Better cohesion.
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launch.ks
22
launch.ks
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@ -6,6 +6,7 @@ run once "lib/rocket".
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run once "lib/util".
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run once "lib/vectors".
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run once "lib/warp".
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run once "maneuvers".
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function launch {
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@ -111,16 +112,8 @@ function launch {
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extend_antennas().
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}
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// Create maneuver node that will circularize the orbit. TODO: create circulize()-function in lib/maneuvers.ks instead
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// NOTE: Potential errors in the inclination are not fixed, since we are most likely going to change our orbit, which will make the inclination change cheaper later on.
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local node is NODE(TIME:SECONDS + ETA:APOAPSIS, 0, 0, 0).
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// Burn magnitude in the prograde direction is the difference between the required velocity to acheive circular orbit at apoapsis altitude and our velocity at apoapsis
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local required_velocity is orbital_velocity_from_ap_pe(APOAPSIS, APOAPSIS, target_orbit_altitude).
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set node:prograde to required_velocity - velocityat(SHIP, TIME:seconds + ETA:apoapsis):orbit:mag.
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add node.
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execute_node().
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// NOTE: Potential errors in the inclination are not fixed since we are most likely going to change our orbit, which will make the inclination change cheaper later on.
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circularize_at_apoapsis().
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print "------------ LAUNCH SEQUENCE COMPLETE ------------".
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@ -129,9 +122,12 @@ function launch {
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function calculate_launch_azimuth {
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//
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// Calculate the launch azimuth; the compass heading we head for when launching to achieve orbit of desired inclination.
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// http://www.orbiterwiki.org/wiki/Launch_Azimuth
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// https://www.princeton.edu/~stengel/MAE342Lecture4.pdf
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// Based on:
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// http://www.orbiterwiki.org/wiki/Launch_Azimuth
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// https://www.princeton.edu/~stengel/MAE342Lecture4.pdf
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//
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parameter target_orbit_inclination.
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parameter target_orbit_altitude. // to compensate for the rotation of the body, we need to know the velocity of the target orbit, which is calculated from its altitude
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parameter launch_site_latitude.
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@ -139,7 +135,7 @@ function calculate_launch_azimuth {
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local inertial_azimuth is arcsin(cos(target_orbit_inclination) / cos(launch_site_latitude)). // azimuth in inertial space, that is, disregarding the rotation of the body
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local equatorial_rotational_velocity is (2 * CONSTANT:PI * BODY:radius) / BODY:rotationperiod.
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local target_orbit_velocity is orbital_velocity_from_ap_pe(target_orbit_altitude, target_orbit_altitude, target_orbit_altitude).
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local target_orbit_velocity is orbital_velocity_circular(target_orbit_altitude).
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local launch_vector_x_component is target_orbit_velocity * sin(inertial_azimuth) - equatorial_rotational_velocity * cos(launch_site_latitude).
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local launch_vector_y_component is target_orbit_velocity * cos(inertial_azimuth).
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@ -52,6 +52,11 @@ function orbital_velocity_from_ap_pe {
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return orbital_velocity(altitude, semi_major_axis(ap, pe)).
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}
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function orbital_velocity_circular {
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parameter altitude.
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return orbital_velocity_from_ap_pe(altitude, altitude, altitude).
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}
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function orbital_eccentricity {
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//
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@ -29,7 +29,7 @@ function execute_node {
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print "=== EXECUTE MANEUVER NODE ===".
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print "Estimated burn duration: " + ROUND(burn_duration, 1) + "s".
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print "Aligning ship with burn vector..".
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print "Aligning ship with burn vector".
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SAS off.
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lock STEERING to node:deltav.
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wait until vang(SHIP:facing:vector, node:deltav) < 0.5.
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@ -21,4 +21,31 @@ function change_orbit {
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print argument_of_periapsis.
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}
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change_orbit().
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function circularize {
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//
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// Circularize orbit at the given target.
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//
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parameter target.
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parameter eta. // eta to target
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local node is NODE(TIME:SECONDS + eta, 0, 0, 0).
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// Prograde burn magnitude is the difference between the required velocity to achieve circular orbit at target's altitude and our actual velocity at the target
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local required_velocity is orbital_velocity_circular(target).
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set node:prograde to required_velocity - velocityat(SHIP, TIME:seconds + eta):orbit:mag.
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add node.
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execute_node(node).
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}
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function circularize_at_apoapsis {
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print "Circularizing at apoapsis".
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return circularize(APOAPSIS, ETA:APOAPSIS).
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}
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function circularize_at_periapsis {
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print "Circularizing at periapsis".
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return circularize(PERIAPSIS, ETA:PERIAPSIS).
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}
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circularize_at_periapsis().
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