Cauchy sequences and continuity versus uniform continuity

In summary, a Cauchy sequence is a special type of sequence in mathematics that satisfies the Cauchy criterion, while a normal sequence does not necessarily satisfy this criterion. Continuity is a function that has no abrupt changes, while uniform continuity requires a consistent rate of change throughout the entire domain. Cauchy sequences are important in defining completeness in a metric space, and they are closely related to the concept of uniform continuity. A function can be continuous but not uniformly continuous, as demonstrated by the function f(x) = 1/x.
  • #1
renjean
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Homework Statement



This isn't really a problem but it is just something I am curious about, I found a theorem stating that you have two metric spaces and f:X --> Y is uniform continuous and (xn) is a cauchy sequence in X then f(xn) is a cauchy sequence in Y.

Homework Equations



This proposition is for uniform continuity but I am wondering if it also holds true for just regular continuity.
 
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  • #2
Think about f(x)=1/x
 

1. What is a Cauchy sequence and how is it different from a normal sequence?

A Cauchy sequence is a special type of sequence in mathematics that satisfies the Cauchy criterion, which states that for any positive real number, there exists a point in the sequence after which all succeeding points are within that distance from each other. This is different from a normal sequence, where the points may get arbitrarily close to each other, but do not necessarily satisfy this specific criterion.

2. How is continuity different from uniform continuity?

Continuity is a mathematical concept that describes a function that has no abrupt changes or breaks. This means that as the input values of the function change, the output values change smoothly and continuously. Uniform continuity, on the other hand, is a stronger condition that requires the function to have a consistent rate of change throughout its entire domain, rather than just at isolated points.

3. What is the importance of Cauchy sequences in mathematics?

Cauchy sequences are important in mathematics because they help to define the concept of completeness in a metric space. This means that a metric space is considered complete if and only if every Cauchy sequence in that space converges to a point within the space. Completeness is a fundamental concept in analysis and is used in various branches of mathematics, including real analysis, abstract algebra, and functional analysis.

4. How do Cauchy sequences relate to the concept of uniform continuity?

Cauchy sequences and uniform continuity are closely related in that both concepts involve the idea of points staying close to each other. In the case of Cauchy sequences, this closeness is measured by the distance between points in the sequence, while in uniform continuity, it is measured by the rate of change of the function. Both concepts are important in understanding the behavior of functions and their limits.

5. Can a function be continuous but not uniformly continuous?

Yes, a function can be continuous but not uniformly continuous. For a function to be uniformly continuous, it must have a consistent rate of change throughout its entire domain. However, a function can still be continuous at isolated points even if it does not have a uniform rate of change. An example of this is the function f(x) = 1/x, which is continuous but not uniformly continuous on its domain of (0,∞).

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