It does not have to be the case that □ and □ are finite, although normally at least one of these expressions will be. Often □ and □ are respectively referred to as the “lower limit” and the “upper limit” of the series. Assuming that □ and □ are finite, the expanded form of this expression can be written as This expression dictates that we evaluate □ ( □ ) for □ = □, □ + 1, □ + 2, …, □ and then add together these values in order. Then, for two integers □ and □, where □ ≤ □, we can sum over this function using the sigma notation Sigma notation can be used to encode any map or function where the output is derived from adding together the terms of a given sequence and is rich with algebraic properties that can be used to simplify calculations through this highly condensed notation.Ĭonsider a function or sequence that is denoted □ ( □ ), where □ ∈ ℤ. There are many important types of series that appear across mathematics, with some of the most common being arithmetic series and geometric series, both of which can be represented succinctly using sigma notation. Sigma notation is a convenient way of representing series where each term of the summation can be defined by a sequence or function. Evaluating a series can prove challenging and it may be impossible to do this using a closed-form expression, depending largely on the form of the sequence that the series is based on. For example, if we were given the sequence above as 16, 25, 36, 49, then the series corresponding to this sequence would be 1 6 + 2 5 + 3 6 + 4 9, and, in this case, the series can be evaluated to give a total of 126. Once a sequence has been well defined, it can be used to create a “series”, which essentially consists of adding together the elements of a sequence in the original order. However, we could choose a finite subset of these numbers such as 16, 25, 36, 49, and this would still constitute a sequence based on the square numbers, albeit a finite sequence. Given that there are infinitely many square numbers, the sequence of these is infinite. For example, a common sequence of numbers would be the square numbers, whereby every positive integer is squared and presented in order, giving 1, 4, 9, 16, 25, etc. Often sequences of interest will relate to basic concepts within mathematics that can be described using this idea. Given this very open-ended and vague description, it should be easy to believe that there are infinitely many sequences. In mathematics, a sequence can be loosely thought of as an ordered list of numbers. In this explainer, we will learn how to express a series in sigma notation and how to expand and evaluate series represented in sigma notation.
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