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Smileyxx
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How can decelerating force would be applied to satellite in order to slow it down?
Smileyxx said:How can decelerating force would be applied to satellite in order to slow it down?
Pkruse said:I've been in the space and aerospace business for a long time, and I've never heard the term "retro-rockets." Every program I've worked called them TVC or TVCS for "thrust vector control system."
Drakkith said:Typically by chemical rockets using on board fuel. However some are allowed to simply decelerate due to friction with the Earth's atmosphere until they burn up on re-entry.
Smileyxx said:Ohhk i get it nw.but i read somewere that if satellite travels too slowly,it will fall down towards the Earth surface or if it goes too fast it will move out to higher orbit.it has something to do with formula v^2=GM/r where G is gravitational constant.can u tell me what's the reason behind it?
Smileyxx said:Ohhk i get it now. but i read somewere that if satellite travels too slowly,it will fall down towards the Earth surface or if it goes too fast it will move out to higher orbit.it has something to do with formula v^2=GM/r where G is gravitational constant.can you tell me what's the reason behind it?
That's odd. The term "thrust vector control system" implies to me something completely different than "retro-rocket" (and even odder to me that you haven't heard it!). Are you sure the term retro-rocket isn't simply an anachronism? A "retro-rocket" would have been a rocket engine with the sole purpose of slowing the spacecraft down for re-entry/landing. In early spacecraft , it would have been an engine dedicated to that purpose. In the space shuttle, though, that task was performed by the multi-purpose OMS engines.Pkruse said:I've been in the space and aerospace business for a long time, and I've never heard the term "retro-rockets." Every program I've worked called them TVC or TVCS for "thrust vector control system."
Retro rockets are used to slow down the movement at that particular time. The major difference is that the TVCS can vary the thrust for any purpose (i.e., changing acceleration, or velocity or even direction). But a retro rocket is the kind that "mainly" decelerates (it can also have directional deceleration, but it is 'deceleration').Pkruse said:I've been in the space and aerospace business for a long time, and I've never heard the term "retro-rockets." Every program I've worked called them TVC or TVCS for "thrust vector control system."
. Yeah i get it. Thanks:)SHISHKABOB said:that formula is for a satellite in a circular orbit, which is a simplification because orbits are actually elliptical
but, what is also says is that the radius of the orbit is *determined* by the velocity of the object (and ofc the mass of what it's orbiting)
so by accelerating and decelerating in the direction of motion, a satellite can change the radius of its orbit.
It's a bit more complicated than that because orbits are elliptical and depending on where you accelerate in the orbit (at the furthest point from the Earth or the closest point; apogee or perigee) you will change your apogee or perigee or something like that.
the basic thing is that if a satellite is at a constant velocity, its orbit will stay the same. If its velocity is changing, then the orbit will change.
Bandersnatch said:Think of when you're throwing a rock. It travels in a ballistic trajectory and then hits the ground. Now imagine you throw it harder. Perhaps hard enough to go beyond the horizon(large guns can do that. For example, in WWI the Germans used one to shell Paris from ~120 km away). As it flies beyond the horizon, it lands farther than it would were the Earth a flat surface. In other words, the curvature of the planet and the ballistic trajectory intersect farther away.
You could imagine throwing a rock hard enough that it would never hit the ground. It's ballistic trajectory would never intersect with the Earth's surface. As the gravity would try to pull the rock down, it would still travel so fast, that it'd keep "missing" the Earth. It's ballistic trajectory would turn into an ellipse - an orbit.
In a way, all ballistic trajectories are parts of elliptic orbits that protrude above Earth's surface.
So, a satellite is just an object like that very fast rock. It constantly falls towards Earth, but it's got just enough sideways velocity to keep on missing it.
Now, if you've got a satellite that's already in orbit, and you decelerate it, then it's orbit might shrink enough to graze the upper atmosphere, slowing it down even more and eventually hitting the ground. You took away enough of it's sideways(aka tangential) velocity that allowed it to keep missing the surface.
If you accelerate it, on the other hand, the ellipse of its orbit will grow larger, taking it further away from the surface of the Earth. With enough extra velocity added, it might escape the Earth's gravitational pull completely.
If you're interested in this topic, I'd recommend playing a bit with the free game called Orbiter( http://orbit.medphys.ucl.ac.uk/ ). It's a great way of getting the hang of the orbital mechanics. It comes with a manual describing the basic orbital manuevers and the physics behind them.
russ_watters said:Are you sure the term retro-rocket isn't simply an anachronism? A "retro-rocket" would have been a rocket engine with the sole purpose of slowing the spacecraft down for re-entry/landing. In early spacecraft , it would have been an engine dedicated to that purpose.
There are several ways to decelerate satellites in orbit. One method is to use thrusters to slow down the satellite's speed. Another option is to deploy drag-inducing devices, such as solar sails or aerobrakes, to increase atmospheric drag and slow the satellite's velocity. Additionally, gravity assists from nearby celestial bodies can also be used to decelerate satellites in orbit.
Decelerating a satellite in orbit will cause its orbit to change. Depending on the method used, the orbit may become more circular or elliptical. The satellite's altitude and inclination may also be affected. It is important to carefully plan and calculate deceleration maneuvers to ensure the satellite remains in a stable and desired orbit.
Yes, there are methods for decelerating satellites without burning fuel. As mentioned before, deploying drag-inducing devices can use atmospheric drag to slow a satellite's velocity. Another option is to use gravity assists from nearby celestial bodies, which do not require the use of fuel. However, these methods may not be as precise or effective as using thrusters.
The amount of time it takes to decelerate a satellite in orbit depends on several factors, including the satellite's mass, velocity, and the method used for deceleration. Generally, it can take several weeks to months for a satellite to reach its desired decelerated orbit.
Decelerating a satellite in orbit carries some risks, as any maneuver in space does. There is always a chance that something could go wrong and the satellite could become damaged or completely lost. Additionally, if the satellite is not decelerated correctly, it could end up in an unstable orbit and potentially collide with other objects in space. Careful planning and precise execution are crucial to mitigate these risks.