Time dilation for a moving electronic clock












6












$begingroup$


Is this a correct application for the time dilation theorem?



Suppose an electronic clock has a copper wire of length $d$, which allows the electrons to take $t$ seconds to complete a cycle on the $d$-long copper wire, in the electronic clock.



Then, the the entire clock is moving in a rocket at a speed $v$ in a straight line.



The electronic clock must slowdown. My question is, is the following the new slowed-down time (update: in the reference frame of someone stationary that is not moving in the rocket)?



$$
t_{new} = frac{t}{sqrt{1-frac{v^2}{c^2}}}
$$

where $c$ is light speed.



Is that correct? If not correct, why?



Note: just to be clear, I know that applies on the light clock. But does it also apply on other non-light clocks, such as an electronic clock? E.g. should I replace $c$ by the speed of the electron movement on that copper instead?










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  • 3




    $begingroup$
    The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
    $endgroup$
    – Monty Harder
    8 hours ago






  • 1




    $begingroup$
    @MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
    $endgroup$
    – llama
    3 hours ago
















6












$begingroup$


Is this a correct application for the time dilation theorem?



Suppose an electronic clock has a copper wire of length $d$, which allows the electrons to take $t$ seconds to complete a cycle on the $d$-long copper wire, in the electronic clock.



Then, the the entire clock is moving in a rocket at a speed $v$ in a straight line.



The electronic clock must slowdown. My question is, is the following the new slowed-down time (update: in the reference frame of someone stationary that is not moving in the rocket)?



$$
t_{new} = frac{t}{sqrt{1-frac{v^2}{c^2}}}
$$

where $c$ is light speed.



Is that correct? If not correct, why?



Note: just to be clear, I know that applies on the light clock. But does it also apply on other non-light clocks, such as an electronic clock? E.g. should I replace $c$ by the speed of the electron movement on that copper instead?










share|cite|improve this question









New contributor




caveman is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$








  • 3




    $begingroup$
    The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
    $endgroup$
    – Monty Harder
    8 hours ago






  • 1




    $begingroup$
    @MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
    $endgroup$
    – llama
    3 hours ago














6












6








6





$begingroup$


Is this a correct application for the time dilation theorem?



Suppose an electronic clock has a copper wire of length $d$, which allows the electrons to take $t$ seconds to complete a cycle on the $d$-long copper wire, in the electronic clock.



Then, the the entire clock is moving in a rocket at a speed $v$ in a straight line.



The electronic clock must slowdown. My question is, is the following the new slowed-down time (update: in the reference frame of someone stationary that is not moving in the rocket)?



$$
t_{new} = frac{t}{sqrt{1-frac{v^2}{c^2}}}
$$

where $c$ is light speed.



Is that correct? If not correct, why?



Note: just to be clear, I know that applies on the light clock. But does it also apply on other non-light clocks, such as an electronic clock? E.g. should I replace $c$ by the speed of the electron movement on that copper instead?










share|cite|improve this question









New contributor




caveman is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$




Is this a correct application for the time dilation theorem?



Suppose an electronic clock has a copper wire of length $d$, which allows the electrons to take $t$ seconds to complete a cycle on the $d$-long copper wire, in the electronic clock.



Then, the the entire clock is moving in a rocket at a speed $v$ in a straight line.



The electronic clock must slowdown. My question is, is the following the new slowed-down time (update: in the reference frame of someone stationary that is not moving in the rocket)?



$$
t_{new} = frac{t}{sqrt{1-frac{v^2}{c^2}}}
$$

where $c$ is light speed.



Is that correct? If not correct, why?



Note: just to be clear, I know that applies on the light clock. But does it also apply on other non-light clocks, such as an electronic clock? E.g. should I replace $c$ by the speed of the electron movement on that copper instead?







time-dilation






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edited 6 hours ago







caveman













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asked 12 hours ago









cavemancaveman

1336




1336




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New contributor





caveman is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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Check out our Code of Conduct.








  • 3




    $begingroup$
    The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
    $endgroup$
    – Monty Harder
    8 hours ago






  • 1




    $begingroup$
    @MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
    $endgroup$
    – llama
    3 hours ago














  • 3




    $begingroup$
    The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
    $endgroup$
    – Monty Harder
    8 hours ago






  • 1




    $begingroup$
    @MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
    $endgroup$
    – llama
    3 hours ago








3




3




$begingroup$
The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
$endgroup$
– Monty Harder
8 hours ago




$begingroup$
The speed of the electrons isn't what matters. An electromagnetic signal moving along a wire propagates at the speed of light. Adm. Grace Hopper had a habit of handing out wires cut to the length of a light-nanosecond, as a way to illustrate how that makes a hard limit on how fast data can be moved about a computer system.
$endgroup$
– Monty Harder
8 hours ago




1




1




$begingroup$
@MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
$endgroup$
– llama
3 hours ago




$begingroup$
@MontyHarder slightly pedantic correction - electromagnetic signals in wires propagate slower than the speed of light, sometimes very close to it (>95%), sometimes as slow as about half of it for certain types of coaxial cable, depending mostly on the dielectric spacer used.
$endgroup$
– llama
3 hours ago










4 Answers
4






active

oldest

votes


















2












$begingroup$

To answer your first question, yes, the formula is correct, and it shows changed time interval for a moving observer. And, yes, the formula can be applied to all clocks and to all events.Time interval that takes one event to happen changes depending on the motion of the observer. In order to see this for all events, look for some derivation of Lorentz boosts that is, Lorentz transformations regarding observers in constant speed motion in regard to each other. One way to derive these is to observe what happens to a spherical light pulse for two different observers in relative motion. When you get Lorentz transformations for the time and space then you just check out how does a time interval behave, that is, how does difference betwen two time points look in one and how in some other frame. So you can have t1 and t2. Time interval is t1-t2...transform t1 and t2 and check how does transformed time interval, T1 - T2, behave.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
    $endgroup$
    – caveman
    3 hours ago












  • $begingroup$
    @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
    $endgroup$
    – Henning Makholm
    2 hours ago












  • $begingroup$
    So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
    $endgroup$
    – Henning Makholm
    2 hours ago





















11












$begingroup$

Note that the clock slows down as viewed from someone else's reference frame.



In the rocket: clocks, melting ice, human biology, time, and whatever else you can think of all proceed normally. (Same with length contraction: right now we are both pancake flat in the reference frame of a cosmic ray, but we don't really notice it--at all).



Of course life on Earth proceeds normally too, even though the rocket's occupants see Earth's time ticking slowly (not to mention an, ahem, flat Earth).






share|cite|improve this answer









$endgroup$









  • 19




    $begingroup$
    Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
    $endgroup$
    – Aaron Stevens
    10 hours ago








  • 10




    $begingroup$
    hats off to, "give them a boost".
    $endgroup$
    – JEB
    10 hours ago






  • 2




    $begingroup$
    @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
    $endgroup$
    – JEB
    10 hours ago






  • 2




    $begingroup$
    Well I was shooting for the double entendre.
    $endgroup$
    – Aaron Stevens
    10 hours ago








  • 2




    $begingroup$
    @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
    $endgroup$
    – Acccumulation
    6 hours ago



















6












$begingroup$

All (properly functioning) clocks must experience the same time dilation, no matter what mechanism they use to tell time. Otherwise, you could use 2 different clocks to determine your absolute speed, but relativity says that absolute speed isn't a thing.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    So, my equation is correct to calculate the dilation of the electronic clock?
    $endgroup$
    – caveman
    6 hours ago






  • 1




    $begingroup$
    @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
    $endgroup$
    – PM 2Ring
    6 hours ago





















4












$begingroup$

I recommend Feynmann's chapter on this. It is included in Six easy pieces I think. He points out that once you've found the effect for one type of clock (e.g. light pulse clock) then you have found it for all types, because otherwise the different types of clock would get out of step with one another when observed by one observer but stay in step when observed by another. That would be a direct impossibility. For example if one observer says that two clocks go "bong" at the same moment at the same place, then all observers must agree that the bongs happened at the same moment at the same place.



You can put your electronic clock next to a light pulse clock, both in the same state of overall motion, and then whenever they tick at the same moment in their joint rest frame, that is one joint 'bong'.



This is also discussed in other introductory texts of course.






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    4 Answers
    4






    active

    oldest

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    4 Answers
    4






    active

    oldest

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    active

    oldest

    votes






    active

    oldest

    votes









    2












    $begingroup$

    To answer your first question, yes, the formula is correct, and it shows changed time interval for a moving observer. And, yes, the formula can be applied to all clocks and to all events.Time interval that takes one event to happen changes depending on the motion of the observer. In order to see this for all events, look for some derivation of Lorentz boosts that is, Lorentz transformations regarding observers in constant speed motion in regard to each other. One way to derive these is to observe what happens to a spherical light pulse for two different observers in relative motion. When you get Lorentz transformations for the time and space then you just check out how does a time interval behave, that is, how does difference betwen two time points look in one and how in some other frame. So you can have t1 and t2. Time interval is t1-t2...transform t1 and t2 and check how does transformed time interval, T1 - T2, behave.






    share|cite|improve this answer









    $endgroup$













    • $begingroup$
      Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
      $endgroup$
      – caveman
      3 hours ago












    • $begingroup$
      @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
      $endgroup$
      – Henning Makholm
      2 hours ago












    • $begingroup$
      So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
      $endgroup$
      – Henning Makholm
      2 hours ago


















    2












    $begingroup$

    To answer your first question, yes, the formula is correct, and it shows changed time interval for a moving observer. And, yes, the formula can be applied to all clocks and to all events.Time interval that takes one event to happen changes depending on the motion of the observer. In order to see this for all events, look for some derivation of Lorentz boosts that is, Lorentz transformations regarding observers in constant speed motion in regard to each other. One way to derive these is to observe what happens to a spherical light pulse for two different observers in relative motion. When you get Lorentz transformations for the time and space then you just check out how does a time interval behave, that is, how does difference betwen two time points look in one and how in some other frame. So you can have t1 and t2. Time interval is t1-t2...transform t1 and t2 and check how does transformed time interval, T1 - T2, behave.






    share|cite|improve this answer









    $endgroup$













    • $begingroup$
      Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
      $endgroup$
      – caveman
      3 hours ago












    • $begingroup$
      @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
      $endgroup$
      – Henning Makholm
      2 hours ago












    • $begingroup$
      So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
      $endgroup$
      – Henning Makholm
      2 hours ago
















    2












    2








    2





    $begingroup$

    To answer your first question, yes, the formula is correct, and it shows changed time interval for a moving observer. And, yes, the formula can be applied to all clocks and to all events.Time interval that takes one event to happen changes depending on the motion of the observer. In order to see this for all events, look for some derivation of Lorentz boosts that is, Lorentz transformations regarding observers in constant speed motion in regard to each other. One way to derive these is to observe what happens to a spherical light pulse for two different observers in relative motion. When you get Lorentz transformations for the time and space then you just check out how does a time interval behave, that is, how does difference betwen two time points look in one and how in some other frame. So you can have t1 and t2. Time interval is t1-t2...transform t1 and t2 and check how does transformed time interval, T1 - T2, behave.






    share|cite|improve this answer









    $endgroup$



    To answer your first question, yes, the formula is correct, and it shows changed time interval for a moving observer. And, yes, the formula can be applied to all clocks and to all events.Time interval that takes one event to happen changes depending on the motion of the observer. In order to see this for all events, look for some derivation of Lorentz boosts that is, Lorentz transformations regarding observers in constant speed motion in regard to each other. One way to derive these is to observe what happens to a spherical light pulse for two different observers in relative motion. When you get Lorentz transformations for the time and space then you just check out how does a time interval behave, that is, how does difference betwen two time points look in one and how in some other frame. So you can have t1 and t2. Time interval is t1-t2...transform t1 and t2 and check how does transformed time interval, T1 - T2, behave.







    share|cite|improve this answer












    share|cite|improve this answer



    share|cite|improve this answer










    answered 10 hours ago









    Žarko TomičićŽarko Tomičić

    1,003511




    1,003511












    • $begingroup$
      Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
      $endgroup$
      – caveman
      3 hours ago












    • $begingroup$
      @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
      $endgroup$
      – Henning Makholm
      2 hours ago












    • $begingroup$
      So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
      $endgroup$
      – Henning Makholm
      2 hours ago




















    • $begingroup$
      Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
      $endgroup$
      – caveman
      3 hours ago












    • $begingroup$
      @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
      $endgroup$
      – Henning Makholm
      2 hours ago












    • $begingroup$
      So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
      $endgroup$
      – Henning Makholm
      2 hours ago


















    $begingroup$
    Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
    $endgroup$
    – caveman
    3 hours ago






    $begingroup$
    Thanks. But to be honest, I am a bit surprised why the light speed, which is derived from the light-clock, still applies to non-light clock ones. Is there any proof for this applicability to non-light clocks? I mean, I can re-prove the time dilation by using an electronic clock, then instead of $c^2$ I'll have $v_e^2$ denoting electron's speed on that copper. The resultant time dilation would be different than the light-clock ones. So why should I believe the light-based one, and not the electron-based one for the dilation?
    $endgroup$
    – caveman
    3 hours ago














    $begingroup$
    @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
    $endgroup$
    – Henning Makholm
    2 hours ago






    $begingroup$
    @caveman: The starting point of relativity is the postulate that all fundamental laws of nature work equally well in a moving inertial frame. That this postulate is true about our universe is ultimately an empirical fact -- it's not a matter of proof, but of (abundant) empirical verification.
    $endgroup$
    – Henning Makholm
    2 hours ago














    $begingroup$
    So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
    $endgroup$
    – Henning Makholm
    2 hours ago






    $begingroup$
    So therefore if a light clock ticks slower by a certain factor in a moving frame, that factor has to hold for all other clocks too, because the laws that we have just postulated are invariant say they must tick at the same rate as a light clock.
    $endgroup$
    – Henning Makholm
    2 hours ago













    11












    $begingroup$

    Note that the clock slows down as viewed from someone else's reference frame.



    In the rocket: clocks, melting ice, human biology, time, and whatever else you can think of all proceed normally. (Same with length contraction: right now we are both pancake flat in the reference frame of a cosmic ray, but we don't really notice it--at all).



    Of course life on Earth proceeds normally too, even though the rocket's occupants see Earth's time ticking slowly (not to mention an, ahem, flat Earth).






    share|cite|improve this answer









    $endgroup$









    • 19




      $begingroup$
      Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 10




      $begingroup$
      hats off to, "give them a boost".
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      Well I was shooting for the double entendre.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 2




      $begingroup$
      @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
      $endgroup$
      – Acccumulation
      6 hours ago
















    11












    $begingroup$

    Note that the clock slows down as viewed from someone else's reference frame.



    In the rocket: clocks, melting ice, human biology, time, and whatever else you can think of all proceed normally. (Same with length contraction: right now we are both pancake flat in the reference frame of a cosmic ray, but we don't really notice it--at all).



    Of course life on Earth proceeds normally too, even though the rocket's occupants see Earth's time ticking slowly (not to mention an, ahem, flat Earth).






    share|cite|improve this answer









    $endgroup$









    • 19




      $begingroup$
      Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 10




      $begingroup$
      hats off to, "give them a boost".
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      Well I was shooting for the double entendre.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 2




      $begingroup$
      @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
      $endgroup$
      – Acccumulation
      6 hours ago














    11












    11








    11





    $begingroup$

    Note that the clock slows down as viewed from someone else's reference frame.



    In the rocket: clocks, melting ice, human biology, time, and whatever else you can think of all proceed normally. (Same with length contraction: right now we are both pancake flat in the reference frame of a cosmic ray, but we don't really notice it--at all).



    Of course life on Earth proceeds normally too, even though the rocket's occupants see Earth's time ticking slowly (not to mention an, ahem, flat Earth).






    share|cite|improve this answer









    $endgroup$



    Note that the clock slows down as viewed from someone else's reference frame.



    In the rocket: clocks, melting ice, human biology, time, and whatever else you can think of all proceed normally. (Same with length contraction: right now we are both pancake flat in the reference frame of a cosmic ray, but we don't really notice it--at all).



    Of course life on Earth proceeds normally too, even though the rocket's occupants see Earth's time ticking slowly (not to mention an, ahem, flat Earth).







    share|cite|improve this answer












    share|cite|improve this answer



    share|cite|improve this answer










    answered 10 hours ago









    JEBJEB

    6,1781718




    6,1781718








    • 19




      $begingroup$
      Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 10




      $begingroup$
      hats off to, "give them a boost".
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      Well I was shooting for the double entendre.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 2




      $begingroup$
      @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
      $endgroup$
      – Acccumulation
      6 hours ago














    • 19




      $begingroup$
      Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 10




      $begingroup$
      hats off to, "give them a boost".
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
      $endgroup$
      – JEB
      10 hours ago






    • 2




      $begingroup$
      Well I was shooting for the double entendre.
      $endgroup$
      – Aaron Stevens
      10 hours ago








    • 2




      $begingroup$
      @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
      $endgroup$
      – Acccumulation
      6 hours ago








    19




    19




    $begingroup$
    Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
    $endgroup$
    – Aaron Stevens
    10 hours ago






    $begingroup$
    Ah, so flat Earthers aren't necessarily wrong, they are just in the wrong reference frame! :) Someone should really give them a boost.
    $endgroup$
    – Aaron Stevens
    10 hours ago






    10




    10




    $begingroup$
    hats off to, "give them a boost".
    $endgroup$
    – JEB
    10 hours ago




    $begingroup$
    hats off to, "give them a boost".
    $endgroup$
    – JEB
    10 hours ago




    2




    2




    $begingroup$
    @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
    $endgroup$
    – JEB
    10 hours ago




    $begingroup$
    @AaronStevens I read it as "that should really give them a boost [ideologically]", which is great double entendre. No offense, but I am putting my hat back on.
    $endgroup$
    – JEB
    10 hours ago




    2




    2




    $begingroup$
    Well I was shooting for the double entendre.
    $endgroup$
    – Aaron Stevens
    10 hours ago






    $begingroup$
    Well I was shooting for the double entendre.
    $endgroup$
    – Aaron Stevens
    10 hours ago






    2




    2




    $begingroup$
    @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
    $endgroup$
    – Acccumulation
    6 hours ago




    $begingroup$
    @AaronStevens "(of an encoding or function) Having multiple domain elements correspond to one element of the range." en.wiktionary.org/wiki/degenerate
    $endgroup$
    – Acccumulation
    6 hours ago











    6












    $begingroup$

    All (properly functioning) clocks must experience the same time dilation, no matter what mechanism they use to tell time. Otherwise, you could use 2 different clocks to determine your absolute speed, but relativity says that absolute speed isn't a thing.






    share|cite|improve this answer









    $endgroup$













    • $begingroup$
      So, my equation is correct to calculate the dilation of the electronic clock?
      $endgroup$
      – caveman
      6 hours ago






    • 1




      $begingroup$
      @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
      $endgroup$
      – PM 2Ring
      6 hours ago


















    6












    $begingroup$

    All (properly functioning) clocks must experience the same time dilation, no matter what mechanism they use to tell time. Otherwise, you could use 2 different clocks to determine your absolute speed, but relativity says that absolute speed isn't a thing.






    share|cite|improve this answer









    $endgroup$













    • $begingroup$
      So, my equation is correct to calculate the dilation of the electronic clock?
      $endgroup$
      – caveman
      6 hours ago






    • 1




      $begingroup$
      @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
      $endgroup$
      – PM 2Ring
      6 hours ago
















    6












    6








    6





    $begingroup$

    All (properly functioning) clocks must experience the same time dilation, no matter what mechanism they use to tell time. Otherwise, you could use 2 different clocks to determine your absolute speed, but relativity says that absolute speed isn't a thing.






    share|cite|improve this answer









    $endgroup$



    All (properly functioning) clocks must experience the same time dilation, no matter what mechanism they use to tell time. Otherwise, you could use 2 different clocks to determine your absolute speed, but relativity says that absolute speed isn't a thing.







    share|cite|improve this answer












    share|cite|improve this answer



    share|cite|improve this answer










    answered 10 hours ago









    PM 2RingPM 2Ring

    2,9712922




    2,9712922












    • $begingroup$
      So, my equation is correct to calculate the dilation of the electronic clock?
      $endgroup$
      – caveman
      6 hours ago






    • 1




      $begingroup$
      @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
      $endgroup$
      – PM 2Ring
      6 hours ago




















    • $begingroup$
      So, my equation is correct to calculate the dilation of the electronic clock?
      $endgroup$
      – caveman
      6 hours ago






    • 1




      $begingroup$
      @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
      $endgroup$
      – PM 2Ring
      6 hours ago


















    $begingroup$
    So, my equation is correct to calculate the dilation of the electronic clock?
    $endgroup$
    – caveman
    6 hours ago




    $begingroup$
    So, my equation is correct to calculate the dilation of the electronic clock?
    $endgroup$
    – caveman
    6 hours ago




    1




    1




    $begingroup$
    @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
    $endgroup$
    – PM 2Ring
    6 hours ago






    $begingroup$
    @caveman Yes, it is. If it's the right equation for a lightclock, it's the right equation for an electronic clock, or a caesium atomic clock, or a mechanical pendulum clock, or an hourglass. ;)
    $endgroup$
    – PM 2Ring
    6 hours ago













    4












    $begingroup$

    I recommend Feynmann's chapter on this. It is included in Six easy pieces I think. He points out that once you've found the effect for one type of clock (e.g. light pulse clock) then you have found it for all types, because otherwise the different types of clock would get out of step with one another when observed by one observer but stay in step when observed by another. That would be a direct impossibility. For example if one observer says that two clocks go "bong" at the same moment at the same place, then all observers must agree that the bongs happened at the same moment at the same place.



    You can put your electronic clock next to a light pulse clock, both in the same state of overall motion, and then whenever they tick at the same moment in their joint rest frame, that is one joint 'bong'.



    This is also discussed in other introductory texts of course.






    share|cite|improve this answer









    $endgroup$


















      4












      $begingroup$

      I recommend Feynmann's chapter on this. It is included in Six easy pieces I think. He points out that once you've found the effect for one type of clock (e.g. light pulse clock) then you have found it for all types, because otherwise the different types of clock would get out of step with one another when observed by one observer but stay in step when observed by another. That would be a direct impossibility. For example if one observer says that two clocks go "bong" at the same moment at the same place, then all observers must agree that the bongs happened at the same moment at the same place.



      You can put your electronic clock next to a light pulse clock, both in the same state of overall motion, and then whenever they tick at the same moment in their joint rest frame, that is one joint 'bong'.



      This is also discussed in other introductory texts of course.






      share|cite|improve this answer









      $endgroup$
















        4












        4








        4





        $begingroup$

        I recommend Feynmann's chapter on this. It is included in Six easy pieces I think. He points out that once you've found the effect for one type of clock (e.g. light pulse clock) then you have found it for all types, because otherwise the different types of clock would get out of step with one another when observed by one observer but stay in step when observed by another. That would be a direct impossibility. For example if one observer says that two clocks go "bong" at the same moment at the same place, then all observers must agree that the bongs happened at the same moment at the same place.



        You can put your electronic clock next to a light pulse clock, both in the same state of overall motion, and then whenever they tick at the same moment in their joint rest frame, that is one joint 'bong'.



        This is also discussed in other introductory texts of course.






        share|cite|improve this answer









        $endgroup$



        I recommend Feynmann's chapter on this. It is included in Six easy pieces I think. He points out that once you've found the effect for one type of clock (e.g. light pulse clock) then you have found it for all types, because otherwise the different types of clock would get out of step with one another when observed by one observer but stay in step when observed by another. That would be a direct impossibility. For example if one observer says that two clocks go "bong" at the same moment at the same place, then all observers must agree that the bongs happened at the same moment at the same place.



        You can put your electronic clock next to a light pulse clock, both in the same state of overall motion, and then whenever they tick at the same moment in their joint rest frame, that is one joint 'bong'.



        This is also discussed in other introductory texts of course.







        share|cite|improve this answer












        share|cite|improve this answer



        share|cite|improve this answer










        answered 6 hours ago









        Andrew SteaneAndrew Steane

        5,319735




        5,319735






















            caveman is a new contributor. Be nice, and check out our Code of Conduct.










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