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Chapter 13: Problem 79

Find the sum of each sequence. \(\sum_{k=5}^{20} k^{3}\)

Short Answer

Expert verified
The sum of the sequence \(\sum_{k=5}^{20} k^{3}\) is 45700.

Step by step solution

01

- Understand the Summation Notation

The given exercise asks to find the sum of the cubes of integers from 5 to 20. The notation \(\sum_{k=5}^{20} k^{3}\) represents the sum of the sequence \(5^{3}, 6^{3}, 7^{3}, \dots, 20^{3}\).
02

- Identify the Limits of Summation

The lower limit of summation is 5 and the upper limit is 20. So, calculate the cubes of each integer from 5 to 20.
03

- Calculate Each Term in the Sequence

Calculate the cubes of the numbers from 5 to 20: \(5^{3} = 125\), \(6^{3} = 216\), \(7^{3} = 343\), \(8^{3} = 512\), \(9^{3} = 729\), \(10^{3} = 1000\), \(11^{3} = 1331\), \(12^{3} = 1728\), \(13^{3} = 2197\), \(14^{3} = 2744\), \(15^{3} = 3375\), \(16^{3} = 4096\), \(17^{3} = 4913\), \(18^{3} = 5832\), \(19^{3} = 6859\), \(20^{3} = 8000\).
04

- Sum All Calculated Terms

Add all the calculated terms: \(125 + 216 + 343 + 512 + 729 + 1000 + 1331 + 1728 + 2197 + 2744 + 3375 + 4096 + 4913 + 5832 + 6859 + 8000\).
05

- Provide the Final Sum

The final sum of the sequence is: 45700.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Sequences
A sequence is a list of numbers arranged in a specific order. Each number in a sequence is referred to as a term. Sequences can be finite or infinite. In this exercise, we deal with a finite sequence which starts at 5 and ends at 20. This sequence includes all integers between 5 and 20, inclusive.
Sequences often follow a specific pattern, such as the arithmetic or geometric patterns. In this problem, each term in the sequence is a cube of an integer from 5 to 20. The terms of this sequence are:
• 53=125
• 63=216
• 73=343
• 83=512
Understanding sequences helps in identifying patterns and calculating terms in a systematic manner.
Series
A series is the sum of the terms of a sequence. When the terms of a sequence are added together, you get a series. If a sequence is given by \{an\}, the corresponding series is represented as \(\sum an\).
In our example, we consider the series derived from the sequence of cubes of integers from 5 to 20. The notation \(\sum_{k=5}^{20} k^{3}\) asks us to find the sum of the cubes of these numbers.
A series can be finite, like in our case, or infinite if it goes on without stopping. For a finite series, we can simply add all the terms together to get the sum. The process often involves breaking down the problem into manageable steps, like calculating each term and then summing them up systematically.
Summation
Summation notation is a concise way of expressing the sum of a series. This notation uses the Greek letter sigma (\(\sum\)) to represent the sum. The general form involves an index of summation, upper and lower limits, and the terms to be summed.
In the given exercise, the summation notation \(\sum_{k=5}^{20} k^{3}\) tells us to sum the cubes of all integers from 5 to 20. The index of summation is \(k\), the lower limit is 5, and the upper limit is 20.
Summation helps in structuring and simplifying mathematical expressions where adding multiple terms is required. It's particularly useful in calculus, statistics, and various areas of algebra. For our sequence, the step-by-step approach using summation notation provided a clear method to reach the final sum.

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Most popular questions from this chapter

Determine whether the given sequence is arithmetic, geometric, or neither. If the sequence is arithmetic, find the common difference; if it is geometric, find the common ratio. If the sequence is arithmetic or geometric, find the sum of the first 50 terms. $$ \left\\{3-\frac{2}{3} n\right\\} $$

Challenge Problem If the terms of a sequence have the property that \(\frac{a_{1}}{a_{2}}=\frac{a_{2}}{a_{3}}=\cdots=\frac{a_{n-1}}{a_{n}},\) show that \(\frac{a_{1}^{n}}{a_{2}^{n}}=\frac{a_{1}}{a_{n+1}}\)

Reflections in a Mirror A highly reflective mirror reflects \(95 \%\) of the light that falls on it. In a light box having walls made of the mirror, the light reflects back-and-forth between the mirrors. (a) If the original intensity of the light is \(I_{0}\) before it falls on a mirror, write the \(n\) th term of the sequence that describes the intensity of the light after \(n\) reflections. (b) How many reflections are needed to reduce the light intensity by at least \(98 \% ?\)

Use the Principle of Mathematical Induction to show that the given statement is true for all natural numbers \(n\). $$ \frac{1}{1 \cdot 2}+\frac{1}{2 \cdot 3}+\frac{1}{3 \cdot 4}+\cdots+\frac{1}{n(n+1)} \equiv \frac{n}{n+1} $$

Use the Principle of Mathematical Induction to show that the given statement is true for all natural numbers \(n\). $$ -2-3-4-\cdots-(n+1)=-\frac{1}{2} n(n+3) $$
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