This is one I haven't gotten a handle on...
An asteroid is seen approaching earth at 0.9c and an expedition is sent to intercept and deflect it. The astronauts land on it (how doesn't matter, they just do) and set up the deflection engines to cause the asteroid to change its speed.
Earth-based techs monitor the whole operation and watch the astronauts install the asteroid-monted rockets in place, pointed directly at the earth. The astronauts fire the engines and the asteroid's approach speed drops toward 0, passes it, and later achieves 0.9c away from earth. The astronauts pack up and come home, never having to pay taxes again.
From earth, the influence of the rocket engines on the asteroids seems to follow GR's rules: during the times when the asteroid is at relativisitic speeds compared to earth its acceleration is reduced, because of its increased mass. Around the time its speed is near zero its acceleration from the known-thrust rockets is what Newton predicted.
Of course, to the astronauts sitting on the asteroid the accelerometers they installed work perfectly according to Newton the whole time. Acceleration from the known-thrust rockets is constant no matter how fast they're going relative to an arbitrary reference. The astronauts only can measure the asteroid's rest mass.
But wait! The techs on earth have been watching those asteroid-based acclerometers and could observe their readings, so they could see that the mass was not relativistically altered. In fact, they could even read the astronauts' bathroom scale when they weighed themselves every morning (they were parked so the scale was at right angles to the asteroid's accleration, they were reading only the gravitational attraction between the astronauts' bodies and the asteroid).
So, what do the earth-based techs conclude about the mass of the asteroid? That it changes with speed, per GR, or that it is constant, per the locally mounted guages and instruments they can read?
I do know that particles accelerated to near light speed deflect in magnetic fields as if they were more massive per GR, but what is "right" when you can see both the effects from your reference frame and those on the local reference at the same time?
Maybe this is no big deal, and reflects what I don't know about GR, but I've been under the impression that the velocity-based mass shift was supposed to be absolute to observers on the remote inertial frame.
An asteroid is seen approaching earth at 0.9c and an expedition is sent to intercept and deflect it. The astronauts land on it (how doesn't matter, they just do) and set up the deflection engines to cause the asteroid to change its speed.
Earth-based techs monitor the whole operation and watch the astronauts install the asteroid-monted rockets in place, pointed directly at the earth. The astronauts fire the engines and the asteroid's approach speed drops toward 0, passes it, and later achieves 0.9c away from earth. The astronauts pack up and come home, never having to pay taxes again.
From earth, the influence of the rocket engines on the asteroids seems to follow GR's rules: during the times when the asteroid is at relativisitic speeds compared to earth its acceleration is reduced, because of its increased mass. Around the time its speed is near zero its acceleration from the known-thrust rockets is what Newton predicted.
Of course, to the astronauts sitting on the asteroid the accelerometers they installed work perfectly according to Newton the whole time. Acceleration from the known-thrust rockets is constant no matter how fast they're going relative to an arbitrary reference. The astronauts only can measure the asteroid's rest mass.
But wait! The techs on earth have been watching those asteroid-based acclerometers and could observe their readings, so they could see that the mass was not relativistically altered. In fact, they could even read the astronauts' bathroom scale when they weighed themselves every morning (they were parked so the scale was at right angles to the asteroid's accleration, they were reading only the gravitational attraction between the astronauts' bodies and the asteroid).
So, what do the earth-based techs conclude about the mass of the asteroid? That it changes with speed, per GR, or that it is constant, per the locally mounted guages and instruments they can read?
I do know that particles accelerated to near light speed deflect in magnetic fields as if they were more massive per GR, but what is "right" when you can see both the effects from your reference frame and those on the local reference at the same time?
Maybe this is no big deal, and reflects what I don't know about GR, but I've been under the impression that the velocity-based mass shift was supposed to be absolute to observers on the remote inertial frame.
