Relativity Tutorial

Galilean Relativity

Relativity can be described using space-time diagrams. Contrary to popular opinion, Einstein did not invent relativity. Galileo preceded him. Aristotle had proposed that moving objects (on the Earth) had a natural tendency to slow down and stop. This is shown in the space-time diagram below.



But Galilean transformations do not preserve velocity. Thus the statement "The speed limit is 70 mph" does not make sense -- but don't try this in court. According to relativity, this must be re-expressed as "The magnitude of the relative velocity between your car and the pavement must be less than 70 mph". Relative velocities are OK.

Special Relativity

But 200 years after Newton the theory of electromagnetism was developed into Maxwell's equations. These equations describe waves with a speed of 1/sqrt(epsilon o *mu o ), where epsilon o is the constant describing the strength of the electrostatic force in a vacuum, and mu o is the constant describing the strength of the magnetic interaction in a vacuum. This is an absolute velocity -- it is not relative to anything. The value of the velocity was very close to the measured speed of light, and when Hertz generated electromagnetic waves (microwaves) in his laboratory and showed that they could be reflected and refracted just like light, it became clear that light was just an example of electromagnetic radiation. Einstein tried to fit the idea of an absolute speed of light into Newtonian mechanics. He found that the transformation from one reference frame to another had to affect the time -- the idea of sliding a deck of cards had to be abandoned. This led to the theory of special relativity. In special relativity, the velocity of light is special. Anything moving at the speed of light in one reference frame will move at the speed of light in all unaccelerated reference frames. Other velocities are not preserved, so you can still try to get lucky on speeding tickets.



Thus in the situation shown in 3 space-time diagrams below, the central section shows the worldline of one stationary observer, one observer moving to the right, and two events on the future light cone on the event where the two observers' worldlines cross.



What is the evidence for the invariance of the speed of light? The hypothesis that the speed of light is c relative to its source can easily be disproved by the one-way transmission of light from distant supernovae. When a star explodes as a supernova, we see light coming from material with a large range of velocities dv, at least 10,000 km/sec. Because of this range of velocities, the spectral lines of a supernova are very broad due to the Doppler shift. After traveling a distance D in time D/c, the arrival time of the light would be spread out by dt = (dv/c)(D/c).



However, light could travel at speed c relative to a medium -- the ether. If it did, then the rate of a "bouncing photon clock" moving with respect to the ether



P(par) = L/(c-v) + L/(c+v) = [2L/c]/(1-v2/c2).

(ct)2 = L2 + (vt)2 so t = L/sqrt(c2-v2) P(perp) = 2t = [2L/c]/sqrt(1-v2/c2).

dP/P = [P(par)-P(perp)]/P = 0.5*v2/c2.

Michelson and Morley used two bouncing photon clocks at right angles to each other, but without the lasers and counters which didn't exist. This left an L-shaped interferometer. But they were able to show that dP/P was essentially zero instead of the ether model prediction.

Radar

The constancy of the speed of light allows the use of radar (RAdio Detection And Ranging) to measure the position and time of events not on an observer's worldline. All that we need are a clock and the ability to emit and detect radar pulses.



Time Dilation

Armed with radar, we can determine the time of two events on the worldline of an observer moving with respect to us. We can then compare the time interval we measure to the time interval measured by the moving observer. Consider the two observers A and B below.



v = D/t = DA(R)/tA(R) = c(k*k-1)/(k*k+1).

k = sqrt((1+v/c)/(1-v/c))

(1+k*k)/(2*k) = 1/sqrt(1-v2/c2).

This slow down factor is exactly the slow down calculated above in the ether model for a bouncing photon clock moving perpendicular to its bounce axis. The clock moving parallel to the axis slows down by the same amount under special relativity because of the Lorentz-Fitzgerald contraction of moving objects in the direction of motion.



P(par) = [2L*sqrt(1-v2/c2)/c]/(1-v2/c2) = [2L/c]/sqrt(1-v2/c2) = P(perp)

Because the clocks of different observers run at different rates, depending on their velocities, the time for a given observer is a property of that observer and his worldline. This time is called the proper time because it is "owned" by a given particle, not because it is the "correct" time. Proper time is invariant when changing reference frames because it is the property of a particle, not of the reference frame or coordinate system. In general, given any two events A and B with B inside the future light cone of A, there is one unaccelerated worldline connecting A and B, just as there is one straight line connecting two points in space. In the frame of reference of the observer following this unaccelerated worldline, his clock is always stationary, while clocks following any other worldline from A to B will be moving at least some of the time. Because moving clocks run slow, these observers will measure a smaller proper time between events A and B than the unaccelerated observer. Thus the straight worldline between two events has the largest proper time, and all other curved worldlines connecting the two events have smaller proper times. This is exactly analogous to the fact that the straight line between two points has the smallest length of all possible curves between the points. Thus the "twin paradox" is no more paradoxical than the statement that a man who drives straight from LA to Las Vegas will cover fewer miles than a man who drives from LA to Las Vegas via Reno.



The pair of space-time diagrams above show quintuplets separated at birth. The middle worldline shows the quint who stays home. The space-time diagram on the left is done from the point of view of the middle quint. Each dot on a worldline is a birthday party, so the middle quint is 10 years old when they all rejoin each other, while the other quints are 6 and 8 years old. The space-time diagram on the right shows the same events from the point of view of an observer initially moving with one of the moving quints. When the quints come together their ages are still 6, 8, 10, 8, and 6 years. Thus the straight worldline between two events can be found by maximizing the proper time, just as the straight line between two points can be found by minimizing the length.

General Relativity

Now we come to a matter of gravity: how can gravity be an inverse square law force, when the distance between two objects can not even be defined in Einstein's special relativity? Special relativity was constructed to satisfy Maxwell's equations, which replaced the inverse square law electrostatic force by a set of equations describing the electromagnetic field. So gravity was the only remaining action-at-a-distance inverse square law force. And gravity has a unique property; the acceleration due to gravity at a given place and time is independent of the nature of the body.



Thus through any event in space-time, in any given direction, there is only one worldline corresponding to motion solely influenced by gravity. Compare this to the geometric fact that through any point, in any given direction, there is only one straight line. We are led to propose that worldlines influenced only by gravity are really straight worldlines. But how can an accelerating body have a straight worldline? It all depends on how you measure it. Suppose we plot a straight line on polar graph paper, and then make a plot of radius vs angle as shown below?



Principle of Equivalence

Einstein proposed that the effects of gravity (in a small region of spacetime) are equivalent to the effect of using an accelerated frame of reference without gravity. As as example, consider the famous "Einstein elevator" thought experiment. If an elevator far out in space accelerates upward at 10 meters/second2, it will feel like a downward acceleration of gravity at 1 g = 10 m/s2. If a clock on the ceiling of the elevator emits flashes of light f times per second, an observer on the floor will see them arriving faster than f times per second because of the Doppler shift due to the acceleration of the elevator during the light transit time.



The effect of gravity on clocks was tested to greater precision by Vessot etal (1980, PRL, 45, 2081) who launched a hydrogen maser straight up at 8.5 km/sec, and watched its frequency change as it coasted up to 10,000 km altitude and then fell back to Earth. The frequency shift due to gravity was (f'/f -1) = 4*10-10 at 10,000 km altitude, and the experimental result agreed to within 70 parts per million of this shift.

Because of the gravitational speedup for uphill clocks, an observer moving between two events can achieve a larger proper time by shifting his worldline upward in the middle. Going too far upward requires moving so fast that time dilation due to motion reduces the proper time more than the gravitational speedup, so there is an optimum curvature to the worldline that maximizes the proper time.



Curved Spacetime

Curved coordinates alone, such as the polar graph, do not provide a satisfactory model for gravity. Two straight lines through the same point but with different directions will never cross again, while two worldlines influenced only by gravity which pass through the same event with different velocities can cross again. Consider the Galileo spacecraft, which made two Earth flybys. In between the flybys, Galileo was on an elliptical orbit with a 2 year period. In order to allow "straight" lines to cross multiple times, a curved space-time is needed. As a familiar example of a curved space, consider the surface of the Earth and the great circle arc connecting two cities. The great circle is the shortest distance between two points on the surface of the Earth, and it is the path followed by airliners.



Plotting latitude vs longitude, as if longitude were time and latitude position, gives the pseudo-spacetime diagram below.



Einstein was able to compute the perihelion advance of Mercury using general relativity, and his calculation matched an observed discrepancy with Newtonian predictions. Einstein also computed that light passing by the Sun would be deflected by twice as much as a prediction using Newtonian gravity and Newton's particle model for light would suggest. The same effect causes a delay of light passing by the limb of the Sun, known as the Shapiro delay, which has now been measured to great accuracy and agrees with the prediction of general relativity.

Light cones in curved space-time

Unlike the restricted set of Lorentz transformations allowed in special relativity, the more general coordinate transformations of general relativity will change the slope of the walls of the lightcones. In other words, the speed of light (dx/dt) will change in the transformed coordinates: dx'/dt' will not equal dx/dt in general. The light cones can tilt or stretch. The figure below shows "lightcones" added to the radius vs angle example given above:



Thus the fundamentals of relativity that are important for cosmology are:

The speed of light is a constant independent of the velocity of the source or the observer.

Events that are simultaneous as seen by one observer are generally not simultaneous as seen by other observers, so there can be no absolute time.

Each observer can define his own proper time -- the time measured by a good clock moving along his worldline.

Observers can assign times and positions to events not on their worldlines using radar observations.

Every observer will see his clock running faster than other clocks which are moving with respect to him, and this is a mathematically consistent pattern required by the properties of radar observations.

As a result, the unaccelerated worldline between two events will have the longest proper time of all worldlines connecting these events.

In the presence of gravity, the worldlines of objects accelerated only by gravity have the longest proper times.

Gravity requires that spacetime have a non-Euclidean geometry, and this curvature of spacetime must be created by matter.

Relativity also leads to interesting objects such as black holes, but these are not very relevant to cosmology.

There are many books on relativity available, but two that stick to a simple level of mathematics are:

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