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In the study of mathematical analysis and calculus, a geometric series is a series in which the ratio of successive adjacent terms is constant. In other words, the sum of consecutive terms of a geometric sequence forms a geometric series. Thus, each term is the geometric mean of its two neighboring terms, similar to how the terms in an arithmetic series are the arithmetic means of their two neighboring terms.

Geometric series have been studied in mathematics from the Zeno of Elea created a paradox. It continued to the time of Euclid in his work Elements, which explored geometric proportions. Archimedes further advanced the study through his work on infinite sums, particularly in calculating areas and volumes of geometric shapes (for instance calculating the area inside a parabola). In the early development of modern calculus, they were paradigmatic examples of both convergent series and divergent series, and they came to be crucial references for investigations of convergence, for instance in the ratio test and root test for convergence and in the definitions of rates of convergence. Geometric series have further served as prototypes in the study of mathematical objects such as the Taylor series, generating functions, and perturbation theories.

Though geometric series are most commonly found and applied with both real or complex numbers, there are also important results and applications for matrix-valued geometric series, function-valued geometric series, -adic number geometric series, and most generally geometric series of elements of abstract algebraic fields, rings, and semirings.

Definition, common ratio, and examples

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The geometric series shown as areas of purple squares. Each of the purple squares has 1/4 of the area of the next larger square , , and so forth. Thus, the sum of the purple squares' area is one-third of the area of the large square.

The geometric series is an infinite series derived from a special type of sequence called a geometric progression. This series has two parameters known as the initial term and common ratio . The common ratio in geometric progression is the ratio of any term with the previous term, or it can be interpreted as a multiplier used to calculate each next term in the series from the previous term. By the definition, the geometric series can be described as:[1] Truncating the geometric series into several terms is called finite geometric series, that is:[2]

When it is often called a growth rate or rate of expansion. When it is often called a decay rate or shrink rate, where the idea that it is a "rate" comes from interpreting as a sort of discrete time variable. When an application area has specialized vocabulary for specific types of growth, expansion, shrinkage, and decay, that vocabulary will also often be used to name parameters of geometric series. In economics, for instance, rates of increase and decrease of price levels are called inflation rates and deflation rates, while rates of increase in values of investments include rates of return and interest rates.[3]

Examples of geometric series are the following:

  • Grandi's series – Infinite series summing alternating 1 and -1 terms: 1 − 1 + 1 − 1 + ⋯
  • 1 + 2 + 4 + 8 + ⋯ – Infinite series that diverges
  • 1 − 2 + 4 − 8 + ⋯ – Infinite series that diverges
  • 1/2 + 1/4 + 1/8 + 1/16 + ⋯ – Infinite series summable to 1
  • 1/2 − 1/4 + 1/8 − 1/16 + ⋯ – Infinite series summable to 1/3
  • 1/4 + 1/16 + 1/64 + 1/256 + ⋯ – Infinite series summable to 1/3
  • A geometric series is a unit series, meaning the series sum converges to one, if and only if and .
  • The terms of a geometric series are also the elements of a generalized Fibonacci sequence (a recursively defined sequence with when the series's common ratio satisfies the constraint , which is when equals the golden ratio or its conjugate .
  • The only geometric series that is a unit series and also has terms of a generalized Fibonacci sequence has the golden ratio as its initial term and the conjugate golden ratio as its common ratio. It is a unit series because and , it is a generalized Fibonacci sequence because , and it is an alternating series because .
  • Decimal numbers that have repeated patterns that continue forever can be interpreted as geometric series and thereby converted to expressions of the ratio of two integers.[4] For example, the repeated decimal fraction can be written as the geometric series where the initial term is and the common ratio is .

Convergence of the series and its proof

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The convergence of the infinite sequence of partial sums of the infinite geometric series depends on the magnitude of the common ratio alone:

  • If , the terms of the series approach zero (becoming smaller and smaller in magnitude) and the sequence of partial sums converge to a limit value of .[1]
  • If , the terms of the series become larger and larger in magnitude and the partial sums of the terms also get larger and larger in magnitude, so the series diverges.[1]
  • If , the terms of the series become no larger or smaller in magnitude and the sequence of partial sums of the series does not converge. When , all the terms of the series are the same and the grow to infinity. When , the terms take two values and alternately, and therefore the sequence of partial sums of the terms oscillates between the two values and 0. Consider, for example, Grandi's series: . Partial sums of the terms oscillate between 1 and 0; the sequence of partial sums does not converge. When and , the partial sums circulate periodically among the values , never converging to a limit. Generally when for any integer and with any , the partial sums of the series will circulate indefinitely with a period of , never converging to a limit.[5]

The rate of convergence shows how the sequence quickly approaches its limit. In the case of the geometric series—the relevant sequence is and its limit is —the rate and order are found via where represents the order of convergence. Using and choosing the order of convergence gives:[6] When the series converges, the rate of convergence gets slower as approaches .[6] The pattern of convergence also depends on the sign or complex argument of the common ratio. If and then terms all share the same sign and the partial sums of the terms approach their eventual limit monotonically. If and , adjacent terms in the geometric series alternate between positive and negative, and the partial sums of the terms oscillate above and below their eventual limit . For complex and the converge in a spiraling pattern.

The convergence is proved as follows. The partial sum of the first terms of a geometric series, up to and including the term, is given by the closed form where is the common ratio. The case is merely a simple addition, a case of an arithmetic series. The formula for the partial sums with can be derived as follows:[7][8][9] for . As approaches 1, polynomial division or L'Hospital's rule recovers the case .[10]

Proof without words of the formula for the sum of a geometric series if and , the term vanishes, leaving . This figure uses a slightly different convention for than the main text, shifted by one term.

As approaches infinity, the absolute value of r must be less than one for this sequence of partial sums to converge to a limit. When it does, the series converges absolutely. The infinite series then becomes for .[7]

This convergence result is widely applied to prove the convergence of other series as well, whenever those series's terms can be bounded from above by a suitable geometric series; that proof strategy is the basis for the ratio test and root test for the convergence of infinite series.[11]

Connection to the power series

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Like the geometric series, a power series has one parameter for a common variable raised to successive powers corresponding to the geometric series's , but it has additional parameters  one for each term in the series, for the distinct coefficients of each , rather than just a single additional parameter  for all terms, the common coefficient of  in each term of a geometric series. The geometric series can therefore be considered a class of power series in which the sequence of coefficients satisfies  for all  and .[12]

This special class of power series plays an important role in mathematics, for instance for the study of ordinary generating functions in combinatorics and the summation of divergent series in analysis. Many other power series can be written as transformations and combinations of geometric series, making the geometric series formula a convenient tool for calculating formulas for those power series as well.[13][14]

As a power series, the geometric series has a radius of convergence of 1.[15] This could be seen as a consequence of the Cauchy–Hadamard theorem and the fact that for any or as a consequence of the ratio test for the convergence of infinite series, with implying convergence only for However, both the ratio test and the Cauchy–Hadamard theorem are proven using the geometric series formula as a logically prior result, so such reasoning would be subtly circular.[16]

Background

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2,500 years ago, Greek mathematicians believed that an infinitely long list of positive numbers must sum to infinity. Therefore, Zeno of Elea created a paradox, demonstrating as follows: in order to walk from one place to another, one must first walk half the distance there, and then half of the remaining distance, and half of that remaining distance, and so on, covering infinitely many intervals before arriving. In doing so, he partitioned a fixed distance into an infinitely long list of halved remaining distances, each with a length greater than zero. Zeno's paradox revealed to the Greeks that their assumption about an infinitely long list of positive numbers needing to add up to infinity was incorrect.[17]

Elements of Geometry, Book IX, Proposition 35. "If there is any multitude whatsoever of continually proportional numbers, and equal to the first is subtracted from the second and the last, then as the excess of the second to the first, so the excess of the last will be to all those before it."
Archimedes' dissection of a parabolic segment into infinitely many triangles

Euclid's Elements has the distinction of being the world's oldest continuously used mathematical textbook, and it includes a demonstration of the sum of finite geometric series in Book IX, Proposition 35, illustrated in an adjacent figure.[18]

Archimedes in his The Quadrature of the Parabola used the sum of a geometric series to compute the area enclosed by a parabola and a straight line. Archimedes' theorem states that the total area under the parabola is 4/3 of the area of the blue triangle. His method was to dissect the area into infinite triangles as shown in the adjacent figure.[19] He determined that each green triangle has 1/8 the area of the blue triangle, each yellow triangle has 1/8 the area of a green triangle, and so forth. Assuming that the blue triangle has area 1, then, the total area is the sum of the infinite series Here the first term represents the area of the blue triangle, the second term is the area of the two green triangles, the third term is the area of the four yellow triangles, and so on. Simplifying the fractions gives a geometric series with common ratio and its sum is:[19]

A two dimensional geometric series diagram Nicole Oresme used to determine that the infinite series 1/2 + 2/4 + 3/8 + 4/16 + 5/32 + 6/64 + 7/128 + ... converges to 2.

In addition to his elegantly simple proof of the divergence of the harmonic series, Nicole Oresme[20] proved that the arithmetico-geometric series known as Gabriel's Staircase,[21] In the diagram for his geometric proof, similar to the adjacent diagram, shows a two-dimensional geometric series. The first dimension is horizontal, in the bottom row, representing the geometric series with initial value and common ratio The second dimension is vertical, where the bottom row is a new initial term and each subsequent row above it shrinks according to the same common ratio , making another geometric series with sum , This approach generalizes usefully to higher dimensions, and that generalization is described below in § Connection to the power series.

Applications

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As mentioned above, the geometric series can be applied in the field of economics. This leads to the common ratio of a geometric series that may refer to the rates of increase and decrease of price levels are called inflation rates and deflation rates; in contrast, the rates of increase in values of investments include rates of return and interest rates. More specifically in mathematical finance, geometric series can also be applied in time value of money; that is to represent the present values of perpetual annuities, sums of money to be paid each year indefinitely into the future. This sort of calculation is used to compute the annual percentage rate of a loan, such as a mortgage loan. It can also be used to estimate the present value of expected stock dividends, or the terminal value of a financial asset assuming a stable growth rate. However, the assumption that interest rates are constant is generally incorrect and payments are unlikely to continue forever since the issuer of the perpetual annuity may lose its ability or end its commitment to make continued payments, so estimates like these are only heuristic guidelines for decision making rather than scientific predictions of actual current values.[3]

The interior of the Koch snowflake is a union of infinitely many triangles

In addition to finding the area enclosed by a parabola and a line in Archimedes' The Quadrature of the Parabola,[19] the geometric series may also be applied in finding the Koch snowflake's area described as the union of infinitely many equilateral triangles (see figure). Each side of the green triangle is exactly 1/3 the size of a side of the large blue triangle and therefore has exactly 1/9 the area. Similarly, each yellow triangle has 1/9 the area of a green triangle, and so forth. All of these triangles can be represented in terms of geometric series: the blue triangle's area is the first term, the three green triangles' area is the second term, the twelve yellow triangles' area is the third term, and so forth. Excluding the initial 1, this series has a common ratio , and by taking the blue triangle as a unit of area, the total area of the snowflake is:[22]

Various topics in computer science may include the application of geometric series in the following:

Beyond real and complex numbers

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While geometric series with real and complex number parameters and are most common, geometric series of more general terms such as functions, matrices, and -adic numbers also find application.[23] The mathematical operations used to express a geometric series given its parameters are simply addition and repeated multiplication, and so it is natural, in the context of modern algebra, to define geometric series with parameters from any ring or field.[24] Further generalization to geometric series with parameters from semirings is more unusual, but also has applications; for instance, in the study of fixed-point iteration of transformation functions, as in transformations of automata via rational series.[25]

In order to analyze the convergence of these general geometric series, then on top of addition and multiplication, one must also have some metric of distance between partial sums of the series. This can introduce new subtleties into the questions of convergence, such as the distinctions between uniform convergence and pointwise convergence in series of functions, and can lead to strong contrasts with intuitions from the real numbers, such as in the convergence of the series 1 + 2 + 4 + 8 + ... with and to in the 2-adic numbers using the 2-adic absolute value as a convergence metric. In that case, the 2-adic absolute value of the common coefficient is , and while this is counterintuitive from the perspective of real number absolute value (where naturally), it is nonetheless well-justified in the context of p-adic analysis.[23]

When the multiplication of the parameters is not commutative, as it often is not for matrices or general physical operators, particularly in quantum mechanics, then the standard way of writing the geometric series, , multiplying from the right, may need to be distinguished from the alternative , multiplying from the left, and also the symmetric , multiplying half on each side. These choices may correspond to important alternatives with different strengths and weaknesses in applications, as in the case of ordering the mutual interferences of drift and diffusion differently at infinitesimal temporal scales in Ito integration and Stratonovitch integration in stochastic calculus.

References

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  1. ^ a b c Varberg, Dale E.; Purcell, Edwin J.; Rigdon, Steven E. (2007). Calculus (9th ed.). Pearson Prentice Hall. p. 456. ISBN 978-0131469686.
  2. ^ Young, Cynthia Y. (2010). Precalculus. John Wiley & Sons. p. 966. ISBN 978-0-470-55665-8.
  3. ^ a b Cvitanic, Jaksa; Zapatero, Fernando (2004). Introduction to the Economics and Mathematics of Financial Markets. Cambridge, Massachusetts: MIT Press. pp. 35–38. ISBN 978-0-262-03320-6.
  4. ^ Apostol (1967), p. 393.
  5. ^ Apostol, Tom M. (1967). Calculus. Vol. 1 (2nd ed.). USA: John Wiley & Sons. p. 408. ISBN 0-471-00005-1.
  6. ^ a b Nocedal, Jorge; Wright, Stephen J. (1999). Numerical Optimization (1st ed.). New York: Springer. pp. 28–29. ISBN 978-0-387-98793-4.
  7. ^ a b Apostol (1967), pp. 388–390.
  8. ^ Abramowitz, M.; Stegun, I. A. (1972). Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables (9th printing ed.). New York: Dover Publications. p. 10.
  9. ^ Protter, Murray H.; Morrey, Charles B. Jr. (1970). College Calculus with Analytic Geometry (2nd ed.). Reading: Addison-Wesley. pp. 639–640. LCCN 76087042.
  10. ^ Apostol (1967), pp. 292–295.
  11. ^ Apostol (1967), pp. 399–400.
  12. ^ Apostol (1967), pp. 389.
  13. ^ Wilf, Herbert S. (1990). Generatingfunctionology. San Diego, California: Academic Press. pp. 27–28, 32, 45, 49. ISBN 978-1-48-324857-8.
  14. ^ Bender, Carl M.; Orszag, Steven A. (1999). Advanced Mathematical Methods for Scientists and Engineers: Asymptotic Methods and Perturbation Theory. Springer Science+Business Media. pp. 368–371. ISBN 978-0-387-98931-0.
  15. ^ Spivak, Michael (2008). Calculus (4th ed.). Houston, Texas: Publish or Perish, Inc. p. 473. ISBN 978-0-914098-91-1.
  16. ^ Spivak (2008), p. 476.
  17. ^ Riddle, Douglas E. (1974). Calculus and Analytic Geometry (2nd ed.). Wadsworth Publishing. p. 556. ISBN 053400301-X.
  18. ^ Heiberg, J. L. (2007). Euclid's Elements of Geometry (PDF). Translated by Richard Fitzpatrick. Richard Fitzpatrick. p. 4. ISBN 978-0615179841. Archived (PDF) from the original on 2013-08-11.
  19. ^ a b c Swain, Gordon; Dence, Thomas (1998). "Archimedes' Quadrature of the Parabola Revisited". Mathematics Magazine. 71 (2): 123–130. doi:10.2307/2691014. ISSN 0025-570X. JSTOR 2691014.
  20. ^ Babb, J (2003). "Mathematical Concepts and Proofs from Nicole Oresme: Using the History of Calculus to Teach Mathematics" (PDF). Winnipeg: The Seventh International History, Philosophy and Science Teaching conference. pp. 11–12, 21. Archived (PDF) from the original on 2021-05-27.
  21. ^ Swain, Stuart G. (2018). "Proof Without Words: Gabriel's Staircase". Mathematics Magazine. 67 (3): 209. doi:10.1080/0025570X.1994.11996214. ISSN 0025-570X.
  22. ^ Khare, Apoorva; Lachowska, Anne (2015). Beautiful, Simple, Exact, Crazy: Mathematics in the Real World. Yale University Press. p. 181.
  23. ^ a b Robert, Alain M. (2000). A Course in -adic Analysis. Graduate Texts in Mathematics. Vol. 198. New York, USA: Springer-Verlag. pp. 3–4, 12–17. ISBN 978-0387-98669-2.
  24. ^ Dummit, David S.; Foote, Richard M. (2004). Abstract Algebra (3rd ed.). Hoboken, New Jersey: John Wiley and Sons. p. 238. ISBN 978-0-471-43334-7.
  25. ^ Kuich, W. (1997). "9. Semirings and formal power series: Their relevance to formal languages and automata theory". In Rozenberg, G.; Salomaa, A. (eds.). Handbook of Formal Languages. Vol. 1. Berlin: Springer. pp. 609–677. ISBN 978-3642638633.