Are complex numbers just means to an end?

In summary, imaginary numbers are used in intermediary steps of predictive theories such as in quantum mechanics and signal processing. However, it is possible to solve problems without using complex numbers and they are not directly measurable in nature. Real numbers can also be seen as a means to an end in modeling and understanding the world.
  • #1
jaydnul
558
15
Do we use imaginary numbers just in the intermediary steps of a predictive theory? For example, in QM, in order to make predictions in the real world, you square the wave function. The wave function might have have all the information, but in order to predict something you must operate on it to remove the imaginary numbers. Is it like this in other areas, like EE, or can you have a predictive answer in terms of imaginary numbers?
 
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  • #2
In signal processing you certainly can have meaningful imaginary numbers. Basically, all you need is to have a signal where the magnitude and the phase both encode meaningful information.
 
  • #3
Complex numbers are very useful as a means to an end. But even if they weren't so useful, we'd still study them before they're so fascinating in their own right.
 
  • #5
You can't measure an imaginary number in nature...You can measure the coefficient (real number) of [itex]i[/itex] of the imaginary part of a complex number, but not actually measure an imaginary number. Laws of physics may take a more convenient form in terms of complex numbers, but I think it can be proved that all algebraic manipulations can be done without recourse to complex numbers as well as contour integration.
 
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  • #6
julian said:
You can't measure an imaginary number in nature...You can measure the coefficient (real number) of [itex]i[/itex] of the imaginary part of a complex number, but not actually measure an imaginary number. Laws of physics may take a more convenient form in terms of complex numbers, but I think it can be proved that all algebraic manipulations can be done without recourse to complex numbers as well as contour integration.
How do you "measure a real number in nature"?
 
  • #7
HallsofIvy said:
How do you "measure a real number in nature"?

Now we are getting into the nature of reality and numbers...interesting mathematical and philosophy issue? Not qualified to say much. If others know more about this I'd like to hear about it.
 
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  • #8
Recently looking back at some fluid mechanics notes and found that problems that can be formulated as a complex o.d. diff equation were equivalent to a pair of real coupled partial diff equations. So they are not just convenient for QM calculations...
 
  • #9
julian said:
Now we are getting into the nature of reality and numbers...interesting mathematical and philosophy issue? Not qualified to say much. If others know more about this I'd like to hear about it.
Well, you were the one who said "You can't measure an imaginary number in nature...You can measure the coefficient (real number) of i of the imaginary part of a complex number, but not actually measure an imaginary number."

What did you mean by that? I see no reason to think that "complex numbers are just a means to an end" is any more true (or false) than the same statement about real numbers.
 
  • #10
HakimPhilo said:

Fluid mechanics: It isn't just 2D flow. There are problems that are more easily solved by a complex o.d. diff equation, namely problems involving sinusoidal oscillations. QM involves sinusoidal oscillations - hmm.
 
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  • #11
HallsofIvy said:
Well, you were the one who said "You can't measure an imaginary number in nature...You can measure the coefficient (real number) of i of the imaginary part of a complex number, but not actually measure an imaginary number."

What did you mean by that? I see no reason to think that "complex numbers are just a means to an end" is any more true (or false) than the same statement about real numbers.
Well you could call it measuring a complex number but really you are measuring the real numbers that can be extracted from the complex number, for example [itex]a[/itex] and [itex]b[/itex] from [itex]z = a + ib[/itex] or with [itex]z = R e^{i \theta}[/itex] we can extract [itex]R[/itex] and [itex]\theta[/itex]. Formulation of problem to solution can be done without recourse to complex numbers though.
 
  • #12
julian said:
Well you could call it measuring a complex number but really you are measuring the real numbers that can be extracted from the complex number, for example [itex]a[/itex] and [itex]b[/itex] from [itex]z = a + ib[/itex] or with [itex]z = R e^{i \theta}[/itex] we can extract [itex]R[/itex] and [itex]\theta[/itex]. Formulation of problem to solution can be done without recourse to complex numbers though.

Except you can't measure (observe) real numbers either because we don't have infinite precision. We model with the real numbers. Heck you can still do the most important aspects of calculus without the reals, this is called computable analysis.
 
  • #13
pwsnafu said:
computable analysis.

It brings up the Gödel's incompleteness theorem by which we as humans can understand things that would take and infinite number of computations.
 
  • #14
How do you prove that axb = bxa in a computable manner? It is obvious that this is right, but how do you do this via a computable manner for all a and b? Possibly I could be misunderstanding.
 
  • #15
julian said:
You can't measure an imaginary number in nature...You can measure the coefficient (real number) of [itex]i[/itex] of the imaginary part of a complex number, but not actually measure an imaginary number. Laws of physics may take a more convenient form in terms of complex numbers, but I think it can be proved that all algebraic manipulations can be done without recourse to complex numbers as well as contour integration.

If you can measure a real number, you can measure a complex one. You can measure phase and amplitude of some physical quantity.
 
  • #16
You can't measure a physical quantity to be [itex]i[/itex] for example, that was my original point.
 
  • #17
And you cannot measure a physical quantity to be [itex]\sqrt{2}[/itex] (or even 2). That was my (and others) point.
 
  • #18
The first paragraph or so of http://math.buffalostate.edu/~MED600/signednumbrs/jacobstm.pdf quotes an amusing and relevant anecdote by Isaac Asimov.
 
  • #19
HallsofIvy said:
And you cannot measure a physical quantity to be [itex]\sqrt{2}[/itex] (or even 2). That was my (and others) point.

What if a certain quantum observable takes discrete values? Assuming QM and its predictions are right. If you measure it to be in a definite discrete quantum state and then that eigenvalue is determined exactly.

EDIT: fundamental constants may not be determined exactly.
 
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  • #20
This is deviating away from the OP question. There will be a proof that what can be expressed via the real numbers associated with complex numbers, and the intermediate steps in a calculation involving complex number's rules can all be done without recourse to complex numbers. This is the case in physics where nothing can be measured as [itex]i[/itex] or proportional to [itex]i[/itex], however maths people want solutions to [itex]\sqrt{-1}[/itex].
 
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  • #21
julian said:
What if a certain quantum observable takes discrete values? Assuming QM and its predictions are right. If you measure it to be in a definite discrete quantum state and then that eigenvalue is determined exactly.

No. This is what I'm telling you. We don't have instruments with infinite precision...or even anywhere near Plank's distance. The quantity predicted in the model will still be a random variable when we do the observation. You need to realize measuring a quantity is different from the quantity itself, which in turn is different from the prediction of the quantity from the model (in this case QM). This is why in stats we distinguish X and x.

But this is turning into a metrology thread.

julian said:
This is deviating away from the OP question. There will be a proof that what can be expressed via the real numbers associated with complex numbers, and the intermediate steps in a calculation involving complex number's rules can all be done without recourse to complex numbers. This is the case in physics where nothing can be measured as [itex]i[/itex] or proportional to [itex]i[/itex], however maths people want solutions to [itex]\sqrt{-1}[/itex].

This is like arguing that every real number is a sequence of rationals, so we can do all our math in Q. "There is no such thing as a true model, just useful ones."
 
  • #22
pwsnafu said:
No. This is what I'm telling you. We don't have instruments with infinite precision...or even anywhere near Plank's distance. The quantity predicted in the model will still be a random variable when we do the observation. You need to realize measuring a quantity is different from the quantity itself, which in turn is different from the prediction of the quantity from the model (in this case QM). This is why in stats we distinguish X and x.

But this is turning into a metrology thread.
This is like arguing that every real number is a sequence of rationals, so we can do all our math in Q. "There is no such thing as a true model, just useful ones."

In principle if we had in a sense `ideal' measuring devices then, plus as the eigenvalue distance between discrete eigenvalues is finite then that is the exact eigenstate projected onto.

I know of work done by people on the use of realistic measuring devices, I wasn't going to get into that.

There was this programme on the BBC "Horizon" U.K. called how long is a piece of string? It ended with the need to measure with precise accuracy then induces photons of such high frequency that it would induce black holes. Still loop quantum gravity people say that geometric variables have precise eigenvalues even at the Plank scale. I contacted the BBC and Rovelli, Rovelli said he would be very interested in a follow up but nothing came of it.

I don't see how to get out [itex]i[/itex] from the say real numbers analogous to how we get the reals from the rationals. No experiment I know of has ever measured something to be proportional to [itex]i[/itex]. Purely mathematical invention which physicists find useful but can do without.
 
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What are complex numbers?

Complex numbers are numbers that have both a real and an imaginary component. They are typically represented in the form a + bi, where a is the real part and bi is the imaginary part, with i being the imaginary unit equal to the square root of -1.

What are complex numbers used for?

Complex numbers are used to represent quantities that involve both real and imaginary components, such as electrical currents, sound waves, and quantum mechanics. They are also used in engineering, physics, and other scientific fields to solve mathematical problems and equations that involve imaginary numbers.

Are complex numbers just a mathematical concept or do they have practical applications?

Complex numbers have both theoretical and practical applications. In mathematics, they are used to solve equations that involve imaginary numbers, and in physics and engineering, they are used to model and analyze complex systems.

Can complex numbers be visualized?

Although complex numbers cannot be represented on a traditional number line, they can be visualized on a complex plane. This is a two-dimensional plane where the real numbers are plotted on the x-axis and the imaginary numbers are plotted on the y-axis.

Do complex numbers have real-world significance?

Yes, complex numbers have real-world significance in various fields, including physics, engineering, and economics. They are used to solve complex equations and model real-world phenomena, making them an important tool in understanding and analyzing complex systems.

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