A progression is a sequence of numbers or values that follow a specific pattern or rule. It is a fundamental concept in mathematics, particularly in the study of sequences and series, which are important topics in pre-calculus and beyond.
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In an arithmetic sequence, the common difference between consecutive terms is constant.
The formula for the $n$th term of an arithmetic sequence is $a_n = a_1 + (n-1)d$, where $a_1$ is the first term and $d$ is the common difference.
The formula for the sum of the first $n$ terms of an arithmetic sequence is $S_n = \frac{n}{2}[2a_1 + (n-1)d]$.
Arithmetic sequences can be used to model real-world situations, such as the number of steps taken in a staircase or the savings accumulated in a bank account over time.
Progressions, including arithmetic sequences, are important in understanding and analyzing patterns, making predictions, and solving various mathematical problems.
Review Questions
Explain the relationship between an arithmetic sequence and a progression.
An arithmetic sequence is a specific type of progression, where the difference between consecutive terms is constant. In other words, an arithmetic sequence is a progression that follows a linear pattern. The key feature of an arithmetic sequence is the common difference, which allows for the prediction of future terms and the calculation of the sum of the sequence. Progressions, in a broader sense, encompass any sequence of numbers or values that follow a specific rule or pattern, not just those with a constant difference.
Describe how the formulas for the $n$th term and the sum of the first $n$ terms of an arithmetic sequence are derived and how they can be used to solve problems.
The formula for the $n$th term of an arithmetic sequence, $a_n = a_1 + (n-1)d$, is derived by recognizing the pattern that each successive term is obtained by adding the common difference $d$ to the previous term. This formula allows you to find any term in the sequence, given the first term $a_1$ and the common difference $d$. The formula for the sum of the first $n$ terms, $S_n = \frac{n}{2}[2a_1 + (n-1)d]$, is derived by recognizing that the sum of an arithmetic sequence can be expressed as the average of the first and last terms multiplied by the number of terms. These formulas can be used to solve a variety of problems, such as finding the total distance traveled in a linear motion problem or the total amount saved in a savings plan.
Analyze how the properties of an arithmetic sequence, such as the common difference and the relationship between consecutive terms, can be used to model and solve real-world problems.
The properties of an arithmetic sequence, particularly the constant common difference, allow for the modeling of many real-world situations that exhibit a linear pattern. For example, the number of steps in a staircase or the distance traveled in a constant-speed motion problem can be represented by an arithmetic sequence, where the common difference corresponds to the height of each step or the distance traveled in each time interval, respectively. By recognizing the arithmetic sequence pattern, you can use the formulas for the $n$th term and the sum of the first $n$ terms to make predictions, calculate missing values, and solve problems related to these real-world scenarios. The ability to model linear patterns using arithmetic sequences is a powerful tool in applied mathematics and problem-solving.
Related terms
Sequence: A sequence is an ordered list of numbers or values that follow a specific pattern.
Series: A series is the sum of the terms in a sequence.
Arithmetic Sequence: An arithmetic sequence is a sequence where the difference between consecutive terms is constant.