Calculus: Difference between revisions

For other uses, see Calculus (disambiguation).

Calculus (from Latin, "pebble" or "little stone") is a major area in mathematics "where infinitesimal data yields global information."^[1] It has widespread applications in science and engineering and is used to solve complex and expansive problems that cannot be solved by algebra alone. It builds on analytic geometry and includes two major branches; differential and integral calculus, which are related by the Fundamental Theorem of Calculus.

Applications of differential calculus include computations involving velocity and acceleration, the slope of a curve, and optimization. Applications of integral calculus include computations involving area, volume, arc length, center of mass, work, and pressure. More advanced applications include power series and Fourier series. Calculus can be used to compute the trajectory of a shuttle docking at a space station or the amount of snow in a driveway.

Calculus is also used to gain a more precise understanding of the nature of space, time, and motion. For centuries, mathematicians and philosophers wrestled with paradoxes involving division by zero or sums of infinitely many numbers. These questions arise in the study of motion and area. The ancient Greek philosopher Zeno gave several famous examples of such paradoxes. Calculus provides tools, especially the limit and the infinite series, which resolve the paradoxes.

While some of the ideas of calculus were developed earlier, in Greece, India, Iraq, and Japan, the modern use of calculus began in Europe, during the 17th century, when Isaac Newton and Gottfried Wilhelm Leibniz built on the work of earlier mathematicians to introduce the basic principles of calculus. This work had a strong impact on the development of physics.

History

Sir Isaac Newton was one of the more famous inventors and contributors of calculus, with relation to his laws of motion and other mathematical physics concepts.

Main article: History of calculus

The history of calculus falls into several distinct periods, most notably the ancient, medieval, and modern periods.

The ancient period introduced some of the ideas of integral calculus, but does not seem to have developed these ideas in a rigorous or systematic way. The method of integration can be traced back to the Egyptian Moscow papyrus circa 1800 BC, which gives the formula for finding the volume of a pyramidal frustrum.^[2]

Eudoxus (circa 408 BC - circa 355 BC) used the method of exhaustion, which prefigures the concept of the limit, to calculate areas and volumes. Archimedes (circa 287 BC - 212 BC) developed this idea further, inventing heuristics which resemble integral calculus.^[3]

The Indian mathematician Aryabhata used the notion of infinitesimals in 499 AD and expressed an astronomical problem in the form of a basic differential equation.^[4] This equation eventually led Bhaskara in the 12th century to develop an early derivative representing infinitesimal change, and describe an early form of "Rolle's theorem".^[5]

Around 1000 AD, the Iraqi mathematician Ibn al-Haytham (Alhazen) was the first to derive the formula for the sum of the fourth powers. In turn, he developed a method for determining the general formula for the sum of any integral powers, which was fundamental to the development of integral calculus.^[6]

In the 14th century, Madhava of Sangamagrama, along with other mathematician-astronomers of the Kerala school of astronomy and mathematics, described special cases of Taylor series^[7] which are treated in the text Yuktibhasa.^[8][9][10]

In the 17th century, independent discoveries in calculus were being made in Japan, by mathematicians such as Seki Kowa, who expanded upon the method of exhaustion.

The second half of the 17th century was a time of major innovation in Europe. Calculus provided a new opportunity in mathematical physics to solve long-standing problems. Several mathematicians contributed to these breakthroughs, notably John Wallis and Isaac Barrow. James Gregory proved a special case of the second fundamental theorem of calculus in 1668.

Gottfried Wilhelm Leibniz was originally accused of plagiarism of Sir Isaac Newton's unpublished works, but is now regarded as an independent inventor and contributor towards calculus.

Leibniz and Newton pulled these ideas together into a coherent whole and they are usually credited with the independent and nearly simultaneous invention of calculus. Newton was the first to apply calculus to general physics and Leibniz developed much of the notation used in calculus today; he often spent days determining appropriate symbols for concepts. The basic insight that both Newton and Leibniz had was the fundamental theorem of calculus.

When Newton and Leibniz first published their results, there was great controversy over which mathematician (and therefore which country) deserved credit. Newton derived his results first, but Leibniz published first. Newton claimed Leibniz stole ideas from his unpublished notes. This controversy divided English-speaking mathematicians from continental mathematicians for many years, to the detriment of English mathematics. A careful examination of the papers of Leibniz and Newton shows that they arrived at their results independently, with Leibniz starting first with integration and Newton with differentiation. Today, both Newton and Leibniz are given credit for developing calculus independently. It is Leibniz, however, who gave the new discipline its name. Newton called his calculus the "the science of fluxions".

Since the time of Leibniz and Newton, many mathematicians have contributed to the continuing development of calculus. In the 19th century, calculus was put on a much more rigorous footing by mathematicians such as Cauchy, Riemann, and Weierstrass. It was also during this period that the ideas of calculus were generalized to Euclidean space and the complex plane. Lebesgue further generalized the notion of the integral.

Calculus is an ubiquitous topic in most modern high schools and universities, and mathematicians around the world continue to contribute to its development.^[11]

Limits and Infinitesimals

Main article: Limit (mathematics)

Calculus is usually developed by manipulating very small quantities. Historically, the first method of doing so was by infinitesimals. These are objects which can be treated like numbers but which are, in some sense, "infinitely small". On a number line, these would be locations which are not zero, but which have zero distance from zero. No non-zero number is an infinitesimal, because its distance from zero is positive. Any multiple of an infinitesimal is still infinitely small, in other words, infinitesimals do not satisfy the Archimedean property. From this viewpoint, calculus is a collection of techniques for manipulating infinitesimals. This viewpoint fell out of favor in the 19th century because it is difficult to make the notion of an infinitesimal precise. However, the concept was revived in the 20th century with the introduction of non-standard analysis, which provided solid foundations for the manipulation of infinitesimals.

In the 19th century, infinitesimals were replaced by limits. Limits describe the value of a function at a certain input in terms of its values at nearby input. They capture small-scale behavior, just like infinitesimals, but using ordinary numbers. From this viewpoint, calculus is a collection of techniques for manipulating certain limits. Infinitesimals get replaced by very small numbers, and the infinitely small behavior of the function is found by taking the limiting behavior for smaller and smaller numbers. Limits are easy to put on rigorous foundations, and for this reason they are the standard approach to calculus.

Derivatives

Tangent line at (x, f(x)). The derivative f ' (x) of a curve at a point is the slope (rise over run) of the line tangent to that curve at that point.

Main article: Derivative

Differential calculus is the study of the definition, properties, and applications of the derivative or slope of a graph. The process of finding the derivative is called differentiation. In technical language, the derivative is a linear operator, which inputs a function and outputs a second function, so that at every point the value of the output is the slope of the input.

The concept of the derivative is fundamentally more advanced than the concepts encountered in algebra. In algebra, students learn about functions which input a number and output another number. For example, if the doubling function inputs 3, then it outputs 6, while if the squaring function inputs 3, it outputs 9. But the derivative inputs a function and outputs another function. For example, if the derivative inputs the squaring function, then it outputs the doubling function, because the doubling functions gives the slope of the squaring function at any given point.

To understand the derivative, students must learn mathematical notation. In mathematical notation, one common symbol for the derivative of a function is an apostrophe-like mark called "prime". Thus the derivative of f is f ' (f prime). The last sentence of the preceding paragraph, in mathematical notation, would be written:

${\displaystyle f(x)=x^{2}\,}$

${\displaystyle f'(x)=2x\,}$.

If the input of a function is time, then the derivative of that function is the rate at which the function changes.

If a function is linear (that is, if the graph of the function is a straight line), then the function can be written y = m x + b, where:

${\displaystyle m={rise \over {run}}={{\mbox{change in }}y \over {\mbox{change in }}x}={\Delta y \over {\Delta x}}}$.

This gives an exact value for the slope of a straight line. If the function is not a straight line, however then the change in y divided by the change in x varies, and we need calculus to find an exact value at a given point. (Note that y and f(x) are two different notations for the same thing: the output of the function.) A line through two points on a curve is called a secant line. The slope, or rise over run, of a secant line can be expressed as:

${\displaystyle m={f(x+h)-f(x) \over {(x+h)-x}}\,}$

where the coordinates of the first point are (x, f(x)) and h is the horizontal distance between the two points.

To determine the slope of the curve, we use the limit:

${\displaystyle \lim _{h\to 0}{f(x+h)-f(x) \over {h}}}$

Working out one particular case, we find the slope of the squaring function at the point where the input is 3 and the output is 9 (i.e. ${\displaystyle f(x)=x^{2}}$, so ${\displaystyle f(3)=9}$).

${\displaystyle f'(3)=\lim _{h\to 0}{(3+h)^{2}-9 \over {h}}=}$

${\displaystyle \lim _{h\to 0}{9+6h+h^{2}-9 \over {h}}=}$

${\displaystyle \lim _{h\to 0}{6h+h^{2} \over {h}}=}$

${\displaystyle \lim _{h\to 0}(6+h)=6}$

The slope of the squaring function at the point (3, 9) is 6, that is to say, it is going up six times as fast as it is going to the right.

Integrals

Main article: Integral

Integral calculus is the study of the definitions, properties, and applications of two related concepts, the indefinite integral and the definite integral. The process of finding the value of an integral is called integration. In technical language, integral calculus studies two related linear operators.

The indefinite integral is the antiderivative, the inverse operation to the derivative. F is an indefinite integral of f when f is a derivative of F. (This use of upper- and lower-case letters for a function and its indefinite integral is common in calculus.)

The definite integral inputs a function and outputs a number, which gives the area between the graph of the input and the x-axis. The technical definition of the definite integral is the limit of a sum of areas of rectangles, called a Riemann sum.

A motivating example is the distances traveled in a given time.

${\displaystyle \mathrm {Distance} =\mathrm {Speed} \cdot \mathrm {Time} }$

If the speed is constant, only multiplication is needed, but if the speed changes, then we need a more powerful method of finding the distance. One such method is to approximate the distance traveled by breaking up the time into many short intervals of time, then multiplying the time elapsed in each interval by one of the speeds in that interval, and then taking the sum (Riemann sum) of the approximate distance traveled in each interval. The basic idea is that if only a short time elapses, then the speed will stay more or less the same. However, a Riemann sum only gives an approximation of the distance traveled. We must take the limit of all such Riemann sums to find the exact distance traveled.

Integration can be thought of as measuring the area under a curve, defined by f(x), between two points (here a and b).

If f(x) in the diagram on the left represents speed as it varies over time, the distance traveled between the times represented by a and b is the area of the shaded region s.

To approximate that area, an intuitive method would be to divide up the distance between a and b in to a number of equal segments, the length of each segment represented by the symbol Δx. For each small segment, we can choose one value of the function f(x). Call that value h. Then the area of the rectangle with base Δx and height h gives the distance (time Δx multiplied by speed h) traveled in that segment. Associated with each segment is the average value of the function above it, f(x)=h. The sum of all such rectangles gives an approximation of the area between the axis and the curve, which is an approximation of the total distance traveled. A smaller value for Δx will give more rectangles and in most cases a better approximation, but for an exact answer we need to take a limit as Δx approaches zero.

The symbol of integration is ${\displaystyle \int _{\,}^{\,}}$, an elongated S (which stands for "sum"). The definite integral is written as:

${\displaystyle \int _{a}^{b}f(x)\,dx}$

and is read "the integral from a to b of f-of-x with respect to x."

The indefinite integral, or antiderivative, is written:

${\displaystyle \int f(x)\,dx}$.

Since the derivative of the function y = x² + C is y ' = 2x (where C is any constant)

${\displaystyle \int 2x\,dx=x^{2}+C}$.

Fundamental theorem

Main article: Fundamental theorem of calculus

The fundamental theorem of calculus states that differentiation and integration are inverse operations. More precisely, it relates the values of antiderivatives to definite integrals. Because it is usually easier to compute an antiderivative than to apply the definition of a definite integral, the Fundamental Theorem of Calculus provides a practical way of computing definite integrals. It can also be interpreted as a precise statement of the fact that differentiation is the inverse of integration.

The Fundamental Theorem of Calculus states: If a function f is continuous on the interval [a, b] and if F is a function whose derivative is f on the interval (a, b), then

${\displaystyle \int _{a}^{b}f(x)\,dx=F(b)-F(a).}$

Furthermore, for every x in the interval (a, b),

${\displaystyle {\frac {d}{dx}}\int _{a}^{x}f(t)\,dt=f(x).}$

This realization, made by both Newton and Leibniz, who based their results on earlier work by Isaac Barrow, was key to the massive proliferation of analytic results after their work became known. The fundamental theorem provides an algebraic method of computing many definite integrals—without performing limit processes—by finding formulas for antiderivatives. It is also a prototype solution of a differential equation. Differential equations relate an unknown function to its derivatives, and are ubiquitous in the sciences.

Foundations

In mathematics, foundations refers to the rigorous development of a subject from precise axioms and definitions. Working out a rigorous foundation for calculus occupied mathematicians for much of the century following Newton and Leibniz and is still to some extent an active area of research today.

There is more than one rigorous approach to the foundation of calculus. The usual one is via the concept of limits defined on the continuum of real numbers. An alternative is nonstandard analysis, in which the real number system is augmented with infinitesimal and infinite numbers. The foundations of calculus are included in the field of real analysis, which contains full definitions and proofs of the theorems of calculus as well as generalisations such as measure theory and distribution theory.

Applications

The logarithmic spiral of the Nautilus shell is a classical image used to depict the growth and change related to calculus

Calculus is used in every branch of the physical sciences, in computer science, statistics, engineering, economics, business, medicine, and in other fields wherever a problem can be mathematically modeled and an optimal solution is desired.

Physics makes particular use of calculus; all concepts in classical mechanics are interrelated through calculus. The mass of an object of known density, the moment of inertia of objects, as well as the total energy of an object within a conservative field can be found by the use of calculus. In the subfields of electricity and magnetism calculus can be used to find the total flux of electromagnetic fields. A more historical example of the use of calculus in physics is Newton's second law of motion, it expressly uses the term "rate of change" which refers to the derivative: The rate of change of momentum of a body is equal to the resultant force acting on the body and is in the same direction. Even the common expression of Newton's second law as: Force = Mass × Acceleration, involves differential calculus because acceleration can be expressed as the derivative of velocity. Maxwell's theory of electromagnetism and Einstein's theory of general relativity are also expressed in the language of differential calculus.

Calculus can be used in conjunction with other mathematical disciplines. For example, it can be used with linear algebra to find the "best fit" linear approximation for a set of points in a domain.

In the realm of medicine, calculus can be used to find the optimal branching angle of a blood vessel so as to maximize flow.

In analytic geometry, the study of graphs of functions, calculus is used to find high points and low points (maximums and minimums), slope, concavity and inflection points.

In economics, calculus allows for the determination of maximal profit by providing a way to easily calculate both marginal cost and marginal revenue.

Calculus can be used to find approximate solutions to equations, in methods such as Newton's method, fixed point iteration, and linear approximation. For instance, spacecraft use a variation of the Euler method to approximate curved courses within zero gravity environments.

See also

 This article incorporates text from a publication now in the public domain: Chisholm, Hugh, ed. (1911). Encyclopædia Britannica (11th ed.). Cambridge University Press. {{cite encyclopedia}}: Missing or empty |title= (help)

Lists

• List of basic calculus topics
• List of basic calculus equations and formulas
• List of calculus topics
• Publications in calculus
• Table of integrals

Related topics

• Calculus with polynomials
• Differential geometry
• Mathematics
• Multivariable calculus
• Non-standard analysis
• Precalculus (mathematical education)

References

Notes

1. Heinonen, J., Nonsmooth calculus, Bull. Amer. Math. Soc. (2) 44 no. 2, April 2007, p. 163
2. Helmer Aslaksen. Why Calculus? National University of Singapore.
3. Archimedes, Method, in The Works of Archimedes ISBN 978-0-521-66160-7
4. Aryabhata the Elder
5. Ian G. Pearce. Bhaskaracharya II.
6. Victor J. Katz (1995). "Ideas of Calculus in Islam and India", Mathematics Magazine 68 (3), p. 163-174.
7. "Madhava". Biography of Madhava. School of Mathematics and Statistics University of St Andrews, Scotland. Retrieved 2006-09-13.
8. "An overview of Indian mathematics". Indian Maths. School of Mathematics and Statistics University of St Andrews, Scotland. Retrieved 2006-07-07.
9. "Science and technology in free India" (PDF). Government of Kerala — Kerala Call, September 2004. Prof.C.G.Ramachandran Nair. Retrieved 2006-07-09.
10. Charles Whish (1835). Transactions of the Royal Asiatic Society of Great Britain and Ireland.
11. UNESCO-World Data on Education [[1]]

Books

• Donald A. McQuarrie (2003). Mathematical Methods for Scientists and Engineers, University Science Books. ISBN 9781891389245
• James Stewart (2002). Calculus: Early Transcendentals, 5th ed., Brooks Cole. ISBN 9780534393212

Other resources

Further reading

• Robert A. Adams. (1999) ISBN 978-0-201-39607-2 Calculus: A complete course.
• Albers, Donald J.; Richard D. Anderson and Don O. Loftsgaarden, ed. (1986) Undergraduate Programs in the Mathematics and Computer Sciences: The 1985-1986 Survey, Mathematical Association of America No. 7,
• John L. Bell: A Primer of Infinitesimal Analysis, Cambridge University Press, 1998. ISBN 978-0-521-62401-5. Uses synthetic differential geometry and nilpotent infinitesimals
• Florian Cajori, "The History of Notations of the Calculus." Annals of Mathematics, 2nd Ser., Vol. 25, No. 1 (Sep., 1923), pp. 1-46.
• Leonid P. Lebedev and Michael J. Cloud: "Approximating Perfection: a Mathematician's Journey into the World of Mechanics, Ch. 1: The Tools of Calculus", Princeton Univ. Press, 2004
• Cliff Pickover. (2003) ISBN 978-0-471-26987-8 Calculus and Pizza: A Math Cookbook for the Hungry Mind.
• Michael Spivak. (Sept 1994) ISBN 978-0-914098-89-8 Calculus. Publish or Perish publishing.
• Silvanus P. Thompson and Martin Gardner. (1998) ISBN 978-0-312-18548-0 Calculus Made Easy.
• Mathematical Association of America. (1988) Calculus for a New Century; A Pump, Not a Filter, The Association, Stony Brook, NY. ED 300 252.
• Thomas/Finney. (1996) ISBN 978-0-201-53174-9 Calculus and Analytic geometry 9th, Addison Wesley.
• Weisstein, Eric W. "Second Fundamental Theorem of Calculus." From MathWorld--A Wolfram Web Resource.

Online books

• Crowell, B., (2003). "Calculus" Light and Matter, Fullerton. Retrieved 6^th May 2007 from http://www.lightandmatter.com/calc/calc.pdf
• Garrett, P., (2006). "Notes on first year calculus" University of Minnesota. Retrieved 6^th May 2007 from http://www.math.umn.edu/~garrett/calculus/first_year/notes.pdf
• Faraz, H., (2006). "Understanding Calculus" Retrieved Retrieved 6^th May 2007 from Understanding Calculus, URL http://www.understandingcalculus.com/ (HTML only)
• Keisler, H. J., (2000). "Elementary Calculus: An Approach Using Infinitesimals" Retrieved 6^th May 2007 from http://www.math.wisc.edu/~keisler/keislercalc1.pdf
• Mauch, S. (2004). "Sean's Applied Math Book" California Institute of Technology. Retrieved 6^th May 2007 from http://www.cacr.caltech.edu/~sean/applied_math.pdf
• Sloughter, Dan., (2000) "Difference Equations to Differential Equations: An introduction to calculus". Retrieved 6^th May 2007 from http://math.furman.edu/~dcs/book/
• Stroyan, K.D., (2004). "A brief introduction to infinitesimal calculus" University of Iowa. Retrieved 6^th May 2007 from http://www.math.uiowa.edu/~stroyan/InfsmlCalculus/InfsmlCalc.htm (HTML only)
• Strang, G. (1991) "Calculus" Massachusetts Institute of Technology. Retrieved 6^th May 2007 from http://ocw.mit.edu/ans7870/resources/Strang/strangtext.htm.

Web pages

• Weisstein, Eric W. "Calculus". MathWorld.
• Topics on Calculus at PlanetMath.
• Calculus.org: The Calculus page at University of California, Davis — contains resources and links to other sites
• COW: Calculus on the Web at Temple University - contains resources ranging from pre-calculus and associated algebra
• Online Integrator (WebMathematica) from Wolfram Research
• The Role of Calculus in College Mathematics from ERICDigests.org
• OpenCourseWare Calculus from the Massachusetts Institute of Technology
• Infinitesimal Calculus — an article on its historical development, in Encyclopaedia of Mathematics, Michiel Hazewinkel ed. .