Answer :
Answer:
6.26 times more
Explanation:
Given:
- most satellite orbit at height r_1 = 1000 km
- Geosynchronous satellites orbit at height r_2 = 35,790 km
- mass of Geosynchronous satellite m = 410 kg
- The radius of the earth r_e = 6371 km
Find:
- Compare the Energy required to send the satellite to Geosynchronous orbit @ r_2 vs Energy required to send the satellite to normal orbit @ r_1. How much more. ( U_1 / U_2 ).
Solution:
- The gravitational potential energy of any mass m in an orbit around another mass M is given by the following relation:
U_g = - G*m*M / r
Where,
G : Gravitational constant
- We compute the gravitational potential energy U_g of the satellite at both orbits as follows:
-Normal orbit U_1 = - G*m*M / r_e + G*m*M / (r_e+r_1)
U_2 = - G*m*M / r_e + G*m*M / (r_2+r_e)
Now: Take a ratio of the two energies U_1 and U_2 as follows:
U_2 / U_1 = (- G*m*M / r_e + G*m*M / r_2+r_e) / (- G*m*M / r_e + G*m*M / r_1+r_e)
U_2 / U_1 = (1 / (r_2+r_e) - 1 / r_e ) / (1 / (r_1 + r_e) - 1 / r_e )
- Plug values:
U_2 / U_1 = (1 / (35790+6371) - 1 / 6371 ) / (1 / (1000+6371) - 1 / 6371 )
- Evaluate:
U_2 / U_1 = (-1.33242681 * 10^-4) / (2.12944*10^-5)
U_2 / U_1 = 6.26
- Hence The energy required to send the satellite to Geosynchronous orbit is 6.26 times more than that required for normal orbit.