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Introduction

In mathematics, a sequence is an ordered list of elements that follow a certain pattern. A converging sequence is a sequence of numbers that approaches a particular value as the number of terms in the sequence increases indefinitely. This means that as the sequence continues, the difference between its terms and the limiting value becomes smaller and smaller, eventually approaching zero.

A converging sequence is a fundamental concept in calculus, as it allows for the study of limits and infinite series. It is also essential in physics and engineering, where it is used to model physical phenomena and make predictions about the behavior of complex systems.

One of the most famous examples of a converging sequence is the sequence of Fibonacci numbers. This sequence starts with the numbers 0 and 1, and each subsequent number is the sum of the two preceding numbers. Thus, the first few terms of the sequence are 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, and so on.

As the sequence continues, the ratio of successive terms approaches the golden ratio, which is approximately 1.6180339887. In other words, the difference between successive terms becomes smaller and smaller, eventually approaching zero, and the sequence approaches the golden ratio as the number of terms increases.

The concept of a converging sequence can be formalized using the notion of limits. In calculus, a limit is a value that a function or sequence approaches as its input or index approaches a particular value. The limit of a converging sequence is the value that the sequence approaches as the number of terms in the sequence increases indefinitely.

To illustrate the concept of a limit, consider the sequence 1, 1/2, 1/3, 1/4, 1/5, and so on. As the sequence continues, the terms become smaller and smaller, approaching zero. However, the sequence never reaches zero, as there is always a positive term left in the sequence. Thus, we say that the limit of this sequence is zero, and we write:

lim(n->?) 1/n = 0

This notation means that as n (the index of the sequence) approaches infinity, the value of 1/n approaches zero.

Another famous example of a converging sequence is the harmonic series, which is the sum of the reciprocals of the positive integers. The harmonic series can be written as:

1 + 1/2 + 1/3 + 1/4 + 1/5 + …

As the number of terms in the series increases, the sum of the series approaches infinity. This means that the harmonic series is a divergent sequence, as it does not approach a particular value as the number of terms increases indefinitely.

In contrast, a convergent series is a series whose sum approaches a particular value as the number of terms in the series increases indefinitely. For example, the series:

1 + 1/4 + 1/9 + 1/16 + 1/25 + …

is a convergent series, as its sum approaches ?^2/6 (the value of the Basel problem) as the number of terms in the series increases indefinitely.

One of the most important applications of converging sequences is in calculus, where they are used to define the concept of continuity. In calculus, a function is continuous at a point if and only if the limit of the function at that point exists and is equal to the value of the function at that point. This means that a function is continuous if and only if the sequence of values of the function as the input approaches the point in question is a converging sequence.

Definition

A converging sequence is a sequence of real numbers that approaches a fixed limit as the number of terms in the sequence approaches infinity. In other words, if a sequence {an} converges to a limit L, then we can say that for any given positive number ?, there exists a positive integer N such that for all n > N, |an – L| < ?. This means that the terms of the sequence eventually become arbitrarily close to L, the limit of the sequence, and remain so for all subsequent terms.

Properties

• Uniqueness of Limit: A converging sequence has a unique limit. This means that if a sequence converges to a limit L, then L is the only number to which the sequence can converge. In other words, there cannot be two different limits for the same sequence.
• The limit is unique, regardless of how the sequence is defined. For example, the sequence {1/n} converges to zero as n approaches infinity, whether we define the sequence as {1, 1/2, 1/3, …} or {1/10^6, 1/10^7, 1/10^8, …}.
• Converging sequences are bounded. This means that a converging sequence {an} is bounded if there exists a real number M such that |an| ? M for all n.
• If {an} is a converging sequence, then any subsequence of {an} also converges to the same limit. In other words, if {bn} is a subsequence of {an} and {an} converges to L, then {bn} also converges to L.
• The limit of a converging sequence can be found by taking the limit of its subsequence. This means that if {an} converges to L, then any subsequence of {an} also converges to L. Conversely, if any subsequence of {an} converges to L, then {an} also converges to L.

Examples

Example 1: Let {an} be the sequence defined by an = 1/n. Then, as n approaches infinity, the sequence converges to zero. To see this, let ? be any positive number. Then, we can find a positive integer N such that 1/N < ?. For any n > N, we have |an – 0| = 1/n < 1/N < ?. Therefore, {an} converges to zero.

Example 2: Let {an} be the sequence defined by an = (-1)n/n. Then, the sequence alternates between positive and negative values, but as n approaches infinity, the sequence converges to zero. To see this, note that for any ? > 0, we can find a positive integer N such that 1/N < ?. Then, for any n > N, we have |an – 0| = |-1n/n| = 1/n < 1/N < ?. Therefore, {an} converges to zero.