- #1
quantumpandabear
- 1
- 0
Hello,
I am an undergrad and am in an introductory level astrophysics course. I have a bit of confusion that I didn't know where to get help from so I made an account here. Please let me know if I miss some common etiquette or something... I don't understand how the slingshot maneuver provides a net gain in velocity. I just spoke with my professor about this, but his terminology left me confused. I understand that the target body for the flyby loses some of its momentum and that the satellite executing the flyby takes some of that velocity. That makes sense to me. What I do not understand is why that same interaction isn't undone after the satellite is adjacent to the body. If the satellite arrives with some V_1 and gains some ΔV from the planet in addition to having its velocity vector rotated some angle, why doesn't the satellite decelerate and the planet accelerate back to its previous velocity? For instance, take the classic example of a satellite with no velocity being passed by a planet executing a 180 degree flyby. From the planets perspective the satellite approaches the planet with the planet's velocity, call it V_1. After the planet passes, the satellite has a velocity of 2V_1 in the same direction of the planet rather than just v_1, because part of the planet's momentum was stolen by the satellite. Why does the kinetic energy of the satellite at the start of the flyby not equal the kinetic energy of the satellite after the flyby? It's as if the planet is capable of losing momentum from the satellite but is unable to take that same momentum back from the satellite.
I've read a lot of explanations and many analogies, but nobody seems to explain why the acceleration induced on approach isn't reversed on exit. Why can't the planet that loses some velocity to the satellite steal that velocity back from the satellite as the satellite exit's its sphere of influence? Thanks so much for spending the time to read. I look forward to any replies :)
I am an undergrad and am in an introductory level astrophysics course. I have a bit of confusion that I didn't know where to get help from so I made an account here. Please let me know if I miss some common etiquette or something... I don't understand how the slingshot maneuver provides a net gain in velocity. I just spoke with my professor about this, but his terminology left me confused. I understand that the target body for the flyby loses some of its momentum and that the satellite executing the flyby takes some of that velocity. That makes sense to me. What I do not understand is why that same interaction isn't undone after the satellite is adjacent to the body. If the satellite arrives with some V_1 and gains some ΔV from the planet in addition to having its velocity vector rotated some angle, why doesn't the satellite decelerate and the planet accelerate back to its previous velocity? For instance, take the classic example of a satellite with no velocity being passed by a planet executing a 180 degree flyby. From the planets perspective the satellite approaches the planet with the planet's velocity, call it V_1. After the planet passes, the satellite has a velocity of 2V_1 in the same direction of the planet rather than just v_1, because part of the planet's momentum was stolen by the satellite. Why does the kinetic energy of the satellite at the start of the flyby not equal the kinetic energy of the satellite after the flyby? It's as if the planet is capable of losing momentum from the satellite but is unable to take that same momentum back from the satellite.
I've read a lot of explanations and many analogies, but nobody seems to explain why the acceleration induced on approach isn't reversed on exit. Why can't the planet that loses some velocity to the satellite steal that velocity back from the satellite as the satellite exit's its sphere of influence? Thanks so much for spending the time to read. I look forward to any replies :)
