#format jsmath = OLD Launch Azimuth = This was an attempt to make a "one thrust" orbital insertion. Sadly, it doesn't work. Please see OrbitInsertion for the two-thrust solution. [[ https://en.wikipedia.org/wiki/Guiana_Space_Centre | Kourou is located approximately 500 kilometres (310 mi) north of the equator, at a latitude of 5°10' ]]. Ariane 5 GTO launch azimuth [[ https://airbusdefenceandspace.com/wp-content/uploads/2016/01/arianeflight-v228.pdf | 80 degrees from north ]]. Is the launch azimuth designed to clear the coast (running NW-SE) for safety reasons? The inclination of the GTO orbit is 0.5° Since launch loop will throw payloads directly into transfer orbits, launch azimuth should be arranged to put the equatorial plane crossing near apogee as far from earth as possible. For logistical convenience and safety, the launch loop west station should be south of the intertropical convergence zone (ITC) in January, and the whole system should be erected when the rain and wind is minimized. A loop with a 2000 kilometer track and 300 kilometer inclines will be 23 degrees west to east. What is the optimum azimuth for injection into a geostationary circular equatorial orbit (42164 km radius), or into a server sky M288 circular equatorial orbit (12789 km radius)? === Equatorial Launch, Two Impulse Hohmann === If we launch from the equator, latitude $ \phi = 0 $ , the best trajectory is a two impulse Hohmann, with the Launch Loop providing launch velocity $ v_L $ at an altitude $ a_L $, radius from the center of the Earth $ r_L = R_E + a_L $. Start with an azimuth angle ( launch angle deflection to the north) of $ \alpha $ = 0 and zero elevation angle, parallel to the earth's surface (or close to parallel). Ignoring second order effects, the launch vehicle will follow an elliptical transfer orbit to an apogee at the destination orbit, and require one velocity change $ \Delta v_d $ to enter the destination orbit. We want to minimize $ \Delta v_d $, because that scales the size of the rocket engine needed at apogee. A Newtonian orbit with a perigee of $ r_L $ and an apogee of $ r_P $ has a semimajor axis $ r_S = { \Large { { r_P + r_L } \over 2 } } $ and an eccentricity $ e = { \Large { { r_P - r_L } \over { r_P + r_L } } } $. Note that $ r_P $ may differ from $ r_D $ if the transfer orbit is not equatorial and coplanar. Let $ \theta $ be the angle from perigee; the elliptical equatorial transfer orbit will intersect the destination orbit where $ \theta = \pi $. The orbit radius is $ r = { \Large { { ( 1 + e ) r_L } \over { 1 + e \cos( \theta ) } } } $. The orbit's characteristic velocity is $\large v_0 = { \Large { \sqrt{ { \mu \over 2 } \left( { 1 \over r_L } + { 1 \over r_P } \right) } } } $. Earth's standard gravitational parameter is $ \mu $ = 3.9860044e14 m³/s². The velocity as a function of angle is $ v = v_0 ( 1 + e \cos( \theta ) $, so perigee velocity (or absolute launch velocity) $ v_L = v_0 ( 1 + e ) $ and apogee velocity $ v_A = v_0 ( 1 - e ) $. The perigee velocity is the exit velocity relative to the loop vector-summed with the Earth rotation velocity at the exit latitude, 7.292115e-5 radians/sec $ \times r_L \cos( \phi ) $. For a loop exit altitude of 120 km, and an exit latitude of 5 degrees south, $ r_L $ = 6498 km and the rotation velocity at that altitude is 472 m/s. ''' ''This will get a drawing later'' ''' .'''x''' is the direction of the perigee at the equator, pointing out of the page, in the equatorial plane. .'''y''' is the direction 90 degrees east of perigee orthogonal to x, pointing right on the page, in the equatorial plane. .'''z''' is north, pointing up on the page, orthogonal to x and y,and the equatorial plane. The planar equatorial orbit has a direction vector of: $\left[\matrix{ r_x \\ r_y \\ r_z }\right] ~ = ~ \left[\matrix{ \cos( \theta ) \\ \sin( \theta ) \\ 0 }\right] { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta ) } } } ~ = ~ { \Large \left[\matrix{ { { (1 + e) r_L \cos( \theta ) } \over { 1 + e \cos( \theta ) } } \\ { { (1 + e) r_L \sin( \theta ) } \over { 1 + e \cos( \theta ) } } \\ 0 }\right] } $ And a velocity vector of: $\left[\matrix{ v_x \\ v_y \\ v_z }\right] ~ = ~ \left[\matrix{ - \sin( \theta ) \\ \cos( \theta ) \\ 0 }\right] { v_0 ( 1 + e \cos( \theta ) ) } ~ = ~ \left[\matrix{ - v_0 ( 1 + e \cos( \theta ) ) \sin( \theta ) \\ v_0 ( 1 + e \cos( \theta ) ) \cos( \theta ) \\ 0 } \right] $ === Rotation by Launch Azimuth and then Launch Latitude === The Launch Loop exit will be in the southern hemisphere at latitude $ \phi $, inclined towards the north, to avoid hurricanes and the intertropical convergence zone. The eastern exit end of the loop can tolerate more weather than the western elevator end, but wind loads determine the area-to-mass scaling and the operating schedule of the loop, so less wind is better. Since the loop is to the south, the equatorial orbit is inclined by the latitude $ \phi $. That will put the perigee well north of the destination equatorial orbital plane. So, we will change the launch azimuth $ \alpha $, turning the loop northward so that the orbit descends towards the equatorial plane near (but sadly, not at) perigee. To compute the new position and velocity vectors, we rotate both components, first rotating around the '''x''' axis by an angle of $ \alpha $ to the north, and then changing the latitude by rotating the around the '''y''' axis by an angle of $ \phi $. Two matrix multiplications in front of the first: $ \left[\matrix{ r_x \\ r_y \\ r_z }\right] ~=~ \left[\matrix{ \cos( \phi ) & 0 & - \sin( \phi ) \\ 0 & 1 & 0 \\ \sin( \phi ) & 0 & \cos( \phi ) }\right] \left[\matrix{ 1 & 0 & 0 \\ 0 & \cos( \alpha ) & -\sin( \alpha ) \\ 0 & \sin( \alpha ) & \cos( \alpha ) }\right] \left[\matrix{ \cos( \theta ) \\ \sin( \theta ) \\ 0 }\right] { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta ) } } } $ $ \left[\matrix{ v_x \\ v_y \\ v_z }\right] ~=~ \left[\matrix{ \cos( \phi ) & 0 & - \sin( \phi ) \\ 0 & 1 & 0 \\ \sin( \phi ) & 0 & \cos( \phi ) }\right] \left[\matrix{ 1 & 0 & 0 \\ 0 & \cos( \alpha ) & -\sin( \alpha ) \\ 0 & \sin( \alpha ) & \cos( \alpha ) }\right] \left[\matrix{ - \sin( \theta ) \\ \cos( \theta ) \\ 0 }\right] { v_0 ( 1 + e \cos( \theta ) ) } $ ---- ==== Reducing the Matrices to a Unit Vector ==== $ \left[\matrix{ r_x \\ r_y \\ r_z }\right] ~=~ \left[\matrix{ \cos( \phi ) & 0 & - \sin( \phi ) \\ 0 & 1 & 0 \\ \sin( \phi ) & 0 & \cos( \phi ) }\right] \left[\matrix{ \cos( \theta ) \\ \cos( \alpha ) \sin( \theta ) \\ \sin( \alpha ) \sin( \theta ) }\right] { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta ) } } } $ $ \left[\matrix{ v_x \\ v_y \\ v_z }\right] ~=~ \left[\matrix{ \cos( \phi ) & 0 & - \sin( \phi ) \\ 0 & 1 & 0 \\ \sin( \phi ) & 0 & \cos( \phi ) }\right] \left[\matrix{ -\sin( \theta ) \\ \cos( \alpha ) \cos( \theta ) \\ \sin( \alpha ) \cos( \theta ) }\right] { v_0 ( 1 + e \cos( \theta ) ) } $ ---- $ \left[\matrix{ r_x \\ r_y \\ r_z }\right] ~=~ \left[\matrix{ \cos( \phi ) \cos( \theta ) - \sin( \phi ) \sin( \alpha ) \sin( \theta ) \\ \cos( \alpha ) \sin( \theta ) \\ \sin( \phi ) \cos( \theta ) + \cos( \phi ) \sin( \alpha ) \sin( \theta ) }\right] { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta ) } } } $ $ \left[\matrix{ v_x \\ v_y \\ v_z }\right] ~=~ \left[\matrix{ -\cos( \phi ) \sin( \theta ) - \sin( \phi ) \sin( \alpha ) \cos( \theta ) \\ \cos( \alpha ) \cos( \theta ) \\ -\sin( \phi ) \sin( \theta ) + \cos( \phi ) \sin( \alpha ) \cos( \theta ) }\right] { v_0 ( 1 + e \cos( \theta ) ) } $ ----- === One delta V to the Destination Orbit === The destination orbit has radius $ r_D $ equal to the vector sum of $ r_x $ and $ r_y $, with $ r_z $ = 0 . That tells us a lot; we know that the bottom term of the distance unit vector is zero: $ 0 ~=~ \sin( \phi ) \cos( \theta ) + \cos( \phi ) \sin( \alpha ) \sin( \theta ) $ and $ r_D ~=~ { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta ) } } } $ Solving the penultimate equation for $ \theta_D $: $ \cos( \phi ) \sin( \alpha ) \sin( \theta_D ) ~=~ - \sin( \phi ) \cos( \theta_D ) $ $ \Large { { \sin( \theta_D ) } \over { \cos( \theta_D ) } } ~=~ - { { \sin( \phi ) } \over { \cos( \phi ) } } { 1 \over \sin( \alpha ) } $ $ \theta_D ~=~ \arctan\left( \Large { { -\tan( \phi ) } \over { \sin( \alpha ) } } \right) $ ... this has two solutions, choose the solution closest to $\pi$ such that $ \cos( \theta_D ) < 0 $ . Now, given $ \theta_D $ and $ r_D $ and $ r_L $ , solve for $ e $: $ e ~=~ { \Large { { r_D - r_L } \over { r_L - \cos( \theta_D ) r_D } } } $ ---- === Target orbit velocity at insertion === If the circular equatorial target orbit has a radius of $ r_D $, then we can easily compute the orbital velocity $ v_D $: $ v_D ~=~ \sqrt{ \Large{ \mu \over r_D } } $ Define $ \delta $ as the angle of the $ r_D $ vector at insertion; remember that '''z''' = 0 : $\left[\matrix{ r_{Dx} \\ r_{Dy} }\right] ~=~ \left[\matrix{ \cos( \delta ) \\ \sin( \delta ) }\right] r_D $ $\left[\matrix{ v_{Dx} \\ v_{Dy} }\right] ~=~ \left[\matrix{ -\sin( \delta ) \\ \cos( \delta ) }\right] v_D $ What is $ \delta $? We know that $\left[\matrix{ r_{Dx} \\ r_{Dy} }\right] ~=~ \left[\matrix{ r_x \\ r_y }\right] $ $ \left[\matrix{ \cos( \delta ) \\ \sin( \delta ) }\right] r_D ~=~ \left[\matrix{ \cos( \phi ) \cos( \theta_D ) - \sin( \phi ) \sin( \alpha ) \sin( \theta_D ) \\ \cos( \alpha ) \sin( \theta_D ) }\right] { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta_D ) } } } $ But we already know that: $ r_D ~=~ { \Large { { (1 + e) r_L } \over { 1 + e \cos( \theta_D ) } } } $ So we can divide both sides to get: $ \left[\matrix{ \cos( \delta_D ) \\ \sin( \delta_D ) }\right] ~=~ \left[\matrix{ \cos( \phi ) \cos( \theta_D ) - \sin( \phi ) \sin( \alpha ) \sin( \theta_D ) \\ \cos( \alpha ) \sin( \theta_D ) }\right] $ Ah! Two unit vectors, so the components of each must match! Equate the y terms: $ \sin( \delta ) ~=~ \cos( \alpha ) \sin( \theta_D ) $ so $ \delta ~=~ \arcsin( ~ \cos( \alpha ) \sin( \theta_D ) ~ ) ~~~~~~ $ Again, there are two solutions for $ \delta $, so choose the solution closest to $\pi $, so that $ \cos( \delta ) < 0 $. And so the velocity change vector $ \Delta V $ is: $ \Delta V ~=~ \left[\matrix{ v_{Dx} \\ v_{Dy} \\ 0 }\right] - \left[\matrix{ v_x \\ v_y \\ v_z }\right] $ $ ~=~ \left[\matrix{ -\sin( \delta ) \\ \cos( \delta ) \\ 0 }\right] v_D ~-~ \left[\matrix{ -\cos( \phi ) \sin( \theta_D ) - \sin( \phi ) \sin( \alpha ) \cos( \theta_D ) \\ \cos( \alpha ) \cos( \theta_D ) \\ -\sin( \phi ) \sin( \theta_D) + \cos( \phi ) \sin( \alpha ) \cos( \theta_D ) }\right] { v_0 ( 1 + e \cos( \theta_D ) ) } $ What a complicated mess! However, starting with gravitational parameter $\mu$, launch loop exit radius $r_L$, destination radius $r_D$, latitude $\phi$, and a guess for launch azimuth $\alpha$, we have already calculated all the terms in the equation: velocities $v_0$ and $v_D$, transfer orbit angle $\theta_D$, transfer orbit eccentricity $e$, and and destination orbit angle $\delta$, so we can compute thrust vector $\Delta V$ and its magnitude (which we hope to minimize). At this point, I punt, and shove all the parameters and calculations into a spreadsheet, then manually tweak the launch azimuth $\alpha$ until I minimize the magnitude of $\Delta V$. I hope a better mathematician can give me a closed form equation for the optimum! MoreLater