Difference between revisions of "Lunar Reconnaissance Orbiter (BrianJ add-on)"
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At T-5 seconds, engine ignition will happen, and the hold down clamps release at T-0. | At T-5 seconds, engine ignition will happen, and the hold down clamps release at T-0. | ||
− | The Atlas V-401 1st stage autopilot will continue until 1st stage seperation.It can be disengaged by Pressing '''p''' again, but | + | The Atlas V-401 1st stage autopilot will continue until 1st stage seperation.It can be disengaged by Pressing '''p''' again, but this is not recommended. |
<nowiki>10 seconds after 1st stage separation, press the</nowiki> '''p''' <nowiki>key again.</nowiki> | <nowiki>10 seconds after 1st stage separation, press the</nowiki> '''p''' <nowiki>key again.</nowiki> |
Revision as of 13:41, 7 September 2008
Overview
The Lunar Reconnaissance Orbiter (LRO) is the first mission in NASA's planned return to the moon. LRO will launch 2nd March, 2009, with the objectives to finding safe landing sites, locate potential resources, characterize the radiation environment and test new technology.
The return to the moon will enable the pursuit of scientific activities that address our fundamental questions about the history of Earth, the solar system and the universe -- and about our place in them. It will allow us to test technologies, systems, flight operation and exploration techniques to reduce the risk and increase the productivity of future missions to Mars and beyond. It will also expand Earth's economic sphere to conduct lunar activities with benefits to life on our home planet.
LRO is an unmanned mission to create the comprehensive atlas of the moon's features and resources necessary to design and build a lunar outpost. LRO focuses on the selection of safe landing sites, identification of lunar resources and the study of how lunar radiation will affect humans.
After launch, the LCROSS shepherding spacecraft and the Atlas V’s Centaur upper stage rocket will execute a fly-by of the moon and enter into an elongated Earth orbit to position LCROSS for impact on a lunar pole. On final approach, the shepherding spacecraft and Centaur will separate. The Centaur will act as a heavy impactor to create a debris plume that will rise above the lunar surface. Following four minutes behind, the shepherding spacecraft will fly through the debris plume, collecting and relaying data back to Earth before impacting the lunar surface and creating a second debris plume.
The debris plumes are expected to be visible from Earth- and space-based telescopes 10-to-12 inches and larger.
This is a difficult and challenging mission. Experienced orbinauts will enjoy the challenge of targeting the LCROSS to impact the North Pole of the moon, when the LRO spacecraft is overhead. This mission is not recommended for people recently starting to use Orbiter. Familiarity with setting up gravity assist maneuvers in TransX is a required skill.
Mission Objectives
LRO
The objective of the LRO mission is to map the lunar surface in preparation for the return of human missions to the moon, which are planned to occur by 2020.
LCROSS
Earth’s closest neighbor is holding a secret. In 1999, hints of that secret were revealed in the form of concentrated hydrogen signatures detected in permanently shadowed craters at the lunar poles by NASA’s Lunar Prospector. These readings may be an indication of lunar water and could have far-reaching implications as humans expand exploration past low-Earth orbit. The Lunar CRater Observing and Sensing Satellite (LCROSS) mission is seeking a definitive answer.
required add-ons
- Atlas V heavy V2 by Kev33
- IMFD 5.1m
optional add-ons
Procedures
Accuracy of burns in this mission is CRITICAL. During this mission, especially after the TLI burn, we will be using the tools TransX or IMFD to get the DIRECTION of our burns, and using IMFD map to monitor in real time the MAGNITUDE of the DeltaV we are imparting. For this mission, usually the AUTOBURN button is NOT your friend.
You may wish to edit your config/Moon.cfg file and change the LAN line to
LAN = 2.2483 ; ascending node of equator - CHECK!
This will ensure a more accurate simulation.
Launch
Fire up the 01 - AV020 LRO launch scenario in the LRO scenarios folder This is a night launch so visibility is poor until after the TLI burn. The scenario starts at UTC 03/02/2009 05:25:00. Launch time is UTC 05:26:27. The default camera view is Ground Observer. You have just over a minute to set up the camera to your personal preference.
At UTC 05:26:17 press the p key to start the launch countdown and 1st stage auto-pilot.
At T-5 seconds, engine ignition will happen, and the hold down clamps release at T-0. The Atlas V-401 1st stage autopilot will continue until 1st stage seperation.It can be disengaged by Pressing p again, but this is not recommended.
10 seconds after 1st stage separation, press the p key again.
This will ignite the 2nd stage Centaur engine, and engage the 2nd stage autopilot which will put the vehicle in a circular 185km parking orbit. Pressing p again will disengage the 2nd stage autopilot.
Shortly after 2nd stage ignition, the fairing will be automatically jettisoned, and the LRO/LCROSS spacecraft will be exposed.
TLI
After SECO, while established in the 185km parking orbit, set the Left MFD to IMFD.
Also, click the HUD button in the right orbit MFD so that your HUD is set to orbit reference Earth
IMFD Configuration set-up
Click MNU, then Configuration. Click Nxt, then + to change the Mission timer to MJD mode. Click Nxt ten times to hightlight Parking Orbit Alt. Click Set, and set this to 185k
Establishing the TLI burn
Click MNU, then Course. Target Intercept should be highlighted. If not, click Nxt until it is. Click Set Click Tgt and enter Moon Click Nxt so that the Tej parameter is highlighbted. Click + or - repeately until the dV parameter reaches a minimum. This should be about 3.13k Click Pg, then BV, then AB
Sit back and wait for the burn. You may wish to use time acceleration to get close to the burn time, but set it back to 1x acceleration once you get close.
Note for Brian: It may be possible to use an offset in IMFD to target a polar orbit in the TLI. I think AMSO does something like this. It might be worth checking out, but it may make the LCROSS targeting harder.
When the TLI burn is complete, click on the BV button to restore the main IMFD Course target intercept screen
Do not jettison LRO yet
Lunar targeting/LRO
When you reach 32M altitude above the Earth, a piece of orbital debris will puncture the fuel tank of the centaur and drain all of its fuel. It is critical that you get your targeting done for both LRO and LCROSS before this time, as once that happens, your deltaV budget is severely limited.
At about 21M altitude above the earth, select TransX in the Right MFD.
Click on the -- button until the target is Moon Click VW once so the View is Manoevre
Select TransX also in the Left MFD.
In the Left MFD click FWD, then VW, so that the view is 'Encounter' In the Right MFD click ++ so Manoevre mode is On Click VAR 5 times so that Ch. Plane vel. is displayed Click ADJ so that Medium adjustment mode is entered. Click -- until the Min Alt. parameter in the Left MFD is over 50k
Our goal here is to end up with an Inclination parameter in the left MFD as close as possible to 90 degrees, and the Min Alt. parameter as close as possible to 50k.
In the Right MFD click VAR 3 times so that Prograde Vel is selected. Click on ADJ 3 times for Super adjustment mode. Click on ++ or -- until Min Alt. is close to 50k and Inclination is close to 90 degrees in the Left MFD.
Keep repeating these adjustments, using finer adjustment modes until you get as close as possible to the required parameters. Work quickly though, as the orbital debris is getting closer and we still have to target the LCROSS spacecraft.
In the Right MFD click VW to get Target view Use rotation mode to get the cross as close as possible to the center of the target. Do NOT make the burn yet
Use the planetarium view F9 key to make sure you are pointed in a generally northerly direction (towards Polaris + or - 30 degrees or so) If you are pointed in a southerly direction, the transx targeting will have to be re-done using ++ Ch. plane vel. instead of --
Set the Left MFD to IMFD.
Press the MNU button and select Map mode. Press the TGT button and enter Moon Press the Sel button until Ref Moon is displayed.
Watch the PeA parameter as you make a low dV burn with the Centaur engine Ctrl-numpad + When the Pea gets to +50k, STOP the burn with the numpad * key. As it gets close you may with to use translation mode and the numpad-6 key. There is no reverse translation. Don't overshoot by very much, if at all. Some dV will be added by LRO jettison which we will have to correct later.
Press the j key to jettison LRO.
On the Right MFD click VW twice to get back to Maneuver view Click VAR until Maneuver Mode is displayed. Click ++ to turn Maneuver mode Off
Lunar targeting/LCROSS
- Swingby of moon is passive (no thrusting)
- 81 days in post-swingby cruise orbit
- Current baseline is 3-month trajectory with south pole impact
- Two revolutions in high ecliptic inclination (~50 deg), 40-day period Earth orbit
After the LRO is jettisoned, swing the Centaur around 180 degrees. Use the finely graduated scale on the hud, or Attitude MFD to do this. When the Centaur is pointed 180 degrees from where it was when you made the LRO targeting burn, make another small burn, again watching IMFD map so that the final PeA is about 2M on the opposite side of the moon. Select IMFD on the right MFD
Click MNU, then Course. Click NXT 4 times so that Delta Velocity is highlighted. Click Set. Click on TGT and enter Moon as the target. Click Nxt 5 times so that dVf is highlighted. Click Set and enter 0.
In the Left MFD click PG then Plan. The green line of our orbit should turn blue. In the Right MFD click + repeatedly. The RIn parameter in the Left MFD should increase. If not, Click - until it does. Also watch the PeA parameter. Do not let it go negative.
When PeA gets too low, click Nxt on the Right MFD so that dVp is highlighted. Click - until PeA in the Left MFD is back to around 2M. Setting Adj to 10x may be necessary, but return it to 1x when finished.
Keep repeating these adjustments until Rin is close to 90 degrees and PeA is close to 2M. This is just a ball bark "rough in" to make our transx tageting easier. The numbers do not have to be exact. Work quickly though. Liberal use of the Pause function is encouraged.
In the Right MFD, click Pg, then BV.
Use rotation mode to align the cross in the center of the target and then select translation mode and use CTRL-numpad +' to burn until BT is close to 0. AutoBurn is not recommended.
Once this is done, in the Left MFD click PG, then Plan, so the orbit line turns green again.
Select Transx in both MFD's.Select moon as the target in the right MFD, as in the LRO targeting.
Click the FWD button for stage 2, make sure the view is Setup and select the target as Escape. Click the FWD button again for stage 3, and select the target as Moon Click the VW button for Sling Direct view. On the Left MFD, click the FWD button for stage 2, if not already there. Click the VW button for slingshot view, if not already there.
There will be a green line extending from the center of the moon to hopefully past the edge. This is an edge-on view of our current approach to the moon. We need to fine tune this approach to give us a lunar gravity assist which will result in a highly inclined orbit around the earth with a period of 40 days
On the Right MFD, click the VAR button twice to bring up the Inc. angle parameter Click on -- several times until the dotted yellow orbit is about the same size as the solid green line. It does not have to be superimposed in the same place, but of a similar diameter.
On the Left MFD the dotted yellow line should be on the same side (more or less) of the moon as the green line. If it is on the opposite side, click on the ++ button until it is on the same side.
On the Right MFD, click on VAR four times until the outward angle parameter is shown. Adjust this parameter, and the Inc. angle parameter until the dotted line is superimposed on the solid green line in the slingshot view.
This is our current trajectory. Now we need to adjust the trajectory to impact the moon in 2 orbits with a 40 day period.
On the Right MFD, click VW so that the setup view is shown Click VAR 3 times so that Orbits to Icept is shown Click ++ 4 times so that the Orbits to Icept parameter is 2.0
Now we must figure out what our Enc. MJD should be. Take the current MJD and add 85 to it. (5 days to reach the moon, then 2 orbits of 40 days each.) For the Feb 28 (UTC) launch this would be 54890 + 85 = 54975. This is the Enc. MJD we will be shooting for.
Click VW again in the right MFD to get back to sling direct view. Adjust the Inc Angle to get as close as possible to the desired MJD. Click VAR so that Outward angle is displayed. Click ADJ twice so that the increment is Fine Adjust Outward angle to get the Cl. App. as close as possible.
My current solution is Inc Angle of -115.18 degrees and Outward angle of -47.54. Enc MJD is 54978.5013, and Cl. App is 1.747M
Your Mileage may vary.
Once a solution has been reached, click BCK twice on the Right MFD. The View should be Maneuver and Maneuver mode should be off. Click ++ to turn Maneuver mode on Adjust Prograde Vel. and Ch. Plane vel. until the dotted yellow line on the Left MFD lines up with the solid green line. R. Inc should be as close as possible to 0, and Pe Ratio should be as close as possible to 1.000. Once this is done, click VW in the right MFD to get to target view. Use rotational thrusters to get the cross in the middle of the target and burn until Rel.V is as close to 0 as possible. Click VW twice to get to maneuver view, Click VAR to get to Maneuver mode and turn it off. Look at the Left MFD to see how you did. Additional corrections may be done as you get closer to the moon.
Mid course correction/LRO
Switch focus back to LRO.
Press the k key to deploy the LRO solar panels Once the panels have fully unfolded, and rotated to face the sun, press the g key to deploy the antenna
In the Left MFD select IMFD, click on MNU and select Map. Make sure TgT is Moon, and click Sel until Ref is Moon.
Wait until PeT is about 350k
Select IMFD in the Right MFD
Click on MNU, then Course. Click Nxt 4 times until Delta Velocity is highlighted, then click Set. Click Nxt 5 times until dVf is highlighted, click Set and enter 0. Click on TgT and enter Moon. In the Left MFD, click Pg, then Plan so that the green line turns blue. In the right MFD adjust dVp and dVf so that RIn and PeA in the left MFD are as close as possible to 90 degrees and 50k respectively When these adjustments are finished, click PG,BV, then AB in the right MFD. When the burn completes, click Plan in the left MFD so the blue line returns to green.
Repeat these adjustments as necessary as you get closer to the moon.
Course correction/LCROSS
Switch focus to AV020 Centaur. Select TranxX in both left and right MFDs
In the right MFD, click ++ to turn Maneuvre mode On. Adjust Prograde vel and Ch. plane vel so that on the Left MFD R. Inc is as close as possible to 0, and Pe Ratio is as close as possible to 1.0 Click VW on the right MFD for Target view. Use rotational thrusters to get the cross as close to the center of the target as possible. Press M to enable the dummy main engine, and use the numpad-+ key to burn the engine. Reduce the Rel V to as close to 0 as possible.
As an alternative to using the dummy main engine, after the Centaur is targeted with rotational thrusters, you can rotate the Centaur 180 degrees and use the LCROSS main engine numpad-- (minus) This will provide you with graphics of the engine firing in external view. (F1)
Repeat these adjustments as necessary as you get closer to the moon.
orbit insertion/LRO
The LRO main engine is not strong enough to get it into a circular orbit in one try. It will take 3 orbits to achieve a 50km circular orbit. The first burn is critical in that we must avoid a situation where we are "weakly captured" or not captured at all. The orbit eccentricity at the end of our first burn must be 0.8 or less.
When LRO's PeT is about 10k, select imfd in the left MFD, and orbit MFD in the right.
Click on the HUD button on the right MFD. In the left MFD click MNU, then Orbital. Click TgT, then type r.
Note that The burn time to a circular orbit is over 4k seconds (over an hour!). Make sure rotational mode is selected.
At 2k seconds to PeT, select Retrograde mode on the hud. When retrograde attitude is established, de-select retrograde mode. Start the engine by pressing numpad-+ and tap the CTRL key to keep it burning.
Notice that the PeA in the right MFD is decreasing.
Use the numpad 1 and 3 keys to move the attitude closer to what the Orbital imfd mode thinks it should be until the PeA starts increasing.
Keep adjusting the attitude between these points to keep the PeA as close as possible to 50k.
When the Ecc. parameter in the Right MFD is less than 0.8, press the numpad-* key to stop the burn.
Switch focus to AV020Centaur and enjoy the view as it passes by the moon. After the flyby, switch back to LRO and wait until PeT is 1.5k. Press the retrograde button, and de-select it when retrograde attitude is achieved.
Follow the procedure above to make the second burn, keeping PeA as close as possible to 50k, and burn until Eccentricity is below 0.4 Stop the burn when Eccentricity is below 0.4
Go another orbit around the moon, and wait until PeT is 600 seconds.
Assume retrograde attitude again, and then de-select the retrograde autopilot. Burn again, keeping PeA as close as possible to 50k until Eccentricity is as close as possible to 0. Stop the burn immediately when a circular orbit is reached.
LCROSS orbit correction 1
Switch focus back to AV020Centaur and wait until the orbit is farthest from the moon. WARNING Using High values of time acceleration may cause problems for the LRO orbit. It can even kick it out of lunar orbit. It is best to be patient, and check on LRO's orbit once in a while. If it's orbit changes significantly due to time acceleration, fix it with scenario editor. It is now necessary to tune IMFD map for maximum accuracy.
Select IMFD in the left MFD. Click MNU, then Map. Click TgT and type Moon, Click Cnt, and type Earth. Click MOD 3 times. This should give you the Map-config screen. Legs/Frame should be highlighted. Click Set and type 64. Click Nxt, then - twice. Click Nxt twice again, so that Period limit is highlighted, and click + to turn it off. Click Nxt and + to turn Hyper limit off. Click Nxt twice and then + so that Tgt weak Pe is set to No. Click Nxt and + to turn One Pe/Ref off. Click Mod again to return to the map display.
Several orbits should now be shown. Select IMFD in the Right MFD.
In the right MFD click MNU, then Course. Select Delta Velocity mode, then set the target to Moon. Set the dVf parameter to 0. In the left MFD click PG, then Plan. in the right MFD, adjust dVf to get the most deflection of the orbit you can when LCROSS intersects the moon in 1.5 orbits. When this is done, click on Pg, then BV, then AB. When the burn is finished, click Plan in the left MFD to turn the orbit line green again.
LCROSS final moon targeting
LCROSS pole targetinjg
LCROSS LRO targeting
- ~7 hours prior to impact, LCROSS will separate from Centaur upper stage and perform a ~10-minute delay maneuver (~30 m/s) to enable LCROSS to fly through Centaur impact plume
External reference documents
LCROSS Astronomer Workshop
NASA LCROSS page
NASA LRO page
ASU LRO Camera Page
Trajectory Design of the Lunar Impactor Mission Concept
Lunar Reconnaissance Orbiter Spacecraft & Objectives
Mission Design And Operations Considerations For NASA’S LRO