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Geometric progression

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Diagram illustrating three basic geometric sequences of the pattern 1(rn−1) up to 6 iterations deep. The first block is a unit block and the dashed line represents the infinite sum of the sequence, a number that it will forever approach but never touch: 2, 3/2, and 4/3 respectively.

A geometric progression, also known as a geometric sequence, is a mathematical sequence of non-zero numbers where each term after the first is found by multiplying the previous one by a fixed number called the common ratio. For example, the sequence 2, 6, 18, 54, ... is a geometric progression with a common ratio of 3. Similarly 10, 5, 2.5, 1.25, ... is a geometric sequence with a common ratio of 1/2.

Examples of a geometric sequence are powers rk of a fixed non-zero number r, such as 2k and 3k. The general form of a geometric sequence is

where r is the common ratio and a is the initial value.

The sum of a geometric progression's terms is called a geometric series.

Properties

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The nth term of a geometric sequence with initial value a = a1 and common ratio r is given by

and in general

Geometric sequences satisfy the linear recurrence relation

for every integer

This is a first order, homogeneous linear recurrence with constant coefficients.

Geometric sequences also satisfy the nonlinear recurrence relation

for every integer

This is a second order nonlinear recurrence with constant coefficients.

When the common ratio of a geometric sequence is positive, the sequence's terms will all share the sign of the first term. When the common ratio of a geometric sequence is negative, the sequence's terms alternate between positive and negative; this is called an alternating sequence. For instance the sequence 1, −3, 9, −27, 81, −243, ... is an alternating geometric sequence with an initial value of 1 and a common ratio of −3. When the initial term and common ratio are complex numbers, the terms' complex arguments follow an arithmetic progression.

If the absolute value of the common ratio is smaller than 1, the terms will decrease in magnitude and approach zero via an exponential decay. If the absolute value of the common ratio is greater than 1, the terms will increase in magnitude and approach infinity via an exponential growth. If the absolute value of the common ratio equals 1, the terms will stay the same size indefinitely, though their signs or complex arguments may change.

Geometric progressions show exponential growth or exponential decline, as opposed to arithmetic progressions showing linear growth or linear decline. This comparison was taken by T.R. Malthus as the mathematical foundation of his An Essay on the Principle of Population. The two kinds of progression are related through the exponential function and the logarithm: exponentiating each term of an arithmetic progression yields a geometric progression, while taking the logarithm of each term in a geometric progression yields an arithmetic progression.

Geometric series

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Proof without words of the formula for the sum of a geometric series – if |r| < 1 and n → ∞, the r n term vanishes, leaving S = a/1 − r
The geometric series 1/4 + 1/16 + 1/64 + 1/256 + ... shown as areas of purple squares. Each of the purple squares has 1/4 of the area of the next larger square (1/2×1/2 = 1/4, 1/4×1/4 = 1/16, etc.). The sum of the areas of the purple squares is one third of the area of the large square.
Another geometric series (coefficient a = 4/9 and common ratio r = 1/9) shown as areas of purple squares. The total purple area is S = a / (1 - r) = (4/9) / (1 - (1/9)) = 1/2, which can be confirmed by observing that the unit square is partitioned into an infinite number of L-shaped areas each with four purple squares and four yellow squares, which is half purple.

In mathematics, 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. Each term is therefore the geometric mean of its two neighbouring terms, similar to how the terms in an arithmetic series are the arithmetic means of their two neighbouring terms.

Geometric series have been studied in mathematics from at least the time of Euclid in his work, Elements, which explored geometric proportions.[1] 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).[2][3] In the early development of modern calculus, they were paradigmatic examples of both convergent series and divergent series and thus came to be crucial references for investigations of convergence, for instance in the ratio test and root test for convergence[4][5] and in the definitions of rates of convergence.[6] Geometric series have further served as prototypes in the study of mathematical objects such as Taylor series,[4][5] generating functions,[7] and perturbation theories.[8]

Geometric series have been applied to model a wide variety of natural phenomena and social phenomena, such as the expansion of the universe where the common ratio between terms is defined by Hubble's constant, the decay of radioactive carbon-14 atoms where the common ratio between terms is defined by the half-life of carbon-14, probabilities of winning in games of chance where the common ratio could be determined by the odds of a roulette wheel, and the economic values of investments where the common ratio could be determined by an interest rate.[9]

In general, a geometric series is written as , where is the initial term and is the common ratio between adjacent terms.[4][5] For example, the series

is geometric because each successive term can be obtained by multiplying the previous term by .

Truncated geometric series are called "finite geometric series" in certain branches of mathematics, especially in 19th century calculus and in probability and statistics and their applications.

The standard capital-sigma notation[10][11] expression for the infinite geometric series is

and the corresponding expression for the finite geometric series is

Any finite geometric series has the sum , and when the infinite series converges to the limit value .

Though geometric series are most commonly found and applied with the real or complex numbers for and , there are also important results and applications for matrix-valued geometric series, function-valued geometric series, p-adic number geometric series,[12] and, most generally, geometric series of elements of abstract algebraic fields, rings, and semirings.[13]

Product

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The infinite product of a geometric progression is the product of all of its terms. The partial product of a geometric progression up to the term with power is

When and are positive real numbers, this is equivalent to taking the geometric mean of the partial progression's first and last individual terms and then raising that mean to the power given by the number of terms

This corresponds to a similar property of sums of terms of a finite arithmetic sequence: the sum of an arithmetic sequence is the number of terms times the arithmetic mean of the first and last individual terms. This correspondence follows the usual pattern that any arithmetic sequence is a sequence of logarithms of terms of a geometric sequence and any geometric sequence is a sequence of exponentiations of terms of an arithmetic sequence. Sums of logarithms correspond to products of exponentiated values.

Proof

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Let represent the product up to power . Written out in full,

.

Carrying out the multiplications and gathering like terms,

.

The exponent of r is the sum of an arithmetic sequence. Substituting the formula for that sum,

,

which concludes the proof.

One can rearrange this expression to

Rewriting a as and r as though this is not valid for or

which is the formula in terms of the geometric mean.

History

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A clay tablet from the Early Dynastic Period in Mesopotamia (c. 2900 – c. 2350 BC), identified as MS 3047, contains a geometric progression with base 3 and multiplier 1/2. It has been suggested to be Sumerian, from the city of Shuruppak. It is the only known record of a geometric progression from before the time of old Babylonian mathematics beginning in 2000 BC.[14]

Books VIII and IX of Euclid's Elements analyze geometric progressions (such as the powers of two, see the article for details) and give several of their properties.[15]

See also

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References

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  1. ^ Euclid; J.L. Heiberg (2007). Euclid's Elements of Geometry (PDF). Translated by Richard Fitzpatrick. Richard Fitzpatrick. pp. 4, 277. ISBN 978-0615179841. Archived (PDF) from the original on 2013-08-11.
  2. ^ 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.
  3. ^ Russo, Lucio (2004). The Forgotten Revolution. Translated by Levy, Silvio. Germany: Springer-Verlag. pp. 49–52. ISBN 978-3-540-20396-4.
  4. ^ a b c Spivak, Michael (2008). Calculus (4th ed.). Houston, TX, USA: Publish or Perish, Inc. pp. 473–478. ISBN 978-0-914098-91-1.
  5. ^ a b c Apostol, Tom M. (1967). Calculus. Vol. 1 (2nd ed.). USA: John Wiley & Sons. pp. 388–390, 399–401. ISBN 0-471-00005-1.
  6. ^ Nocedal, Jorge; Wright, Stephen J. (1999). Numerical Optimization (1st ed.). New York, NY: Springer. pp. 28–29. ISBN 978-0-387-98793-4.
  7. ^ Wilf, Herbert S. (1990). Generatingfunctionology. San Diego, CA, USA: Academic Press. pp. 27–28, 32, 45, 49. ISBN 978-1-48-324857-8.
  8. ^ 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.
  9. ^ Cvitanic, Jaksa; Zapatero, Fernando (2004). Introduction to the Economics and Mathematics of Financial Markets. Cambridge, MA: MIT Press. pp. 35–38. ISBN 978-0-262-03320-6.
  10. ^ Riddle, Douglas F. Calculus and Analytic Geometry, Second Edition Belmont, California, Wadsworth Publishing, p. 566, 1970.
  11. ^ Apostol, Tom M. (1967). Calculus. Vol. 1 (2nd ed.). USA: John Wiley & Sons. p. 37. ISBN 0-471-00005-1.
  12. ^ Robert, Alain M. (2000). A Course in p-adic Analysis. Graduate Texts in Mathematics. Vol. 198. New York, NY, USA: Springer-Verlag. pp. 3–4, 12–17. ISBN 978-0387-98669-2.
  13. ^ Dummit, David S.; Foote, Richard M. (2004). Abstract Algebra (3rd ed.). Hoboken, NJ, USA: John Wiley and Sons. p. 238. ISBN 978-0-471-43334-7.
  14. ^ Friberg, Jöran (2007). "MS 3047: An Old Sumerian Metro-Mathematical Table Text". In Friberg, Jöran (ed.). A remarkable collection of Babylonian mathematical texts. Sources and Studies in the History of Mathematics and Physical Sciences. New York: Springer. pp. 150–153. doi:10.1007/978-0-387-48977-3. ISBN 978-0-387-34543-7. MR 2333050.
  15. ^ Heath, Thomas L. (1956). The Thirteen Books of Euclid's Elements (2nd ed. [Facsimile. Original publication: Cambridge University Press, 1925] ed.). New York: Dover Publications.
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