Actually, neither. The gyro does not continue to point at the same point, but it precesses much less than 360 degrees.Barry Srase said:does the axis continue to point at the same point in infinity as it rotates around the planet or does the axis follow the curvature of space around the planet and thus appear to a distant observer to rotate through 360 degrees with each rotation around the planet?
DaleSpam said:Actually, neither. The gyro does not continue to point at the same point, but it precesses much less than 360 degrees.
This effect is known as "frame dragging" and is one of the predictions of general relativity. I believe that Gravity Probe B confirmed it to within 20%, which is not a fantastic error margin, but was the first measurement of its kind. Essentially, they did exactly the experiment you described.
Oops, you are right. I somehow assumed the rotation of the massive body was part of the question although it was not there.Matterwave said:the OP did not specify that that central mass is rotating, which is a requirement for frame dragging to occur.
Barry Srase said:...and that the object is traveling in the direction of its axis...
Matterwave said:In addition, the OP did not specify that that central mass is rotating, which is a requirement for frame dragging to occur.
WannabeNewton said:These are not all separate effects and frame dragging does not require a rotating mass in order to occur. Frame dragging includes a variety of effects one of which is the precession of a gyroscope stationary in a coordinate system; geodetic precession in one coordinate system, say for a circular orbit, can easily be converted into frame dragging in the corotating coordinates.
Isn't the mass rotating in the co-rotating coordinates of the orbiting object?WannabeNewton said:...frame dragging does not require a rotating mass in order to occur...
...geodetic precession in one coordinate system, say for a circular orbit, can easily be converted into frame dragging in the corotating coordinates.
A.T. said:Isn't the mass rotating in the co-rotating coordinates of the orbiting object?
I assume they (and the authors of the linked paper) use the term "frame dragging" in the sense of an effect of that coordinate independent rotation, not an effect introduced by transforming into rotating coordinates, like you did in post #8. Is that correct?WannabeNewton said:It certainly orbits the gyroscope but the sense in which matterwave and DaleSpam were using the term "rotation" is that of a spin angular momentum of the central mass, which is coordinate independent.
A.T. said:I assume they (and the authors of the linked paper) use the term "frame dragging" in the sense of an effect of that coordinate independent rotation, not an effect introduced by transforming into rotating coordinates, like you did in post #8. Is that correct?
The paper distinguishes between "geodetic drift" and "frame dragging". In post #8 you seemed to suggest that you cannot separate the two effects. So how did they do it in that paper?WannabeNewton said:The paper simply says there is a frame dragging effect due to the Earth's rotation,
If the mass is not rotating (in a frame independent sense) is there "frame dragging" in the rest frame of that mass (In the sense the paper uses the term "frame dragging" and in the sense you use it, if there is a difference)?WannabeNewton said:...saying there is no frame dragging if there is no rotation of the central mass is not an accurate statement.
Gravitational effects of gyros near a massive object refer to the changes in the movement and rotation of a gyroscope due to the presence of a massive object with a strong gravitational pull.
The mass of the object directly affects the strength of its gravitational pull. The larger the mass of the object, the stronger the gravitational effects on gyros will be.
The closer a gyro is to a massive object, the stronger the gravitational effects will be. As the distance between the gyro and the object increases, the gravitational effects will decrease.
Aside from the mass and distance of the object, other factors that can influence the gravitational effects on gyros include the shape and rotation of the object, as well as the mass and distribution of nearby objects.
The gravitational effects on gyros can impact the accuracy of spacecraft navigation and control systems. Understanding and accounting for these effects is crucial for successful space missions, especially when navigating near large and massive objects like planets or moons.