(brief introduction to the orbit visualizer/planner included in version 1.0.3 )
The orbit planner can be accessed at any time as long as the spacecraft is moving , and it is outside the atmosphere. Simply press "ORBIT" button (top left ) to enter orbit planner mode .
In the default view, we ll see our spacecraft's orbit represented by a green line . Please note that this line can be closed ( circular/eliptical orbits ) or open ( hyperbolic orbits ), in which the exccentricity is > 1.0
By pressing "BACK" button we will return to normal flight simulation mode.
"ORBIT" button opens up the orbital maneuver control panel
On the left , we can increase / decrease Delta-V
, namely the increase/decrease of speed due to the orbital burn . It increases the altitude at the point opposite the current orbit position . Delta-T
, i.e. how far in the future would be the orbital burn. When planning orbital burns in the future ( Delta-T > 0 ) , the current spacecraft's position is shown in white , while the spacecraft's future position at the time of burn is shown in pink/red ,Delta-N
, The burn is tilted perpendicular to the orbit's plane ,
The current orbit will still be shown as green .
The orbit after the burn is shown in Yellow .
The total Delta-V required ( and hence constrained by remaining fuel ) can be seen .Orbit ReferenceAs most cellestial objets are orbiting around anothers, a spacecraft -say- in orbit around the Moon is also obviously in orbit around the Earth ,and also in orbit around the Sun. You can toggle the orbital reference by pressing the button with the current reference :3 views of the same spaecraft with different orbital references: Moon Orbit Reference
Earth Orbit Reference
Sun Orbital Reference
Transfer orbitsIn order to travel to a different celestial body , we need to follow a Transfer orbit . The Hohmann Transfer orbit is an elliptical orbit used to transfer between two circular orbits of different radii in the same plane.
The orbits need to be in the same plane. It is always a good idea before attempting a Hohmann transfer orbit to adjust the orbital plane to be the same as the target , and then if possible circularize the orbit , before attempting the transfer.
Example 1: Mars orbit to Phobos
In this example , we start with mission "Mars Orbit ( Low circular mars orbit )
We can see that our orbit lies on a different plane as phobos . In the mobile version of Space Simulator , all natural planets/moons lie on the same elliptic plane (inclination = 0.0 ). So we need to adjust the orbit of the spacecraft to match the one of Phobos.
To match orbital inclinations ( and hence similar orbital planes) , the maneuver should be performed at the point of crossing those planes. (Ascending and descending nodes ). So here, in this example , we need to advance the Delta_T until the position of the spacecraft is in the same plane as the orbital target .
So we advance Delta T until spacecraft is visually on the eclicptic (or the same target orbital plane ) . And then adjust delta N ( Normal burn ) until the orbital inclination gets close to zero ( -1 in this example ). Please note the displayed total DeltaV and fuel requeriments for the burn
By clicking on "APPLY" button we perform the orbital burn , and we will be have now an spacecraft orbiting on a almost circular orbit on the same orbital plane than our target Phobos.
Before advancing further on the hohmann maneuvre , we need to understand the use of "SHOW APO" (show position at Apogee ). By pressing this button , the planets/moons,etc. will be show in red , in the position they will be by the time our spacecraft reaches the apogee of the orbit,
| "Show APO" Disabled . Shows (in grey ) the position of Phobos at the current Time|| "Show APO" Enabled|
Shows (in red ) the position of Phobos by the time the spacecraft will reach Apogee