Exploring Attitude Control of Satellites & ISS

In summary, according to this article, satellites use attitude control to keep their orientation in space. The ISS does not use tidal locking, instead relying on continuous replacement of fuel to maintain its orientation. This is done by maneuvering the ISS to a torque equilibrium attitude.
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berkeman
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I tried a Google search on this question, and got mixed results. I was curious if satellites (and the ISS) have to burn power to stay pointed at Earth, or if any were able to use passive tidal locking instead. I did find that satellites in geosychronous orbit are less likely to use tidal locking since they are so far away from the Earth, but beyond that the links that I found were ambiguous.

So is a fair portion of the solar panel power in satellites going into keeping the attitude gyro spinning and turning it to maintain the attitude of the satellite? And I did find that the ISS does not use tidal locking; does it have some giant gyro stabilizer somewhere, or does it take continuous replacement of fuel to be able to use its reaction jets to maintain its orientation as it orbits?

Thanks. :smile:
 
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Tidal locking tends to orient the long axis of a satellite toward Earth so pretty sure the ISS has to have some attitude adjustment to keep it oriented "horizontally". I don't know if other satellites need to maintain such a horizontal configuration.

I always assumed ISS used attitude jets.
 
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Found this:

https://www.forbes.com/sites/quora/...station-keep-its-orientation/?sh=50ad57e03a18

Also here:
https://www.quora.com/How-does-the-ISS-keep-its-orientation
(Robert Frost is Flight Engineer at NASA, so he's probably gleaned a few things in the cafeteria.)

"Nominally, attitude control is provided by four control moment gyroscopes (CMGs). Each CMG contains a wheel that is 220 lbs (100 kg). That wheel spins at 6600 rpm, resulting in an angular momentum of 3500 ft-lb-s (4742.5 N-m-s). The basic idea is that if a torque induces a rotation on the ISS, those wheels can rotate about their gimbals to change the angular momentum of the ISS, creating a counter torque. Using CMGs is much more subtle than using thrusters, so microgravity experiments are not impacted. CMGs do have limits, though, so thrusters can assist, if needed. That assistance is needed whenever the torques are large.

To minimize thruster assists, during quiescent operations, we do a type of attitude control called momentum management (MM). This is done by maneuvering the ISS to a torque equilibrium attitude (TEA) that was analyzed by the ground a year or more in advance. This TEA is an attitude that, with meanderings of up to 15 degrees, will result in the gravity torques and atmospheric torques adding up, over an orbit, to close to zero. The CMGs then take up the slack to make that zero.

We often can't be in a TEA during critical operations. For those we need to be in an attitude hold (AH). An example of this is a docking or berthing. Attitude holds are challenging because they require a lot more work, often too much for the CMGs to handle alone, and yet firing thrusters during critical operations can be problematic.

For these operations we design a matrix for the flight rules to ensure safety. For example, we do not allow thrusters to fire whenever the end of the robotic arm is within 2 ft (0.6 m) of the vehicle. The last thing we need is for a thruster firing to shake the arm and cause it to hit the side of a module, puncturing the module. If the timeline indicates the arm will be that close, ADCO (the attitude control flight controller) will inhibit thruster assist.

Dockings and berthings can produce sudden changes in momentum. During these activities we inhibit the entire attitude control system to ensure we do not introduce forces that could damage a docking or berthing mechanism. You might notice, on NASA TV, that the vehicle can get considerably out of attitude at these times.

The attitude control computer (GNC MDM) contains the software that does all of the necessary calculations for attitude control. It takes in the actual attitude and subtracts the commanded attitude to determine the error it needs to correct. It knows the rates of the ISS. That is very sensitive, so sensitive that we can tell when the crew wake up by watching the behavior of the CMGs as the crew start to move around the vehicle. The software also needs a set of user provided parameters such as the vehicle mass properties and inertia tensors. These are located in data slots called CCDBs (controller configuration databases). We have a stockpile of these CCDBs for different vehicle configurations. For example, if a Progress cargo vehicle arrives and docks to the Russian Segment, we will have a CCDB slot designed for that configuration. When it leaves, we will swap to another one."
 
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That's super helpful Dave, thank you. :smile:
 
  • #5
I think we had this as a problem in 8.06. The tidal effect is really, really small.
 
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Vanadium 50 said:
I think we had this as a problem in 8.06. The tidal effect is really, really small.
Sorry, what is 8.06?
 

FAQ: Exploring Attitude Control of Satellites & ISS

What is attitude control for satellites and the ISS?

Attitude control refers to the ability of a satellite or the International Space Station (ISS) to maintain a desired orientation or position in space. This is crucial for their operations and to ensure that they are able to perform their intended tasks effectively.

How is attitude control achieved for satellites and the ISS?

Attitude control for satellites and the ISS is achieved through the use of thrusters, reaction wheels, and gyroscopes. These systems work together to adjust the spacecraft's orientation and maintain stability.

Why is attitude control important for satellites and the ISS?

Attitude control is important for satellites and the ISS because it allows them to maintain a stable position and orientation in space, which is necessary for communication, data collection, and other operations. Without proper attitude control, these spacecraft would not be able to function effectively.

What are some challenges in attitude control for satellites and the ISS?

One of the main challenges in attitude control for satellites and the ISS is dealing with external forces such as solar radiation, gravity, and atmospheric drag. These forces can affect the spacecraft's orientation and require constant adjustments to maintain stability.

How is attitude control for satellites and the ISS tested and monitored?

Attitude control for satellites and the ISS is tested and monitored through ground-based simulations and real-time data monitoring. Engineers also use sensors and telemetry data to track the spacecraft's orientation and make necessary adjustments as needed.

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