Examples of geometric sequence in the following topics:
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- The $n$th term of a geometric sequence with initial value $a$ and common ratio $r$ is given by
- Generally, to check whether a given sequence is geometric, one simply checks whether successive entries in the sequence all have the same ratio.
- The common ratio of a geometric series may be negative, resulting in an alternating sequence.
- For instance: $1,-3,9,-27,81,-243, \cdots$ is a geometric sequence with common ratio $-3$.
- The behavior of a geometric sequence depends on the value of the common ratio.
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- An applied example of a geometric sequence involves the spread of the flu virus.
- Suppose each infected person will infect two more people, such that the terms follow a geometric sequence.
- Using this equation, the recursive equation for this geometric sequence is:
- Each person infects two more people with the flu virus, making the number of recently-infected people the nth term in a geometric sequence.
- Use a recursive formula to find specific terms of a sequence
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- By utilizing the common ratio and the first term of a geometric sequence, we can sum its terms.
- The terms of a geometric series form a geometric progression, meaning that the ratio of successive terms in the series is constant.
- We can use a formula to find the sum of a finite number of terms in a sequence.
- Find the sum of the first five terms of the geometric sequence $\left(6, 18, 54, 162, \cdots \right)$.
- Calculate the sum of the first $n$ terms in a geometric sequence
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- Finite sequences are sometimes known as strings or words and infinite sequences as streams.
- Finite sequences include the empty sequence $( \quad )$ that has no elements.
- These are called recursive sequences.
- A geometric sequence is a list in which each number is generated by multiplying a constant by the previous number.
- The explicit definition of a geometric sequence is obtained in a similar way.
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- Given several terms in a sequence, it is sometimes possible to find a formula for the general term of the sequence.
- Then the sequence looks like:
- Then the sequence would look like:
- The second sequence of differences is:
- For example, the geometric sequence $2, 4, 8, 16,\dots$ is given by the general term $2^n$.
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- Summation is the operation of adding a sequence of numbers; the result is their sum or total.
- If you add up all the terms of an arithmetic sequence (a sequence in which every entry is the previous entry plus a constant), you have an arithmetic series.
- If you add up all the terms of a geometric sequence (one in which each entry is the previous entry multiplied by a constant), you have a geometric series.
- Once again, pause to convince yourself that this will work on all geometric series, but only on geometric series.
- So the total number of people infected follows a geometric series.
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- Geometric series have applications in math and science and are one of the simplest examples of infinite series with finite sums.
- Geometric series are used throughout mathematics.
- The formula for the sum of a geometric series can be used to convert the decimal to a fraction:
- In the case of the Koch snowflake, its area can be described with a geometric series.
- Apply geometric sequences and series to different physical and mathematical topics
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- For a sequence $\{a_n\}$, where $a_n$ is a non-negative real number for every $n$, the sum $\sum_{n=0}^{\infty}a_n$ can either converge or diverge to $\infty$.
- For a sequence $\{a_n\}$, where $a_n$ is a non-negative real number for every $n$, the sequence of partial sums
- Therefore, it follows that a series $\sum_{n=0}^{\infty} a_n$ with non-negative terms converges if and only if the sequence $S_k$ of partial sums is bounded.
- Visualization of the geometric sum in Example 2.
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- The geometric distribution describes the probability of observing the first success on the nth trial.
- OR 10th sequence)
- P(1st sequence OR 2nd sequence OR ...
- OR 10th sequence) = P(1st sequence) + P(2nd sequence) +·+ P(10th sequence)
- P(it takes Brian six tries to make four field goals) = [Number of possible sequences]×P(Single sequence)
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- The assignment of these prefixes depends on the application of two rules: The Sequence Rule and The Viewing Rule.
- The sequence rule is the same as that used for assigning E-Z prefixes to double bond stereoisomers.
- Remembering the geometric implication of wedge and hatched bonds, an observer (the eye) notes whether a curved arrow drawn from the # 1 position to the # 2 location and then to the # 3 position turns in a clockwise or counter-clockwise manner.
- The stereogenic carbon atom is colored magenta in each case, and the sequence priorities are shown as light blue numbers.
- Rule # 3 of the sequence rules allows us to order these substituents.