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===Catch-up orbit=== | ===Catch-up orbit=== | ||
[[Image:Catch-up_orbit.gif|right|thumb|250px|Example of a catch-up orbit]] | [[Image:Catch-up_orbit.gif|right|thumb|250px|Example of a catch-up orbit]] | ||
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The best launch window for a catch-up orbit is one that places the ship into the same orbital plane as the target but with a significantly lower orbit. The important measure is the difference between the [[semi-major axis]], since the semi-major axis defines the time needed for one revolution around [[Earth]]. | The best launch window for a catch-up orbit is one that places the ship into the same orbital plane as the target but with a significantly lower orbit. The important measure is the difference between the [[semi-major axis]], since the semi-major axis defines the time needed for one revolution around [[Earth]]. | ||
The point at which the spacecraft should leave the (almost circular) catch-up orbit can be calculated using this formula: | The point at which the spacecraft should leave the (almost circular) catch-up orbit can be calculated using this formula: | ||
− | <math>\Delta \varphi = | + | <math>\Delta \varphi = \pi \left [ 1 - ( 2 m - 1 ) \left ( \frac {a}{r_z} \right )^{\frac{3}{2}} \right ] </math> |
where | where | ||
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* <math>r_z</math> - the radius of the target orbit (assumed circular). | * <math>r_z</math> - the radius of the target orbit (assumed circular). | ||
− | When this angle is reached, the chasing spacecraft performs a prograde burn to enter the planned transfer ellipse. This is called the ''intercept burn''. | + | When this angle is reached, the chasing spacecraft performs a prograde burn to enter the planned transfer ellipse. This is called the ''intercept burn''. |
+ | [[Image:Transfer_orbit.gif|right|thumb|250px|Example of a transfer orbit]] | ||
===Rendezvous burn=== | ===Rendezvous burn=== | ||
[[Image:Target first rendezvous.gif|right|thumb|250px|Example of correcting a late arrival of the chaser]] | [[Image:Target first rendezvous.gif|right|thumb|250px|Example of correcting a late arrival of the chaser]] | ||
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When reaching the final apogee pass of the transfer ellipse, all possible errors will usually bring the spacecraft away from its desired course (including errors because the initial orbits have not been perfectly circular). Because of that influences, the next orbit is usually not the final target orbit, but again a less eccentric chasing orbit. The parameters of this orbit can be calculated using the following formula: | When reaching the final apogee pass of the transfer ellipse, all possible errors will usually bring the spacecraft away from its desired course (including errors because the initial orbits have not been perfectly circular). Because of that influences, the next orbit is usually not the final target orbit, but again a less eccentric chasing orbit. The parameters of this orbit can be calculated using the following formula: | ||
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The variable <math>n</math> again describes, how many orbits the chasing craft should wait in the immediate orbit until it meets the target. | The variable <math>n</math> again describes, how many orbits the chasing craft should wait in the immediate orbit until it meets the target. | ||
− | If the time to rendezvous is shorter than one [[orbital period]], its possible to ignore most orbital mechanics and instead assume both craft are in a gravity-free space. That concept gets used very often in various [[radar]] rendezvous guidance systems ([[Gemini]], [[Soyuz]]). Instead of making orbital maneuvers, which would need fast computers to calculate, the chasing spacecraft uses a [[Doppler effect|doppler radar]] to measure the angle, distance and rate of change of the distance. By keeping the angle between [[line of sight]] to the target (measured by the radar) and its own velocity vector constant ([[proportional guidance]]), the chasing spacecraft approaches the target very | + | If the time to rendezvous is shorter than one [[orbital period]], its possible to ignore most orbital mechanics and instead assume both craft are in a gravity-free space. That concept gets used very often in various [[radar]] rendezvous guidance systems ([[Gemini]], [[Soyuz]]). Instead of making orbital maneuvers, which would need fast computers to calculate, the chasing spacecraft uses a [[Doppler effect|doppler radar]] to measure the angle, distance and rate of change of the distance. By keeping the angle between [[line of sight]] to the target (measured by the radar) and its own velocity vector constant ([[proportional guidance]]), the chasing spacecraft approaches the target very effectivly. |
− | When better computers are available, its also possible to solve [[Hills equations]], which describe the movement of an object relative to another in an orbit. | + | When better computers are available, its also possible to solve [[Hills equations]], which describe the movement of an object relative to another in an orbit. Thats more effective in terms of fuel and more accurate, but require better onboard computers, as it requires solving differential equations. |
===Rendezvous=== | ===Rendezvous=== | ||
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* [[Rendezvous MFD]], an [[Orbiter]] implementation of [[Hills equations]] in a MFD. | * [[Rendezvous MFD]], an [[Orbiter]] implementation of [[Hills equations]] in a MFD. | ||
* [[STS guidance MFD]] and [[Soyuz guidance MFD]], two similar MFDs which implement automatic rendezvous and station keeping. | * [[STS guidance MFD]] and [[Soyuz guidance MFD]], two similar MFDs which implement automatic rendezvous and station keeping. | ||
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