A spaceship travels through the dock of a space station without slowing down. The speed of the spaceship relative to the station is v = 4c/5, where c is the speed of light. Consider frames of reference in the standard configuration with v and all distances aligned along the x-axis. Primed variables refer to events in the station frame and unprimed to events in the spaceship frame. The dock has a length of L′ = 200 m in the station frame. (a) (i) In the station frame, calculate the time, T′, that it takes for the front of the spaceship to travel the length of the dock. (ii) Define two events in the spaceship frame at (t = 0, x = 0) and (t = T, x = 0) and use appropriate Lorentz transforms to transform them to the station frame. These events correspond to the front of spaceship passing the entrance of the dock and the exit of the dock, respectively. (iii) In the spaceship frame, calculate the time, T , that it takes for spaceship to travel the length of the dock. (b) A fuel transfer will be attempted while the spaceship passes through the dock. The spaceship length is L = 289 m in the spaceship frame. In order for the transfer to be successful, force fields must be closed simultaneously in the station frame at each end of the dock to enclose the entire spaceship for a short period of time. (i) In the station frame, the event corresponding to closing the front of the dock is at (t′ = 0, x′ = 0) and the event corresponding to closing the rear of the dock is at (t′ = 0, x′ = L′). Perform the Lorentz transformation on each of these coordinates to determine the coordinates t,x in the spaceship frame in terms of L′, v and c. (ii) Calculate the difference between the spatial coordinates in the spaceship frame. On this basis, comment on whether the phenomenon of length contraction will allow the entire spaceship to fit into the dock.
A spaceship travels through the dock of a space station without slowing down. The speed of...
A spaceship is preparing to dock with a space station.
Throughout this problem the space station is motionless in the
space frame (inertial frame). Prior to docking, some rotational
maneuvers are necessary for the spaceship. At t = 0, the angular
velocity of the spaceship is zero, and we have e_1 = x cap, e_2 = y
cap and e_3 = z cap. A number of small rocket engines are attached
to the exterior of the spaceship, and they can...
Using Lorentz transformations, analyse the following sequence of events taking place in a spaceship piloted by O': A light pulse emitted from a horizontally positioned laser in the back of the spaceship travels towards a detector mounted on the front of the spaceship. O' measures the time delta t' needed for the laser light to travel this distance, and could use this information to verify the length of her spaceship (call this length L' and write down the formula O'...
general relativity
A spaceship of proper length Lp = 350 m
moves past a transmitting station at a speed of 0.77c.
(The transmitting station broadcasts signals that travel at the
speed of light.) A clock is attached to the nose of the spaceship
and a second clock is attached to the transmitting station. The
instant that the nose of the spaceship passes the transmitter, the
clock attached to the transmitter and the clock attached to the
nose of the spaceship...
this is one question but with multiple choice questions,
sorry.
Problem 1 You're in a spaceship in deep space. Your engines are off, and you're far away from any reference points. a) You release a small ball from rest. The ball remains floating at rest in the same position where you released it. What kind of reference frame are you in? Is there any way to tell if you are moving at all? Let's designate your reference frame as S,...
[Q2 20 points] A and B devices separated by a distance d- 50 m measured in the reference frame S where they are at rest. The following sequence of events occurs: (K) A sends light signal towards B. (L) As soon as the signal is received by B, B sends a signal back to A. (M) A receives the signal from B The reference frame S', coincides with S at time t = t, 0 and is in motion with...
Alice G LOO Bob Let's revisit the simultaneity problem from worksheet 11. To make things concrete, we'll include specific numbers. Bob is standing on the ground watching Alice go by in a high-speed train. As seen in Bob's reference frame, Alice is traveling to the right at speed v = +0.80c. As measured in Bob's frame, Alice's rail car is 12 m long. Alice is sitting in the exact center of the train car. At the instant that the Alice...
2. Consider a mass m moving in R3 without friction. It is fasten tightly at one end of a string with length 1 and can swing in any direction. In fact, it moves on a sphere, a subspace of R3 1 0 φ g 2.1 Use the spherical coordinates (1,0,) to derive the Lagrangian L(0,0,0,0) = T-U, namely the difference of kinetic energy T and potential energy U. (Note r = 1 is fixed.) 2.2 Calculate the Euler-Lagrange equations, namely...
Projectile A is fired at a speed Vo at an angle 0 above horizontal as shown and projectile B is fired at the sar but at a speed of 2%. Use this for Questions #1-7. angle Draw the initial velocity vectors for both projectile A and projectile B. Remember that the length of your arrows is important. 1. 2. Compare the initial horizorntal and vertical velocities of projectiles A and B. Be specific. Explain your answers. 3. Compare the horizontal...
Projectile A is fired at a speed Vo at an angle 0 above horizontal as shown and projectile B is fired at the same angle but at a speed of 2 g. Use this for Questions # 1-7. Draw the initial velocity vectors for both projectile A and projectile B Remember that the length of your arrows is important 1. Compare the initial horizontal and vertical velocities of projectiles A and B. Be specilic. Explain your answers 2. 3. Compare...
Design the cooling system used to manufacture the leg of a table, shown in Fig.2. You will have to determine the required diameter D so that the leg can withstand 100 kg of axial loading. Once the diameter has been determined, you will need to determine the Revolutions per Minute (RPMs) of the fan needed to cool down the leg to 90-C in less than 2 minutes before it starts deforming after being 3D printed. Consider the leg of the...