Satellite

On the concept of the earth satellite

Satellites are, by extension, all astronomical objects which a celestial body - a star , planet or moon or other - orbit.

Artificial devices that orbit the earth are specifically called earth satellites in German . Artificial satellites that orbit and explore a body other than the earth, on the other hand, are referred to as orbiters , whereby a missile orbiting the sun is sometimes also called a "solar satellite". In contrast, there are the natural satellites of planets, which are also known as moons or satellites and - like the earth's moon  - are treated separately, as well as the natural satellites / satellites of the stars, planets, asteroids and other things. Artificial satellites that come from a park orbit around the earth into interplanetary space can be referred to as “artificial planetoids ”, we speak of space probes . Naturally, this also includes those who then enter orbit as orbiters at the target.

Missiles are only called satellites if they orbit the earth in space . A satellite lacks - even after it has reached its career path - a self-propulsion system, which distinguishes it from a spaceship . Simple brake rockets that lead to a controlled crash are not enough in the technical sense to turn a satellite into a spaceship.

history

After the successful launch of Explorer 1, the project managers hold up a model: William H. Pickering , James A. Van Allen and Wernher von Braun

In 1955, US President Eisenhower commissioned the development of an American earth satellite, whereupon the Soviet Union announced a similar project four days later for propaganda reasons. Nevertheless, the successful launch of the Soviet Sputnik 1 satellite on October 4, 1957 (19:28 GMT, October 5, local time) surprised the world public and led to a real Sputnik shock in the West . Sputnik's radio signals indicated in coded form whether the satellite had been hit by matter. The first US American satellite Explorer 1 followed on February 1, 1958 and provided evidence of the Van Allen radiation belt at the beginning of the exploration of the ionosphere . Even so, the development of satellites was influenced by the Cold War for a long time .

In 2016 the number of known active satellites was already over 1,400. In addition, there are several thousand other artificial objects (disused satellites, parts of rockets and other space debris ) in orbit: In 1996, according to ESA data, around 8,500 pieces of "space debris" are to be found. (from about 10 cm in size). In 2009, the Joint Space Operations Center of the United States Strategic Command knew of over 18,500 man-made celestial bodies.

tasks

Depending on the task of the satellite, a distinction is made between the following types:

Which satellite orbit is best suited in each case depends on the tasks. Observation satellites should fly as low as possible. The orbit of spy satellites is sometimes so low that the friction in the atmosphere limits their lifespan to a few months.

construction

A satellite essentially consists of the scientific, commercial or military payload as well as the satellite bus , which contains the structures and subsystems necessary for their operation. This consists of the primary structure into which the other subsystems are integrated. This includes the energy supply ( solar cells , accumulators ), the temperature control system , the drive system for position and position control (path control) and the on-board computer system for control and data management .

Energy supply system

business

After the satellite has started, its continued operation must be guaranteed. This includes not only on-board control and monitoring systems, but also corresponding ground stations (e.g. Mission Control Center ) that take over ground control, remote control and evaluation or provision of data from the satellites or their payload.

These tasks include:

• Transfer to geostationary orbit
• Railway description
• Orbit change maneuvers
• Compensation of railway disruptions
• Path or position control
• Stabilization
• Thermal control

Speeds

For a near-earth, circular orbit, the first cosmic speed of v ₁ = 7.9 km / s applies .

When starting in an easterly direction, the rotation of the earth contributes a maximum of 0.46 km / s to the orbit speed. However, the earth's rotation is not fully exploited, since the missile is slowed down due to air particles (winds) moving in other directions. A v ₁ of 7.44 km / s can thus suffice for a rocket . In a westerly direction, the share would have to be raised, so almost all satellites are launched in an easterly direction. The circular speed of polar orbits remains unaffected by the rotation of the earth.

If you want to leave the earth's gravitational field , the satellite has to be accelerated to the second cosmic speed of about 11.2 km / s. It corresponds to times the first cosmic speed. ${\ displaystyle {\ sqrt {2}}}$

Observation from the earth

When it comes to observation with the naked eye, this is usually only possible shortly after sunset or shortly before sunrise. This is due to the fact that the satellite in its (not too) high orbit still has to be illuminated by the sun so that it can be seen on the ground (where it is already / still dark) in front of the dark sky; in the middle of the night it also flies in the shade and remains invisible. The orbit must not be too high either, because the distance will make the satellite too small to be visible even when exposed to radiation.

A satellite can be recognized by the high speed at which it moves across the sky; it typically only takes a few minutes to completely fly over the visible part of the sky.

A large object like the ISS can be particularly bright. But even it is rarely seen in our latitudes. This is due to several points that also apply to other satellites:

• The object must have a sufficiently inclined orbit to the equatorial plane so that it even penetrates into our latitudes at all; if the object always circles exactly over the equator, it can only be seen there. The ISS in particular only barely and rarely reaches our latitudes.
• As stated above, the orbit must lead the object to our latitudes at a suitable time around sunset or sunrise. Accordingly, there are websites with date previews, when and for which object the next sightings will be possible.
• The lower the orbit of the object, the larger it appears and the brighter it is visible, but also the shorter it is in the visible field of view and has to hit its own location more precisely.
• The higher the orbit of the object, the smaller and less bright it appears, but it is longer and visible from a larger area.

Trace recordings of satellites and rocket upper stages

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  Mir ( Satellite Catalog Number 16609 =  COSPAR designation 1986-017A)

• 

  Iridium  58
  (25274 = 1998-019C)

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  Resurs 1–3 r
  (23343 = 1994-074B)

• 

  Lacrosse  1 (19671 = 1988-106B) and Cosmos  2263r (22803 = 1993-059B)

Long-term recordings from geostationary satellites

While stars move in the night sky, geostationary satellites are always in the same place. This is how they appear as points on long-term recordings:

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  The American SIGINT satellite USA 207 (2009-047A, Palladium at Night ) and two civil, commercial satellites (Paksat-1 and HellasSat 2)

• 

  SIGINT satellite USA 202 (mentor 4)

• 

  Mentor 4 with his neighbor, the civil telecommunications satellite Thuraya 2

Transport and course

Symbols used:

${\ displaystyle \ gamma}$	:	Gravitational constant	=	6.673 · 10 −11 m 3 / kg · s 2
r	:	Orbit radius or distance between the centers of mass of the earth and the body in orbit	=	6.378 x 10 6 m
M.	:	Mass of the earth	=	5.9722 x 10 24 kg
m	:	Mass of the body in orbit
v	:	Orbital speed of the body in orbit

An earth satellite must be given such a high orbital speed when it is launched that its centrifugal force (or radial force ) is at least equal to its weight .

The centrifugal force is calculated as follows:

${\ displaystyle F_ {r} = {\ frac {m \ cdot v ^ {2}} {r}} \}$.

The force of gravity is calculated as follows:

${\ displaystyle F_ {G} = \ gamma \ cdot {\ frac {m \ cdot M} {r ^ {2}}} \}$.

There must be, after insertion: ${\ displaystyle F_ {r} = F_ {G}}$

${\ displaystyle \ \ {\ frac {m \ cdot v ^ {2}} {r}} = \ gamma \ cdot {\ frac {m \ cdot M} {r ^ {2}}} \}$.

Now you can see that the mass of the body on the circular path has no relevance, since it is omitted in the equation. The orbit speed required for a certain orbit therefore only depends on the orbit height:

${\ displaystyle v ^ {2} = {\ frac {\ gamma \ cdot M} {r}} \}$, It follows: .${\ displaystyle \ v = {\ sqrt {\ frac {\ gamma \ cdot M} {r}}} \}$

With this speed it is possible for a body to keep this orbit on a circular orbit around the earth:

${\ displaystyle v_ {1} = {\ sqrt {\ frac {\ gamma \ cdot M} {r}}} \}$, insert results

${\ displaystyle v_ {1} = {\ sqrt {\ frac {6 {,} 673 \ cdot 10 ^ {- 11} \, \ mathrm {\ tfrac {m ^ {3}} {kg \, s ^ ​​{2 }}} \ cdot 5 {,} 976 \ cdot 10 ^ {24} \, \ mathrm {kg}} {6 {,} 378 \ cdot 10 ^ {6} \, \ mathrm {m}}}} = 7905 {,} 4 \, \ mathrm {\ tfrac {m} {s}} = 28459 {,} 6 \, \ mathrm {\ tfrac {km} {h}} \ approx 7 {,} 9 \, \ mathrm { \ tfrac {km} {s}} \}$.

With the second cosmic speed or escape speed he can leave the gravitational field of the earth. It amounts to:

${\ displaystyle v_ {2} = v_ {1} \ cdot {\ sqrt {2}} = 11 {,} 18 \, \ mathrm {\ tfrac {km} {s}} \}$.

The transport into orbit takes place with the help of rockets , which are designed as step rockets for technical and energetic reasons . The satellite is placed on the top (mostly third) rocket stage and is aerodynamically disguised. It is either shot directly into the orbit or released by another spacecraft . As long as the rocket is working, it runs on what is known as the “active path”. After the rocket motors burn out , the "free flight path" (or passive path) follows.