Astronautics

Hubble Space Telescope over Earth (during the STS-109 mission)

Astronautics (alternatively also cosmonautics) is the theory and practice of navigation beyond Earth's atmosphere.

The term astronautics was coined by analogy with aeronautics. Because there is a degree of technical overlap between the two fields, the term aerospace is often used to describe both at once.

As with aeronautics, the restrictions of mass, temperatures, and external forces require that applications in space survive extreme conditions: high-grade vacuum, the radiation bombardment of interplanetary space and the magnetic belts of low Earth orbit. Space launch vehicles must withstand titanic forces, while satellites can experience huge variations in temperature in very brief periods.[1] Extreme constraints on mass cause astronautical engineers to face the constant need to save mass in the design in order to maximize the actual payload that reaches orbit.

History

The early history of astronautics is theoretical: the fundamental mathematics of space travel was established by Isaac Newton in his 1687 treatise Philosophiae Naturalis Principia Mathematica.[2] Other mathematicians, such as Swiss Leonhard Euler and Italian Joseph Louis Lagrange also made essential contributions in the 18th and 19th centuries. In spite of this, astronautics did not become a practical discipline until the mid-20th century. On the other hand, the question of spaceflight puzzled the literary imaginations of such figures as Jules Verne and H. G. Wells. At the beginning of the 20th century, Russian cosmist Konstantin Tsiolkovsky derived the famous rocket equation, the governing equation for a rocket-based propulsion, based on the work of Pedro Paulet, enabling computation of the final velocity of a rocket from the mass of spacecraft (), combined mass of propellant and spacecraft () and exhaust velocity of the propellant ().

In fact this equation was derived earlier by William Moore,[3] a British mathematician who worked at the Royal Military Academy at Woolwich. For more information on the mathematical basis of space travel, see Orbital mechanics.

By the early 1920s, American Robert Goddard was developing liquid-propellant rockets, which would in a few brief decades become a critical component in the designs of such famous rockets as the V-2 and Saturn V.

In 1929, Herman Potočnik set out a plan for a breakthrough into space and the establishment of a permanent human presence there. He conceived a detailed design for a space station, regarded by Russian and American historians of spaceflight to be the first architecture in space [4] and was the first man[5] to recognize the significance of the geosynchronous orbit, on which the station would orbit the Earth. He also made first detailed calculations of this orbit. He described the use of orbiting spacecraft for detailed observation of the ground for peaceful and military purposes, and described how the special conditions of space could be useful for scientific experiments.[6] Potočnik expressed strong doubts of the potentially destructive military use of these fresh discoveries.

Subdisciplines

Although many regard astronautics itself as a rather specialized subject, engineers and scientists working in this area must be knowledgeable in many distinct fields.

Related fields of study

See also

Wikimedia Commons has media related to Astronautics.

References

  1. Understanding Space: An Introduction to Astronautics, Sellers. 2nd Ed. McGraw-Hill (2000)
  2. Fundamentals of Astrodynamics, Bate, Mueller, and White. Dover: New York (1971).
  3. Moore, William; of the Military Academy at Woolwich (1813). A Treatise on the Motion of Rockets. To which is added, An Essay on Naval Gunnery. London: G. and S. Robinson.
  4. "Herman Potocnik Noordung Exhibit". washington.embassy.si. Retrieved 2016-09-03.
  5. "Disposal of Postoperational Geosynchronous Satellites by Phillip Mann". ccar.colorado.edu. Retrieved 2016-09-03.
  6. Walking in Space By David Shayler, p.4
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