Zahid Iftikhar said:My question is about some physical quantities which two observers in two respective inertial frames will find the same. I wonder are there any such quantities? Some books say force, speed of light etc are constants for both the observers. Please guide me on this.
Regards.
pervect said:Something I wanted to clarify. Force, by which I mean the traditional 3-component vector or 3-force, is definitely not an invariant in special relativity.
Seeing as how most intro treatments only consider cases in which the boost is aligned with the x-axis... I think this is worth mentioning.SiennaTheGr8 said:I hesitate to mention this, given the level of the thread, but it also turns out that 3-force (magnitude) is Lorentz-invariant in the one-dimensional case. (More generally, the Cartesian component of 3-force that's parallel to the axis of a Lorentz boost is invariant under said boost. The other components aren't.) I don't attach much meaning to this, though.
Thanks for the reply. Do you mean both the observers will measure same speed of each other's frame of reference? But speed is length divided by time. If length shrinks and time dilates, should the speed not change? My explanation may reveal my very basic knowledge of relativity. I apologize for it.robphy said:The relative speed of the other frame.
But mass increases and time dilates a per special theory of relativity. How are they invariant? please guide.Dale said:In the literature these are called invariants. These include mass, proper time, proper acceleration, phase, ##E^2-B^2##, ##\rho^2-J^2##, and of course c.
Edit: I am both too little and too late!
Thanks for the reply.PeroK said:The term you are looking for is invariant quantities.
The speed of light, ##c## is one - often the defining one.
The spacetime distance between two events is invariant: ##-c^2(\Delta t)^2 + (\Delta x)^2##.
In general, the length of any four-vector is an invariant. Spacetime distance is the length of the displacement four-vector.
Another good example is the energy-momentum four-vector, in which case the invariant quantity is the invariant mass:
##m^2c^4 = E^2 - p^2c^2##
All good stuff!
The usual meaning of mass now is the quantity ##m^2 c^2=E^2/c^2-p^2##. This quantity is invariant. There is some confusion due to an outdated concept called “relativistic mass” that has not been in use for decades among professional physicists.Zahid Iftikhar said:But mass increases
Proper time does not dilate, that is why I specified proper time.Zahid Iftikhar said:and time dilates
Thanks Sir. You mean the time in one's own frame of reference. I am often confused to understand this term. I apologize.Dale said:The usual meaning of mass now is the quantity ##m^2 c^2=E^2/c^2-p^2##. This quantity is invariant. There is some confusion due to an outdated concept called “relativistic mass” that has not been in use for decades among professional physicists.
Proper time does not dilate, that is why I specified proper time.
Imagine a disc that just fits through a ring (like one of those babies' shape sorting toys). If width expands or contracts in different frames, describe what happens when the disc tries to pass through the ring, in the rest frame of the ring and in the rest frame of the disc.Zahid Iftikhar said:What if I say in 2D motion if relative motion of the frames is along x-axis, can we say the observers in both frames will agree upon the width (length along y-axis perpendicular to direction of motion) of all the objects inside both the frames to be invariant?
Yes. Imagine two identical cars in a head-on collision. In car 1's rest frame, all the energy that damaged the cars came from car 2's kinetic energy. In car 2's frame it all came from car 1's kinetic energy. But they agree on the damage done, and how much energy that must have taken. So what does that tell you about the kinetic energy (and hence velocity) of car 2 in car 1's frame and of car 1 in car 2's frame?Zahid Iftikhar said:Do you mean both the observers will measure same speed of each other's frame of reference?
There's a third effect called the relativity of simultaneity, which is critical to understanding relativity. Your analysis is incorrect because you haven't included it. Look up the Lorentz transforms, and then apply them to one car measuring the other's speed and vice versa.Zahid Iftikhar said:But speed is length divided by time. If length shrinks and time dilates, should the speed not change?
Relativistic mass increases with velocity, but serious sources largely stopped using the term decades ago because it causes nothing but confusion. Dale is referring to rest mass (also known as invariant mass), and this is what is usually meant by "mass" these days. It doesn't change.Zahid Iftikhar said:But mass increases and time dilates a per special theory of relativity. How are they invariant? please guide.
Because proper acceleration is something you can measure in a closed box - for example you feel yourself pressed back into the seat when you accelerate in a car. That's a (crude) instrument for detecting proper acceleration. Thus everyone must agree what acceleration you feel - or else we can't explain why you are pressed into your seat.Zahid Iftikhar said:How is acceleration invariant?
The 2d case is just a 4d case where you've required two of all your vector components to be zero. So anything invariant in the general case is also invariant in the 2d or 3d case. As @SiennaTheGr8 points out, you get some extra invariants in 2d.Zahid Iftikhar said:Are there any quantities in 2D or 3D invariant?
Zahid Iftikhar said:Thank you very much all very helpful scholars. After reading all these responses I inwardly realize I need to go through basic lessons of theory of relativity. Would you suggest me some sources where a novice may learn it.
High regards.
Zahid Iftikhar said:Thank you very much all very helpful scholars. After reading all these responses I inwardly realize I need to go through basic lessons of theory of relativity. Would you suggest me some sources where a novice may learn it.
High regards.
An inertial frame is a reference frame in which Newton's first law of motion holds true. This means that an object at rest will remain at rest and an object in motion will continue moving in a straight line at a constant speed, unless acted upon by an external force.
The concept of inertial frames is closely related to Newton's laws of motion. In fact, the first law states that an object will remain in a state of rest or uniform motion in an inertial frame, unless acted upon by a net force. This demonstrates the importance of inertial frames in understanding the behavior of objects in motion.
Constant quantities in an inertial frame are physical quantities that remain unchanged regardless of the reference frame. These include properties such as mass, velocity, and acceleration. In an inertial frame, these quantities will remain constant as long as no external forces act upon the system.
A frame can be determined to be inertial if it satisfies the conditions of Newton's first law of motion. This means that an object at rest will remain at rest and an object in motion will continue in a straight line at a constant speed, unless acted upon by an external force. Additionally, an inertial frame must also be free from any external forces or accelerations.
Inertial frames play a crucial role in understanding the laws of physics, specifically Newton's laws of motion. By using inertial frames as a reference point, we can accurately predict the motion of objects and understand the effects of external forces on these objects. Inertial frames also allow us to make connections between seemingly unrelated phenomena and develop fundamental theories and laws of physics.