Length, Time, and Velocity -- Which are fundamental quantities?

In summary: The resonant frequency of caesium is a far better choice for a universal standard of local time since it is one of the most stable intervals known.The resonant frequency of caesium is about 9.19 GHz, light moves about 3.26 cm in once cycle, which is a nice unit with which to measure something.
  • #1
Keith Koenig
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We think of length and time as the first fundamental quantities and velocity as the first derived quantity but any two determine the third so we would be completely justified in defining velocity as a fundamental quantity and one of length or time as the other, with the remaining being the first derived quantity. Indeed, it may make sense to do so.

Suppose we earthlings are about to join a federation of planets, and we would like to compare our physics with other members. We learn that this federation uses the VA (Vulcan Academy) system of units, where the speed of light has the value of 1c. This is agreeable to all members of the federation, since all members agree on the speed of light. Similarly, the VA defines the peak CMB wavelength, another value all members can agree on, as having the value of 1λ. The first derived quantity is the Sarek (S), where 1S = 1λ/1c.

The greater point is that time without length and speed is meaningless.
 
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  • #3
PeroK said:
:welcome:

The SI unit of time is defined by a caesium clock. The unit of length is defined as the distance light travels in a given time. See:

https://physics.nist.gov/cuu/Units/current.html
I get that, but I was trying to provoke a bit of introspection on basic assumptions that physics makes. Always a good idea, and fun imho.
 
  • #4
Keith Koenig said:
we would be completely justified in defining velocity as a fundamental quantity
Sure. We define the common velocity to be zero (I.e. sharing A common frame of reference) , and then our time and length measurements all agree.

Change our velocity (wrt) the Vulcans, and our measurements change too.
 
  • #5
Having a common value of zero for anything is meaningless. I could claim a quantity exists called "smeorf" that has a default value of zero, but if you multiply your velocity at any point by the proper value of smeorf you obtain another quantity that is proportional to the meaning of life.
 
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  • #6
Keith Koenig said:
Having a common value of zero for anything is meaningless.
Quite the opposite. This entire thread is premised on the acknowledgment that it is not meaningless.

Only when my velocity wrt you is zero (and when yours is zero wrt to me) do we agree on length and time.

To the extent that, if your length and time measurements agree with mine to an arbitrary level of precision, we can conclude that our velocity wrt each is zero.
 
  • #7
OK, my bad, frankly I did not carefully translate wrt to "with respect to", at which point it becomes clear you are thinking relativistically, in which case I agree, with the caveat that it applies most at large velocities. It is interesting that your concern is with defining the value of 0, whereas mine is in defining the value of 1. Both of course are necessary. Good call. Still, it does not address my original point which is that we really can't think that anyone of length, time, or velocity has meaning in and of itself, without the other 2. Something is not long (far if you prefer) unless it takes a long time to get there at some speed. Maybe this is well known and often thought about. I think it has deeper meaning.

Not sure if the usual would be to create a new post or edit this one but I am going with the latter. What exactly is the definition of zero for length and time. We already know it is fuzzy for velocity. Thanks DaveC426913.
 
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  • #8
Velocity of light is not constant. Speed of light (in a vacuum) is. I actually like this universal unit.
Keith Koenig said:
Similarly, the VA defines the peak CMB wavelength, another value all members can agree on, as having the value of 1λ.
This is an incredibly poor choice for a universal standard length since it changes over time and (being a non-local measurement) varies from one location to the next, even for frames in which it is isotropic.
The resonant frequency of caesium is a far better choice for a universal standard of local time since it is one of the most stable intervals known.

That makes the 3rd thing, length, a function of the other two. Since the resonant frequency of caesium is about 9.19 GHz, light moves about 3.26 cm in once cycle, which is a nice unit with which to measure something.
 
  • #9
OK, I'll give you that, but it could be that caesium is extremely rare elsewhere in the universe but certainly a choice can be made using a similar oscillation. And let's give the period and wavelength of the chosen oscillation values of 1. This uniquely determines the value of all speeds in the universe, including of course c, the speed of light. Defining the value of 1 for any of the two uniquely determines all values of the third. No exceptions.
 
  • #10
Keith Koenig said:
OK, I'll give you that, but it could be that caesium is extremely rare elsewhere in the universe but certainly a choice can be made using a similar oscillation. And let's give the period and wavelength of the chosen oscillation values of 1. This uniquely determines the value of all speeds in the universe, including of course c, the speed of light. Defining the value of 1 for any of the two uniquely determines all values of the third. No exceptions.
You seems to be confused by 1) physical quantities, such as length, time, mass and derived quantities such as velocity and energy; 2) the units we use for these quantities, such as the second, kilogram and metre; 3) numbers, such as 0 and 1, which are defined mathematically.
 
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  • #11
PeroK said:
You seems to be confused by 1) physical quantities, such as length, time, mass and derived quantities such as velocity and energy; 2) the units we use for these quantities, such as the second, kilogram and metre; 3) numbers, such as 0 and 1, which are defined mathematically.
I don't think I am at all confused. I am concerned with the definition of the units of fundamental quantities, from which the units of all derived quantities are obtained. To stick with mechanics and leave out charge, the fundamental units are defined to be length, time, and mass. Fundamental also meaning immutable. The first derived quantity is velocity, with units length/time. The next are momentum (mass*length/time) and acceleration(length/time/time). Next of course we have Force (mass*length/time/time) and Energy (mass*length*length/time/time). Surely you agree with that.

Surely you would not dispute that every "length/time" in the above enumeration of physical quantities and their units in mechanics could be replaced with velocity.

So far as I am aware, and please correct me if I am wrong, but there is no principal by which we are compelled to define length and time as fundamental, especially since time is always measured with something that is moving, in other words has velocity, usually an oscillation.

We could instead define the fundamental units as length and velocity. Then the first derived quantity is time, with units length/velocity. The next are momentum (mass*velocity) and acceleration(velocity/time = velocity/length/velocity = velocity*velocity/length. Next of course we have Force (mass*velocity/time = mass*velocity*velocity/length) and Energy (mass*velocity*velocity). Surely you agree with that.
 
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  • #12
Keith Koenig said:
So far as I am aware, and please correct me if I am wrong, but there is no principal by which we are compelled to define length and time as fundamental,
SI units take take the speed of light as fundamental. Length is derived from that.
Keith Koenig said:
We could instead define the fundamental units as length and velocity.
Yes, but time and velocity (in SI) is preferred, for practical purposes.
 
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  • #13
Keith Koenig said:
I am concerned with the definition of the units of fundamental quantities, from which the units of all derived quantities are obtained. To stick with mechanics and leave out charge, the fundamental units are defined to be length, time, and mass. Fundamental also meaning immutable.
I'm not sure what is meant by fundamental here. What does it mean for a quantity to be immutable?

There is obviously a relationship between length, time, and velocity. When two of them are defined, so is the third one. But I don't see how that means that one is more fundamental (whatever that means) than the others.

Keith Koenig said:
We could instead define the fundamental units as length and velocity.
Why do you choose length instead of time as fundamental?

Do we now live in a "spacevelocity" continuum? So instead of telling you «Let's meet in two hours, in the park», it would be better to say «Let's meet at 25 km/h in the park»? And just like "the park" has an implied direction (displacement is a vector), velocity must also have an implied direction, which wouldn't be the same for both persons. Very confusing.

The only reason I can think of for choosing length and time as "fundamental" units is that they are quantities that are easier to measure, easier to conceive, easier to relate to.
 
  • #14
Keith Koenig said:
the fundamental units are defined to be length, time, and mass.
Mass, length, and time are dimensions, not units. So you should say that the fundamental dimensions are defined to be mass, length, and time.

This is true in SI units, but different unit systems use different dimensions. SI units also include current and a couple of other fundamental dimensions, but cgs units do not have a separate electrical dimension. Many of the formulas of electromagnetism are different in cgs than in SI units because the electrical units have different dimensions in the two systems. This idea of reducing the fundamental dimensions is taken to its extreme in geometrized units where the only dimension is length.

So it is already well known that the fundamental dimensions are an arbitrary choice that is part of what defines a system of units.
 
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  • #15
This thread seems to be philosophy, and not very good philosophy at that. Until there is a commonly agreed upon measure of fundamentalness, this is just personal preference.
 
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  • #16
Vanadium 50 said:
Until there is a commonly agreed upon measure of fundamentalness
I vote that the SI unit of fundamentalness be the Point (P), so when we can't specify its value the topic can be said to be Pointless.
 
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  • #17
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Keith Koenig said:
We could instead define the fundamental units as length and velocity.
OK, but what would change other than some words?

I am also not sure how to construct a velocity "meter" that doesn't use a ruler and a clock. Maybe I am just not very creative today.
 
  • #19
gmax137 said:
I am also not sure how to construct a velocity "meter" that doesn't use a ruler and a clock.
Doppler Radar.
 
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  • #20
Dale said:
Mass, length, and time are dimensions, not units. So you should say that the fundamental dimensions are defined to be mass, length, and time.

This is true in SI units, but different unit systems use different dimensions. SI units also include current and a couple of other fundamental dimensions, but cgs units do not have a separate electrical dimension. Many of the formulas of electromagnetism are different in cgs than in SI units because the electrical units have different dimensions in the two systems. This idea of reducing the fundamental dimensions is taken to its extreme in geometrized units where the only dimension is length.

So it is already well known that the fundamental dimensions are an arbitrary choice that is part of what defines a system of units.
That may be a matter of semantics. A quick google search for "fundamental properties of physics" gives this as the first hit: https://www.texasgateway.org/resource/13-language-physics-physical-quantities-and-units#:~:text=In physics, there are seven,of substance, and luminous intensity.

My understanding of the definition of immutable is that it cannot be broken down into smaller parts, though a quick google search of that term yields "unchanging over time or unable to be changed."

Using the former definition, a Newton for example is not immutable since it can be broken down dimensionally to ##kg \cdot \frac{m}{s^2}##

The point I was trying to make, and perhaps Vanadium 50 is correct in that this is more philosophical than anything, is that we cannot really think that time exists independently of length and velocity. In a "heat death" universe where everything is at absolute zero and all motion has stopped, there would be no time, imho. It seems an interesting concept. Not earth-shattering, but interesting nonetheless.
 
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  • #21
Keith Koenig said:
That may be a matter of semantics.
Indeed, but when communicating complicated concepts it is helpful to use the standard semantics.

Keith Koenig said:
we cannot really think that time exists independently of length and velocity
Why would we think that anything exists independently of anything else? Designating a set of fundamental units doesn’t have that implication at all.

Keith Koenig said:
In a "heat death" universe where everything is at absolute zero and all motion has stopped, there would be no time, imho.
That isn’t at all in keeping with current cosmology. Time doesn’t end at heat death according to any reputable source I have read
 
  • #22
Keith Koenig said:
In a "heat death" universe where everything is at absolute zero and all motion has stopped, there would be no time, imho.
Not sure it follows that time stops in a heat death universe, @Keith Koenig. Do we understand what time is in the first place to make that determination? We commonly describe it as progression of events, often using terms such as 'past' and 'present' and 'future', and in that sense, heat death would result in the apparent cessation of time, but is that the same thing as "there would be no time"?
 
  • #23
Keith Koenig said:
Using the former definition, a Newton for example is not immutable since it can be broken down dimensionally to ##kg \cdot \frac{m}{s^2}##
But with the US unit system, a pound (force) is defined as the 'fundamental' unit and thus 'immutable'. The mass is a slug, which can be broken down dimensionally to ##lb \cdot \frac{s^2}{ft}##.

That is what people here are trying to show you: It all depends on what you define as 'fundamental'.
 
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  • #24
Would it be reasonable to say that dimensional units are basically meaningless unless we are comparing two quantities?
 
  • #25
They are not useless. If I ask 'please make 1 of 1 NaCl' (1L of 1.0M NaCl) -- it is unintelligible. You will notice that all of the advisors are always asking newbies to use units. There are many good reasons to do this.

PS: same goes for cooking using recipes, purchases of gasoline, milk, cheese ... ad nauseum.
 
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  • #26
I think what this thread might be about is the difference between knowing there are physical units, and being able to measure them.
If there is a heat death of the universe, will temperatures be measurable even when they still exist? Will any measurement be possible of a background in which there are no comparable differences?

Physics is possible because it's relatively easy to compare measurements, at least it is in this era.
 
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Believe me, just because a measurement is boring doesn’t mean that it cannot be done.
 
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  • #28
The distinction between fundamental and derived quantities is arbitrary. The universe doesn't prefer one system over another, so we generally choose whatever is easiest to comprehend and work with, a.k.a. whatever keeps engineers happy.
 
  • #29
David Lewis said:
The distinction between fundamental and derived quantities is arbitrary. The universe doesn't prefer one system over another, so we generally choose whatever is easiest to comprehend and work with, a.k.a. whatever keeps engineers happy.
Putting an engineer's hat on, we do not care whether the meter is fundamental and the speed of light is derived or whether the speed of light is fundamental and the meter is derived.

We care whether our meter sticks and calipers are going to have to be swapped out due to a change in units.
 
  • #30
Keith Koenig said:
So far as I am aware, and please correct me if I am wrong, but there is no principal by which we are compelled to define length and time as fundamental, especially since time is always measured with something that is moving, in other words has velocity, usually an oscillation.
It is more precise to define things the way BIPM does. This is the science of metrology, not physics. Theoretically you could have velocity as a fundamental unit, but that would be a less precise way of defining units of measure.

Keith Koenig said:
Something is not long (far if you prefer) unless it takes a long time to get there at some speed.

If I have two sticks at rest wrt me, I can compare their lengths and tell you which one is longer and by how much. I don't need to refer to a unit of time or of velocity.

When we measure a length we are simply comparing that length to the standard.
 
  • #31
jack action said:
But with the US unit system, a pound (force) is defined as the 'fundamental' unit and thus 'immutable'.

The pound used in the US is defined as 0.453 592 37 kg.
 
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  • #32
Mister T said:
The pound used in the US is defined as 0.453 592 37 kg.
I was referring to the British gravitational system where the pound is used to define a force and the slug is used for mass.
 
  • #33
jack action said:
I was referring to the British gravitational system where the pound is used to define a force and the slug is used for mass.
But if one goes tracing a definition for the pound force in this system, one is likely to find it specified in terms of the avoirdupois pound (mass) and, thus, the kilogram together with an arbitrary number corresponding to one of the standard accelerations of gravity.
 
  • #34
jack action said:
I was referring to the British gravitational system where the pound is used to define a force and the slug is used for mass.
There is no officially-sanctioned definition of the pound force. There used to be an officially-sanctioned definition of the kilogram force which relied on 9.806 65 N/kg as the standard value for the free fall acceleration. No such scheme was ever created for the pound force.
 
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  • #35
Mister T said:
There is no officially-sanctioned definition of the pound force.
I have also never seen an official definition of the pound force. The only official definition I have ever seen for the pound was that the pound is exactly 0.45359237 kg. That makes it a unit of mass
 
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