Exploring the Discontinuity of Fundamental Quantities and Calculus

In summary: There have been sporadic efforts to redefine calculus for discontinuous functions. The most successful example is probably calculus of variations, which is used for problems like optimisation or control.
  • #1
meaw
19
0
i wondered at the idea that calculus works for continuous functions and in reality fundamental quantities are discontinuous. For example energy or an electron can't asume all values. Therefore isn't there a conflict when we work on a equation like dE/dt or something similar which involve calculus of discountinous things ?
 
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  • #2
Mathematics is not physics. No mathematical model can be expected to work perfectly. That is taken into account when developing a mathematical model for a physical situation.
 
  • #3
"No mathematical model can be expected to work perfectly" - you mean it really ? Then why are we so bothered about mathematical inconsistencies when GR and QM are put together ? Unless you are hiniting at thephylosophical question of whether maths is invented or discovered, the general believe is that Maths is reality. Maybe I misread you. Can you clarify ?
 
  • #4
It is certainly possible to do physics without ever introducing continuous quantities, but it's just that much more cumbersome. In a way, we use things like real numbers or calculus as shorthands for large structures which are well-regulated. The fact that this is often ignored is an unfortunate state of affairs, but textbooks have to draw a line somewhere. In practice, physicists will often do things like use integration when they are talking about discrete sums, as long as the results are reasonable.
 
  • #5
right you are. I am wondering whether any attempts have been made to redefine calculus for discountinouous functions where the discontinuity is of the order of plank's constant which can be ignored for general physics but not so for quantum mech.
 
  • #6
Inside differential geometry (which is basically just calculus on curved manifolds) there is a large combinatorial, simplicial structure. Google for "discrete differential forms". These have found good use in numerical simulations, where things have to be discretised for computation. Similarly, things like lattice QCD or Regge calculus in GR have similar backgrounds.
 
  • #7
There are discrete analogs for the derivative and the integral: the finite difference operator and discrete summation. It's just that a lot of the time, its much easier to do the continuous version, and the results are reasonable.
 

1. What is the discontinuity of fundamental quantities and calculus?

The discontinuity of fundamental quantities and calculus refers to a gap or break in the relationship between two fundamental quantities or in the continuity of a mathematical function. This can occur when there is a sudden change or jump in the values of the quantities or the function.

2. Why is it important to explore the discontinuity of fundamental quantities and calculus?

Studying the discontinuity of fundamental quantities and calculus is important because it helps us better understand the behavior of these quantities and functions. It also allows us to identify potential errors or limitations in our mathematical models and theories.

3. How is the discontinuity of fundamental quantities and calculus represented graphically?

The discontinuity of fundamental quantities and calculus can be represented graphically by a break or jump in the graph of a function, or by a vertical or horizontal asymptote. It can also be shown by a discontinuous or undefined point on a graph.

4. What causes discontinuity in fundamental quantities and calculus?

Discontinuity in fundamental quantities and calculus can be caused by a variety of factors, such as a change in physical conditions, an error in measurement, or a flaw in the mathematical model being used. It can also be a result of the limitations of our current understanding and technology.

5. How can we mitigate the effects of discontinuity in fundamental quantities and calculus?

To mitigate the effects of discontinuity in fundamental quantities and calculus, scientists and mathematicians often use techniques such as smoothing functions, interpolation, or extrapolation to fill in the gaps and create a continuous representation. However, it is important to acknowledge and account for the potential errors and uncertainties that may arise from these methods.

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