Editing Orbit insertion
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===Direct ascent=== | ===Direct ascent=== | ||
| − | + | The simplest way to to fly at a point on the new orbit and accelerate to the [[orbit velocity]] at this point in one powered phase. This is a preferred strategy for rocket stages with engines, which can't be restarted, but causes very high [[gravity losses]]. | |
| − | The simplest way to to fly at a point on the new orbit and accelerate to the [[orbit velocity]] at this point in one powered phase. This is a preferred strategy for rocket stages with engines | ||
===Two-Burn strategy=== | ===Two-Burn strategy=== | ||
[[Image:2burnOrbitIns.png|thumb|right|100px|Two-burn orbit insertion]] | [[Image:2burnOrbitIns.png|thumb|right|100px|Two-burn orbit insertion]] | ||
For reducing gravity losses, one way is to aim for inserting into a nearly stable orbit just above the obstacles (for example 130 km for earth or 15 km on the moon), which has its apogee at a point of the target orbit. A second burn matches the velocity vector to the orbit velocity of the target orbit. | For reducing gravity losses, one way is to aim for inserting into a nearly stable orbit just above the obstacles (for example 130 km for earth or 15 km on the moon), which has its apogee at a point of the target orbit. A second burn matches the velocity vector to the orbit velocity of the target orbit. | ||
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