Weierstrass approach to analysis

In summary, Weierstrass' approach to analysis differed from the classical approach, i.e. Leibniz's and Newton's calculus, in that he was the first to provide a truly mature and rigorous approach to calculus by systematizing the use of the "epsilon/delta"-approach. While Cauchy is often credited as the inventor of the epsilon-delta formulation, Weierstrass and his students actually found flaws in Cauchy's proofs and redid them, leading to the Cauchy-Kawalevsky theorem. However, Cauchy's original proofs lacked precise convergence concepts, which were later clarified by Bolzano and then formalized by Heine, a student of Weierstrass.
  • #1
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how does weierstrass' approach to analysis differ from the classical approach, i.e leibnizs' and Newton's calculus?
 
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  • #2
Since Weierstrass was the one systematizing the "epsilon/delta"-approach to calculus, you might say that Weierstrass was the first to provide a truly mature and rigorous approach to calculus.
 
  • #3
And how does Cauchy fit in that picture? I thought he was the one who invented the epsilon-delta formulation
 
  • #4
quasar987 said:
And how does Cauchy fit in that picture? I thought he was the one who invented the epsilon-delta formulation
I said that Weierstrass SYSTEMATIZED the use of this technique; I didn't say he was the the first to have these ideas.
 
  • #5
Weierstrasse and his students found Cauchy's proofs imperfect and redid them. That's why we have, e.g. the Cauchy-Kawalevsky theorem.
 
  • #6
Cool.

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  • #7
I thought Cauchy was the only mastermind behind epsilon-delta calculus. Did Weierstrass and friends also discovered new basics theorems that Cauchy had missed?
 
  • #8
I think that some of the major problems in Cauchy's original proofs were due to the lack of precise convergence concepts, like pointwise convergence vs. uniform convergence.
 
  • #9
the first reasonably clear definition of continuity may be due to Bolzano, who wrote in 1817 the following definition (in German): f is continuous at x, if and only if "...the difference f(x+h)-f(x) can be made smaller than any given quantity, if h is taken sufficiently small."

In the following proof of the intermediate value theorem he then uses an epsilon for the "given quantity".

Cauchy, writing 6 years later, in 1823, gives the following somewhat less clear definition: " ..the magnitude of the difference f(x+h)-f(x) decreases indeifinitely with that of h."

He clarifies this somewhat as follows: I.e. "an infinitesimal increment in the variable produces an infinitesimal increment in the function itself." where he has explained that an infinitesimal is a quantity whose "successive absolute values decrease indefinitely so as to become less than any given quantity."

the modern definition which needs only to write the letter epsilon for bolzano's "given quantity", as he himself does in his proofs, was published first by heine, a student of weierstrass, in 1874, following lectures of weierstrass.

it is difficult for a modern person to see the real difference in some of these definitions, once one knows what they mean. Indeed I have seen quotations form Newton which sounded essentially like the modern definition of limit. at least one is easily persuaded that the master understood the true meaning very well.

indeed if one spells out the meaning of cauchy's definition as he himself gave it, it is the same. so it seems to me that these workers did themselves understand the meaning of continuity as we do today.

there seems little doubt however that, as has been stated, cauchy did not appreciate the distinction between continuity and uniform continutiy, nor that between convergence and uniform convergence, and made errors or at least omissions of that nature.

the translations i have used here are from "A Source book of classical analysis", Harvard university Press, edited by Garrett Birkhoff. :tongue:

as to why weierstrass and not bolzano gets credit for epsilon - delta continuity, it seems there is a distinction between originating a concept and influencing others to do so. i.e. bolzano may have led the way himself, but did so in papers devoted almost exclusively to such foundations, so few followed, while others like cauchy were more interested in applying these notions to questions about integrals and series.

thus people interested in cauchy's theorems gave him credit for introducing the new methods he was using, even though those were in fact more primitive than the earlier ones of bolzano. finally it seems weierstrass and his students used almost the same formulation as bolzano but applied it to current topics of interest.

it is odd for example that a theorem could be known as the bolzano - weierstrass theorem, when the two men worked some 50 years apart. possibly it was discovered first by bolzano but rediscovered and popularized by weierstrass. (of course there is also a stone - weierstrass theorem and a riemann - kempf theorem, and a gauss - bonnet - chern theorem,...,in which there is 80-120 years separating the two workers, but in those cases the new results mentioned are significant generalizations of the older ones. In fact a friend of mine once asked Stone just when he had worked with Weierstrass.)

on another thread there is a principle mentioned called there the "arnol'd principle", that if a certain concept or theorem carries a person's name, then it is almost certain that person did not originate that principle. it is then mentioned that indeed arnol'd is not responsible for this principle.
 
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  • #10
by the way bolzano clearly states and fairly well proves the so called "cauchy criterion" for convergence in 1817. see p.15 of the source book cited above.
 
  • #11
arildno said:
Since Weierstrass was the one systematizing the "epsilon/delta"-approach to calculus, you might say that Weierstrass was the first to provide a truly mature and rigorous approach to calculus.
from what i read his approach had left behind the infinitisemals for the the epsilon-delta formulation, but i also read that abraham robinson had resurrected the infinitisimal formulation on a better rigorous formulation, in what now is called Non-Standard Analysis (NSA), how do these approaches differ from each other, and what makes NSA non-standard?
 
  • #12
loop quantum gravity said:
from what i read his approach had left behind the infinitisemals for the the epsilon-delta formulation, but i also read that abraham robinson had resurrected the infinitisimal formulation on a better rigorous formulation, in what now is called Non-Standard Analysis (NSA), how do these approaches differ from each other, and what makes NSA non-standard?
I hope math-wizzes like Hurkyl, M.G, or mathwonk can give you a bit of solid info on robinson's approach, but here's a few schematic details on the history of analysis that I don't think is too misleading:

1. As mathwonk has said, the limit concept has been around a long time; formulations by Newton and Bolzano is at times essentially indistinguishable from modern versions. (I would also like to include Archimedes here; his ideas isn't really that far from modern ideas, and the proofs he gives are at times, I believe, up to modern standards of rigour).

2. However, it is by Cauchy we find the origin of the epsilon/delta-formulation (by which ideas of infinitesemals became superfluous), but his texts are at times not careful enough to distinguish between various forms of continuity/convergence (see mathwonk's reply)

3. Weierstrass and his students recognized the difficulties in Cauchy's original work, and took upon themselves to give his maths a major overhaul to make it fully rigorous

4. Robinson realized that it was possible to revive the concepts of infinitesemals, but that in order to do so properly and rigorously, he had to "leave" the number system called "reals", and invent a number system sufficiently subtle to include "infinitesemals" (I think this goes under the name of surreals, but I'm not too sure on that issue).
So, his first task was to develop a good axiomatic structure governing his new number system, and then "translate" the concepts from standard analysis (which lives in the real (or complex) number system)) into his own number system.
 
  • #13
surreal numbers are john conway's innovation, i think robinson's is the hyperreal numbers.
anyway, I've read also about someone's interpratation that replaces the number system to decimals (from the reals), although it puzzled me bacause decimals are just different representatives of the reals, isn't it?!
ill probably need to find it once more to undersatnad what it's really about.
 
  • #14
loop quantum gravity said:
from what i read his approach had left behind the infinitisemals for the the epsilon-delta formulation, but i also read that abraham robinson had resurrected the infinitisimal formulation on a better rigorous formulation, in what now is called Non-Standard Analysis (NSA), how do these approaches differ from each other, and what makes NSA non-standard?

Real numbers can be constructed from natural numbers. Hyperreal numbers, extensions of the real numbers on which non-standard analysis is based, are constructed from non-standard models of the natural numbers.

An elementary calculus book,

"Elementary Calculus: An Approach Using Infinitesimals
On-line Edition, by H. Jerome Keisler

This is a calculus textbook at the college Freshman level based on Abraham Robinson's infinitesimals, which date from 1960. Robinson's modern infinitesimal approach puts the intuitive ideas of the founders of the calculus on a mathematically sound footing, and is easier for beginners to understand than the more common approach via limits.

The First Edition of this book was published in 1976, and a revised Second Edition was published in 1986, both by Prindle, Weber & Schmidt. The book is now out of print and the copyright has been returned to me as the author. I have decided (as of September 2002) to make the book available for free in electronic form at this site. These PDF files were made from the printed Second Edition.",

based on non-standard analysis is available here. Hyperreal numbers are first discussed in a section that begins on page 21. The Epilogue relates non-standard analysis to the standard [itex]\epsilon - \delta[/itex] view of limits.

What little I used to know about the relationship between hyperreals and surreals, I, unfortunately, have forgotten.

Regards,
George
 
  • #15
The surreals are, essentially, the "master" ordered field: every small ordered field can be embedded in the surreal numbers.

(small simply means that the elements of the field will fit into a set)


But since the surreals are so large (they do not fit into a set), they're fairly unwieldy.


The reason nonstandard analysis is called "nonstandard" comes from model theory. I could, for example, create a theory by writing down a list of all the axioms of the real numbers in first-order logic. Then, the set of real numbers can be used to form a model of this theory.

However, the real numbers are not the only model of these axioms! There are other models, like the real algebraic numbers, or the hyperreal numbers. These other models are called non-standard models. Internally, these other models are indistinguishable from the reals; you can only tell them apart by appealing to the set theory in which these models reside. (i.e. looking at it externally)


Non-standard analysis is based upon studying the relationship between a standard model of analysis (built upon the reals) and a non-standard model of analysis (built upon the hyperreals), thus the name.
 
  • #16
here's the paper i mentioned in my previous post, the author of the ideas listed there is prof alexander abian:
http://www.fidn.org/notes1.pdf [Broken]
 
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1. What is the Weierstrass approach to analysis?

The Weierstrass approach to analysis is a method used in mathematical analysis to prove the existence of a continuous function on a closed interval. It was developed by German mathematician Karl Weierstrass in the 19th century.

2. How does the Weierstrass approach differ from other approaches to analysis?

The Weierstrass approach differs from other approaches to analysis in that it focuses on constructing a continuous function using a series of simpler functions, rather than directly proving the existence of a continuous function. This allows for more flexibility and makes it easier to prove the existence of a continuous function in more complex cases.

3. What is the main idea behind the Weierstrass approach?

The main idea behind the Weierstrass approach is that any continuous function can be approximated by a sequence of simpler functions, such as polynomials or trigonometric functions. By using these simpler functions, we can construct a continuous function that closely resembles the original function.

4. What are some applications of the Weierstrass approach in mathematics?

The Weierstrass approach has many applications in mathematics, particularly in real analysis and the study of function spaces. It is used to prove the existence of continuous functions in various mathematical theorems, such as the intermediate value theorem and the Stone-Weierstrass theorem. It is also used in the construction of fractals and in the study of Fourier series.

5. Are there any limitations to the Weierstrass approach?

While the Weierstrass approach is a powerful tool in mathematical analysis, it does have some limitations. It can only be used to prove the existence of a continuous function, not its uniqueness. Additionally, it can be difficult to determine the rate of convergence of the series of simpler functions, leading to potential errors in the approximation of the original function.

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