientific objectives for a large space telescope. with a model of the Large Space Telescope that was eventually developed as the Hubble Space Telescope. While listed as a 1966 photo, this design was not the standard until the mid-1970s. Also crucial was the work of
Nancy Grace Roman, the "Mother of Hubble". Well before it became an official
NASA project, she gave public lectures touting the scientific value of the telescope. After it was approved, she became the program scientist, setting up the steering committee in charge of making astronomer needs feasible to implement and writing testimony to
Congress throughout the 1970s to advocate continued funding of the telescope. Her work as project scientist helped set the standards for NASA's operation of large scientific projects. (pictured in 1931), for whom the telescope is named. Space-based astronomy had begun on a very small scale following
World War II, as scientists made use of developments that had taken place in
rocket technology. The first ultraviolet
spectrum of the
Sun was obtained in 1946, and NASA launched the
Orbiting Solar Observatory (OSO) to obtain UV, X-ray, and gamma-ray spectra in 1962. An
orbiting solar telescope was launched in 1962 by the United Kingdom as part of the
Ariel programme, and in 1966 NASA launched the first
Orbiting Astronomical Observatory (OAO) mission. OAO-1's battery failed after three days, terminating the mission. It was followed by
Orbiting Astronomical Observatory 2 (OAO-2), which carried out ultraviolet observations of
stars and
galaxies from its launch in 1968 until 1972, well beyond its original planned lifetime of one year. The OSO and OAO missions demonstrated the important role space-based observations could play in astronomy. In 1968, NASA developed firm plans for a space-based
reflecting telescope with a mirror in diameter, known provisionally as the Large Orbiting Telescope or Large Space Telescope (LST), with a launch slated for 1979. These plans emphasized the need for crewed maintenance missions to the telescope to ensure such a costly program had a lengthy working life, and the concurrent development of plans for the reusable
Space Shuttle indicated that the technology to allow this was soon to become available.
Quest for funding The continuing success of the OAO program encouraged increasingly strong consensus within the astronomical community that the LST should be a major goal. In 1970, NASA established two committees, one to plan the engineering side of the space telescope project, and the other to determine the scientific goals of the mission. Once these had been established, the next hurdle for NASA was to obtain funding for the instrument, which would be far more costly than any Earth-based telescope. The
U.S. Congress questioned many aspects of the proposed budget for the telescope and forced cuts in the budget for the planning stages, which at the time consisted of very detailed studies of potential instruments and hardware for the telescope. In 1974,
public spending cuts led to Congress deleting all funding for the telescope project. working next to Skylab's crewed solar space observatory, 1973 In 1977, then NASA Administrator
James C. Fletcher proposed a token $5million for Hubble in NASA's budget. Then NASA Associate Administrator for Space Science,
Noel Hinners, instead cut all funding for Hubble, gambling that this would galvanize the scientific community into fighting for full funding. As Hinners recalls: The political ploy worked. In response to Hubble being zeroed out of NASA's budget, a nationwide lobbying effort was coordinated among astronomers. Many astronomers met
congressmen and
senators in person, and large-scale letter-writing campaigns were organized. The
National Academy of Sciences published a report emphasizing the need for a space telescope, and eventually, the Senate agreed to half the budget that had originally been approved by Congress. The funding issues led to a reduction in the scale of the project, with the proposed mirror diameter reduced from 3 m to 2.4 m, both to cut costs and to allow a more compact and effective configuration for the telescope hardware. A proposed precursor space telescope to test the systems to be used on the main satellite was dropped, and budgetary concerns also prompted collaboration with the European Space Agency (ESA). ESA agreed to provide funding and supply one of the first generation instruments for the telescope, as well as the
solar cells that would power it, and staff to work on the telescope in the United States, in return for European astronomers being guaranteed at least 15% of the observing time on the telescope. Congress eventually approved funding of $36million for 1978, and the design of the LST began in earnest, aiming for a launch date of 1983. In 1983, the telescope was named after
Edwin Hubble, who confirmed one of the greatest scientific discoveries of the 20th century, made by
Georges Lemaître, that the
universe is
expanding.
Construction and engineering Once the Space Telescope project had been given the go-ahead, work on the program was divided among many institutions.
Marshall Space Flight Center (MSFC) was given responsibility for the design, development, and construction of the telescope, while
Goddard Space Flight Center was given overall control of the scientific instruments and ground-control center for the mission. MSFC commissioned the optics company
Perkin-Elmer to design and build the
optical telescope assembly (OTA) and Fine Guidance Sensors for the space telescope.
Lockheed was commissioned to construct and integrate the spacecraft in which the telescope would be housed.
Optical telescope assembly Optically, the HST is a
Cassegrain reflector of
Ritchey–Chrétien design, as are most large professional telescopes. This design, with two hyperbolic mirrors, is known for good imaging performance over a wide field of view, with the disadvantage that the mirrors have shapes that are hard to fabricate and test. The mirror and optical systems of the telescope determine the final performance, and they were designed to exacting specifications. Optical telescopes typically have mirrors polished to an
accuracy of about a tenth of the
wavelength of
visible light, but the Space Telescope was to be used for observations from the visible through the ultraviolet (shorter wavelengths) and was specified to be
diffraction limited to take full advantage of the space environment. Therefore, its mirror needed to be polished to an accuracy of 10 nanometers, or about 1/65 of the wavelength of red light. On the long wavelength end, the OTA was not designed with optimum infrared performance in mind, e.g. the mirrors are kept at stable (and warm, about 15°C) temperatures by heaters. This limits Hubble's performance as an infrared telescope. The Kodak mirror is now on permanent display at the
National Air and Space Museum. An Itek mirror built as part of the effort is now used in the 2.4 m telescope at the
Magdalena Ridge Observatory. Construction of the Perkin-Elmer mirror began in 1979, starting with a blank manufactured by
Corning from their ultra-low expansion glass. To keep the mirror's weight to a minimum it consisted of top and bottom plates, each thick, sandwiching a
honeycomb lattice. Perkin-Elmer simulated
microgravity by supporting the mirror from the back with 130 rods that exerted varying amounts of force. This ensured the mirror's final shape would be correct and to specification when deployed. Mirror polishing continued until May 1981. NASA reports at the time questioned Perkin-Elmer's managerial structure, and the polishing began to slip behind schedule and over budget. To save money, NASA halted work on the back-up mirror and moved the launch date of the telescope to October 1984. The mirror was completed by the end of 1981; it was washed using of hot,
deionized water and then received a reflective coating of 65nmthick
aluminum and a protective coating of 25nmthick
magnesium fluoride. Doubts continued to be expressed about Perkin-Elmer's competence on a project of this importance, as their budget and timescale for producing the rest of the OTA continued to inflate. In response to a schedule described as "unsettled and changing daily", NASA postponed the launch date of the telescope until April 1985. Perkin-Elmer's schedules continued to slip at a rate of about one month per quarter, and at times delays reached one day for each day of work. NASA was forced to postpone the launch date until March and then September 1986. By this time, the total project budget had risen to $1.175billion.
Spacecraft systems The spacecraft in which the telescope and instruments were to be housed was another major engineering challenge. It would have to withstand frequent passages from direct sunlight into the darkness of Earth's
shadow, which would cause major changes in temperature, while being stable enough to allow extremely accurate pointing of the telescope. A shroud of
multi-layer insulation keeps the temperature within the telescope stable and surrounds a light aluminum shell in which the telescope and instruments sit. Within the shell, a
graphite-epoxy frame keeps the working parts of the telescope firmly aligned. Because graphite composites are
hygroscopic, there was a risk that water vapor absorbed by the truss while in Lockheed's clean room would later be expressed in the vacuum of space; resulting in the telescope's instruments being covered by ice. To reduce that risk, a nitrogen gas purge was performed before launching the telescope into space. As well as electrical power systems, the
Pointing Control System controls HST orientation using five types of sensors (magnetic sensors, optical sensors, and six gyroscopes) and two types of
actuators (
reaction wheels and
magnetic torquers). The DF-224 and its 386 co-processor were replaced by a 25MHz Intel-based 80486 processor system during
Servicing Mission 3A in 1999. The new computer is 20 times faster, with six times more memory, than the
DF-224 it replaced. It increases throughput by moving some computing tasks from the ground to the spacecraft and saves money by allowing the use of modern programming languages. Additionally, some of the science instruments and components had their own embedded microprocessor-based control systems. The MATs (Multiple Access Transponder) components, MAT-1 and MAT-2, use Hughes Aircraft CDP1802CD microprocessors. The
Wide Field and Planetary Camera (WFPC) also used an
RCA 1802 microprocessor (or possibly the older 1801 version). The WFPC-1 was replaced by the
WFPC-2 during Servicing Mission 1 in 1993, which was then replaced by the
Wide Field Camera 3 (WFC3) during Servicing Mission 4 in 2009. The upgrade extended Hubble's capability of seeing deeper into the universe and providing images in three broad regions of the spectrum.
Initial instruments of the Hubble Space Telescope When launched, the HST carried five scientific instruments: the Wide Field and Planetary Camera (WF/PC), Goddard High Resolution Spectrograph (GHRS), High Speed Photometer (HSP), Faint Object Camera (FOC) and the Faint Object Spectrograph (FOS). WF/PC used a radial instrument bay, and the other four instruments were each installed in an axial instrument bay. The wide field camera (WFC) covered a large angular field at the expense of resolution, while the planetary camera (PC) took images at a longer effective
focal length than the WF chips, giving it a greater magnification. The
Goddard High Resolution Spectrograph (GHRS) was a
spectrograph designed to operate in the ultraviolet. It was built by the Goddard Space Flight Center and could achieve a
spectral resolution of 90,000. Also optimized for ultraviolet observations were the FOC and FOS, which were capable of the highest spatial resolution of any instruments on Hubble. Rather than CCDs, these three instruments used
photon-counting
digicons as their detectors. The FOC was constructed by ESA, while the
University of California, San Diego, and
Martin Marietta Corporation built the FOS. HST's guidance system can also be used as a scientific instrument. Its three
Fine Guidance Sensors (FGS) are primarily used to keep the telescope accurately pointed during an observation, but can also be used to carry out extremely accurate
astrometry; measurements accurate to within 0.0003 arcseconds have been achieved.
Ground support The Space Telescope Science Institute (STScI) is responsible for the scientific operation of the telescope and the delivery of data products to astronomers. STScI is operated by the
Association of Universities for Research in Astronomy (AURA) and is physically located in
Baltimore, Maryland on the Homewood campus of
Johns Hopkins University, one of the 39 U.S. universities and seven international affiliates that make up the AURA consortium. STScI was established in 1981 after something of a power struggle between NASA and the scientific community at large. NASA had wanted to keep this function in-house, but scientists wanted it to be based in an
academic establishment. The
Space Telescope European Coordinating Facility (ST-ECF), established at
Garching bei München near
Munich in 1984, provided similar support for European astronomers until 2011, when these activities were moved to the European Space Astronomy Centre. One complex task that falls to STScI is scheduling observations for the telescope. Hubble is in a low-Earth orbit to enable servicing missions, which results in most astronomical targets being
occulted by the Earth for slightly less than half of each orbit. Observations cannot take place when the telescope passes through the
South Atlantic Anomaly due to elevated
radiation levels, and there are also sizable exclusion zones around the Sun (precluding observations of
Mercury), Moon and Earth. The solar avoidance angle is about 50°, to keep sunlight from illuminating any part of the OTA. Earth and Moon avoidance keeps bright light out of the FGSs, and keeps scattered light from entering the instruments. If the FGSs are turned off, the Moon and Earth can be observed. Earth observations were used very early in the program to generate flat-fields for the WFPC1 instrument. There is a so-called continuous viewing zone (CVZ), within roughly 24° of Hubble's
orbital poles, in which targets are not
occulted for long periods. Due to the
precession of the orbit, the location of the CVZ moves slowly over a period of eight weeks. Because the
limb of the Earth is always within about 30° of regions within the CVZ, the brightness of scattered
earthshine may be elevated for long periods during CVZ observations. Hubble orbits in low Earth orbit at an altitude of approximately and an inclination of 28.5°. Following the resumption of shuttle flights, successfully launched the Hubble on April 24, 1990, as part of the STS-31 mission. At launch, NASA had spent approximately $4.7 billion in inflation-adjusted 2010 dollars on the project. Hubble's cumulative costs are estimated to be about $11.3billion in 2015 dollars, which include all subsequent servicing costs, but not ongoing operations, making it the most expensive science mission in NASA history. ==List of Hubble instruments==