Does the Heisenberg Uncertainty Principle Affect Relativity Calculations?

In summary, the Heisenberg Uncertainty Principle prevents you from accurately knowing all the starting information for small scales. However, after a translation and boost, you can calculate the position and velocity of a particle to arbitrary precision.
  • #1
Tegg Mentall
5
0
Hi,

Just had a quick question... Relativity seems to require the position and time of an event in one reference frame and the difference in velocity with a second reference frame. Given this starting information you're suppose to be able to calculate the position and time of the same event as seen from the second reference frame... Does the Heisenberg Uncertainty Principle prevent you from accurately knowing all the starting information for small scales... Thanks.

Tegg
 
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  • #2
Hi Tegg, welcome to PF!

Position and time are not canonically conjugate to each other so according to the uncertainty principle you can know both to arbitrary precision.
 
  • #3
Thanks for replying... I guess I'm thinking that in particle experiments the primary reference frame is normally some sort of sensor equipment and the secondary frame is anchored to a fast moving particle. Then if you know the velocity of the secondary reference frame you have trouble figuring out the it's position... But maybe that's not the way experiments are set up...
 
  • #4
Remember, reference frames are not physical entities, they are coordinate systems. They are mathematical tools for keeping track of physics, they are in no way "anchored" to anything.

So, let's say that you have a non-relativistic particle whose position you know to be x±∆x and whose velocity you know to be v±∆v such that (∆x)(m∆v) satisfies the HUP. Now, suppose further that you do a translation and a boost such that x'=0 and v'=0. Then in the primed reference frame the particle's position is 0±∆x and the particle's velocity is 0±∆v and (∆x)(m∆v) still satisfies the HUP.
 
  • #5
Thanks again for replying... Sorry for the delay. Had to try and get my head around the math. Not sure if I did... For a relativistic particle with position x±∆x and velocity v±∆v such that (∆x)(m∆v) satisfies the HUP, after the translation and boost I seem to get:

∆x' = ∆x / sqrt(1- v^2/c^2)

∆v' = ∆v / (1 - v^2/c^2 - (v)∆v/c^2)

This seems to imply that ∆x'>∆x and ∆v'>∆v so that (∆x')(m∆v') > (∆x)(m∆v)...
 
  • #6
Yes, I specified non-relativistic because I was too lazy to write out all of those terms.
 
  • #7
Ok. Last question... Things being relative. If you set (∆x')(m∆v') so that it satisfies the HUP then doesn't (∆x)(m∆v) violate the HUP...
 
  • #8
No. Remember, mv is not the momentum of a relativistic particle.
 
  • #9
Thanks for your help.
 

FAQ: Does the Heisenberg Uncertainty Principle Affect Relativity Calculations?

What is the theory of relativity?

The theory of relativity is a scientific theory developed by Albert Einstein in the early 20th century, which describes the relationship between space and time. It consists of two main theories - special relativity and general relativity. Special relativity explains the relationship between time and space for objects moving at a constant speed, while general relativity explains the effects of gravity on the fabric of space-time.

How does the theory of relativity impact our understanding of the universe?

The theory of relativity has had a significant impact on our understanding of the universe. It has provided a more accurate description of the laws of physics and has led to the discovery of new phenomena such as black holes and gravitational waves. It has also helped us understand the concept of time dilation and the fact that the passage of time is relative and not absolute.

What is the uncertainty principle?

The uncertainty principle is a fundamental principle in quantum mechanics, which states that it is impossible to know the exact position and momentum of a particle simultaneously. This means that there will always be a degree of uncertainty in our measurements, and the more precisely we know one aspect, the less we know about the other.

How does the uncertainty principle relate to relativity?

The uncertainty principle and relativity are both fundamental principles of physics, but they apply to different scales. Relativity deals with the behavior of large objects in the universe, while the uncertainty principle applies to the behavior of subatomic particles. However, both theories have implications for our understanding of the nature of reality and the limitations of our ability to make precise measurements.

What are some practical applications of relativity and uncertainty?

The theory of relativity has practical applications in technologies such as GPS, as it accounts for the effects of time dilation and gravitational fields on the accuracy of measurements. The uncertainty principle has practical applications in fields such as quantum computing and cryptography, where the uncertainty of measurements is used to ensure secure communication. Both theories also have implications for the development of new technologies and our understanding of the fundamental laws of nature.

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