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Computer algebra system

January 20, 2024

"Symbolic algebra" redirects here. For the algebra of logic, see Symbolical algebra.

A computer algebra system (CAS) or symbolic algebra system (SAS) is any mathematical software with the ability to manipulate mathematical expressions in a way similar to the traditional manual computations of mathematicians and scientists. The development of the computer algebra systems in the second half of the 20th century is part of the discipline of "computer algebra" or "symbolic computation", which has spurred work in algorithms over mathematical objects such as polynomials.

Computer algebra systems may be divided into two classes: specialized and general-purpose. The specialized ones are devoted to a specific part of mathematics, such as number theory, group theory, or teaching of elementary mathematics.

General-purpose computer algebra systems aim to be useful to a user working in any scientific field that requires manipulation of mathematical expressions. To be useful, a general-purpose computer algebra system must include various features such as:

The library must not only provide for the needs of the users, but also the needs of the simplifier. For example, the computation of polynomial greatest common divisors is systematically used for the simplification of expressions involving fractions.

This large amount of required computer capabilities explains the small number of general-purpose computer algebra systems. Significant systems include Axiom, GAP, Maxima, Magma, Maple, Mathematica, and SageMath.

History edit

 
A Texas Instruments TI-Nspire calculator that contains a computer algebra system

Computer algebra systems began to appear in the 1960s and evolved out of two quite different sources—the requirements of theoretical physicists and research into artificial intelligence.

A prime example for the first development was the pioneering work conducted by the later Nobel Prize laureate in physics Martinus Veltman, who designed a program for symbolic mathematics, especially high-energy physics, called Schoonschip (Dutch for "clean ship") in 1963. Another early system was FORMAC.

Using Lisp as the programming basis, Carl Engelman created MATHLAB in 1964 at MITRE within an artificial-intelligence research environment. Later MATHLAB was made available to users on PDP-6 and PDP-10 systems running TOPS-10 or TENEX in universities. Today it can still be used on SIMH emulations of the PDP-10. MATHLAB ("mathematical laboratory") should not be confused with MATLAB ("matrix laboratory"), which is a system for numerical computation built 15 years later at the University of New Mexico.

In 1987, Hewlett-Packard introduced the first hand-held calculator CAS with the HP-28 series, and it was possible, for the first time in a calculator,[1] to arrange algebraic expressions, differentiation, limited symbolic integration, Taylor series construction and a solver for algebraic equations. In 1999, the independently developed CAS Erable for the HP 48 series became an officially integrated part of the firmware of the emerging HP 49/50 series, and a year later into the HP 40 series as well, whereas the HP Prime adopted the Xcas system in 2013.

The Texas Instruments company in 1995 released the TI-92 calculator with a CAS based on the software Derive; the TI-Nspire series replaced Derive in 2007. The TI-89 series, first released in 1998, also contains a CAS.

Casio released their first CAS calculator with the CFX-9970G and succeeded it with the Algebra FX Series in 1999-2003 and the current ClassPad Series.[citation needed]

The first popular computer algebra systems were muMATH, Reduce, Derive (based on muMATH), and Macsyma; a popular copyleft version of Macsyma called Maxima is actively being maintained. Reduce became free software in 2008.[2] As of today,[when?] the most popular commercial systems are Mathematica[3] and Maple, which are commonly used by research mathematicians, scientists, and engineers. Freely available alternatives include SageMath (which can act as a front-end to several other free and nonfree CAS). Other significant systems include Axiom, GAP, Maxima, Magma, and SageMath.

The movement to web-based applications in the early 2000s saw the release of WolframAlpha, an online search engine and CAS which includes the capabilities of Mathematica.[4]

More recently, computer algebra systems have been implemented using artificial neural networks, though as of 2020 they are not commercially available.[5]

Symbolic manipulations edit

The symbolic manipulations supported typically include:

In the above, the word some indicates that the operation cannot always be performed.

Additional capabilities edit

Many also include:

Some include:

Some computer algebra systems focus on specialized disciplines; these are typically developed in academia and are free. They can be inefficient for numeric operations as compared to numeric systems.

Types of expressions edit

The expressions manipulated by the CAS typically include polynomials in multiple variables; standard functions of expressions (sine, exponential, etc.); various special functions (Γ, ζ, erf, Bessel functions, etc.); arbitrary functions of expressions; optimization; derivatives, integrals, simplifications, sums, and products of expressions; truncated series with expressions as coefficients, matrices of expressions, and so on. Numeric domains supported typically include floating-point representation of real numbers, integers (of unbounded size), complex (floating-point representation), interval representation of reals, rational number (exact representation) and algebraic numbers.

Use in education edit

There have been many advocates for increasing the use of computer algebra systems in primary and secondary-school classrooms. The primary reason for such advocacy is that computer algebra systems represent real-world math more than do paper-and-pencil or hand calculator based mathematics.[10] This push for increasing computer usage in mathematics classrooms has been supported by some boards of education. It has even been mandated in the curriculum of some regions.[11]

Computer algebra systems have been extensively used in higher education.[12][13] Many universities offer either specific courses on developing their use, or they implicitly expect students to use them for their course work. The companies that develop computer algebra systems have pushed to increase their prevalence among university and college programs.[14][15]

CAS-equipped calculators are not permitted on the ACT, the PLAN, and in some classrooms[16] though it may be permitted on all of College Board's calculator-permitted tests, including the SAT, some SAT Subject Tests and the AP Calculus, Chemistry, Physics, and Statistics exams.

Mathematics used in computer algebra systems edit

See also edit

References edit

  1. ^ Nelson, Richard. . Hewlett-Packard. Archived from the original on 2010-07-03.
  2. ^ "REDUCE Computer Algebra System at SourceForge". reduce-algebra.sourceforge.net. Retrieved 2015-09-28.
  3. ^ Interview with Gaston Gonnet, co-creator of Maple 2007-12-29 at the Wayback Machine, SIAM History of Numerical Analysis and Computing, March 16, 2005.
  4. ^ Bhattacharya, Jyotirmoy (2022-05-12). "Wolfram|Alpha: a free online computer algebra system". The Hindu. ISSN 0971-751X. Retrieved 2023-04-26.
  5. ^ Ornes, Stephen. "Symbolic Mathematics Finally Yields to Neural Networks". Quanta Magazine. Retrieved 2020-11-04.
  6. ^ "dsolve - Maple Programming Help". www.maplesoft.com. Retrieved 2020-05-09.
  7. ^ "DSolve - Wolfram Language Documentation". www.wolfram.com. Retrieved 2020-06-28.
  8. ^ "Basic Algebra and Calculus — Sage Tutorial v9.0". doc.sagemath.org. Retrieved 2020-05-09.
  9. ^ "Symbolic algebra and Mathematics with Xcas" (PDF).
  10. ^ "Teaching kids real math with computers". Ted.com. Retrieved 2017-08-12.
  11. ^ "Mathematics - Manitoba Education". Edu.gov.mb.ca. Retrieved 2017-08-12.
  12. ^ "Mathematica for Faculty, Staff, and Students : Information Technology - Northwestern University". It.northwestern.edu. Retrieved 2017-08-12.
  13. ^ "Mathematica for Students - Columbia University Information Technology". cuit.columbia.edu. Retrieved 2017-08-12.
  14. ^ "Mathematica for Higher Education: Uses for University & College Courses". Wolfram.com. Retrieved 2017-08-12.
  15. ^ "MathWorks - Academia - MATLAB & Simulink". Mathworks.com. Retrieved 2017-08-12.
  16. ^ ACT's CAAP Tests: Use of Calculators on the CAAP Mathematics Test August 31, 2009, at the Wayback Machine
  17. ^ a b B. Buchberger; G.E. Collins; R. Loos (2013-06-29). Computer Algebra: Symbolic and Algebraic Computation. Springer Science & Business Media. ISBN 978-3-7091-3406-1.
  18. ^ Joachim von zur Gathen; Jürgen Gerhard (2013-04-25). Modern Computer Algebra. Cambridge University Press. ISBN 978-1-107-03903-2.
  19. ^ Keith O. Geddes; Stephen R. Czapor; George Labahn (2007-06-30). Algorithms for Computer Algebra. Springer Science & Business Media. ISBN 978-0-585-33247-5.

External links edit

  • Curriculum and Assessment in an Age of Computer Algebra Systems 2009-12-01 at the Wayback Machine - From the Education Resources Information Center Clearinghouse for Science, Mathematics, and Environmental Education, Columbus, Ohio.
  • Richard J. Fateman. "Essays in algebraic simplification." Technical report MIT-LCS-TR-095, 1972. (Of historical interest in showing the direction of research in computer algebra. At the MIT LCS website: )

January 20, 2024
computer, algebra, system, symbolic, algebra, redirects, here, algebra, logic, symbolical, algebra, computer, algebra, system, symbolic, algebra, system, mathematical, software, with, ability, manipulate, mathematical, expressions, similar, traditional, manual. Symbolic algebra redirects here For the algebra of logic see Symbolical algebra A computer algebra system CAS or symbolic algebra system SAS is any mathematical software with the ability to manipulate mathematical expressions in a way similar to the traditional manual computations of mathematicians and scientists The development of the computer algebra systems in the second half of the 20th century is part of the discipline of computer algebra or symbolic computation which has spurred work in algorithms over mathematical objects such as polynomials Computer algebra systems may be divided into two classes specialized and general purpose The specialized ones are devoted to a specific part of mathematics such as number theory group theory or teaching of elementary mathematics General purpose computer algebra systems aim to be useful to a user working in any scientific field that requires manipulation of mathematical expressions To be useful a general purpose computer algebra system must include various features such as a user interface allowing a user to enter and display mathematical formulas typically from a keyboard menu selections mouse or stylus a programming language and an interpreter the result of a computation commonly has an unpredictable form and an unpredictable size therefore user intervention is frequently needed a simplifier which is a rewrite system for simplifying mathematics formulas a memory manager including a garbage collector needed by the huge size of the intermediate data which may appear during a computation an arbitrary precision arithmetic needed by the huge size of the integers that may occur a large library of mathematical algorithms and special functions The library must not only provide for the needs of the users but also the needs of the simplifier For example the computation of polynomial greatest common divisors is systematically used for the simplification of expressions involving fractions This large amount of required computer capabilities explains the small number of general purpose computer algebra systems Significant systems include Axiom GAP Maxima Magma Maple Mathematica and SageMath Contents 1 History 2 Symbolic manipulations 3 Additional capabilities 4 Types of expressions 5 Use in education 6 Mathematics used in computer algebra systems 7 See also 8 References 9 External linksHistory edit nbsp A Texas Instruments TI Nspire calculator that contains a computer algebra systemComputer algebra systems began to appear in the 1960s and evolved out of two quite different sources the requirements of theoretical physicists and research into artificial intelligence A prime example for the first development was the pioneering work conducted by the later Nobel Prize laureate in physics Martinus Veltman who designed a program for symbolic mathematics especially high energy physics called Schoonschip Dutch for clean ship in 1963 Another early system was FORMAC Using Lisp as the programming basis Carl Engelman created MATHLAB in 1964 at MITRE within an artificial intelligence research environment Later MATHLAB was made available to users on PDP 6 and PDP 10 systems running TOPS 10 or TENEX in universities Today it can still be used on SIMH emulations of the PDP 10 MATHLAB mathematical laboratory should not be confused with MATLAB matrix laboratory which is a system for numerical computation built 15 years later at the University of New Mexico In 1987 Hewlett Packard introduced the first hand held calculator CAS with the HP 28 series and it was possible for the first time in a calculator 1 to arrange algebraic expressions differentiation limited symbolic integration Taylor series construction and a solver for algebraic equations In 1999 the independently developed CAS Erable for the HP 48 series became an officially integrated part of the firmware of the emerging HP 49 50 series and a year later into the HP 40 series as well whereas the HP Prime adopted the Xcas system in 2013 The Texas Instruments company in 1995 released the TI 92 calculator with a CAS based on the software Derive the TI Nspire series replaced Derive in 2007 The TI 89 series first released in 1998 also contains a CAS Casio released their first CAS calculator with the CFX 9970G and succeeded it with the Algebra FX Series in 1999 2003 and the current ClassPad Series citation needed The first popular computer algebra systems were muMATH Reduce Derive based on muMATH and Macsyma a popular copyleft version of Macsyma called Maxima is actively being maintained Reduce became free software in 2008 2 As of today when the most popular commercial systems are Mathematica 3 and Maple which are commonly used by research mathematicians scientists and engineers Freely available alternatives include SageMath which can act as a front end to several other free and nonfree CAS Other significant systems include Axiom GAP Maxima Magma and SageMath The movement to web based applications in the early 2000s saw the release of WolframAlpha an online search engine and CAS which includes the capabilities of Mathematica 4 More recently computer algebra systems have been implemented using artificial neural networks though as of 2020 they are not commercially available 5 Symbolic manipulations editThe symbolic manipulations supported typically include simplification to a smaller expression or some standard form including automatic simplification with assumptions and simplification with constraints substitution of symbols or numeric values for certain expressions change of form of expressions expanding products and powers partial and full factorization rewriting as partial fractions constraint satisfaction rewriting trigonometric functions as exponentials transforming logic expressions etc partial and total differentiation some indefinite and definite integration see symbolic integration including multidimensional integrals symbolic constrained and unconstrained global optimization solution of linear and some non linear equations over various domains solution of some differential and difference equations taking some limits integral transforms series operations such as expansion summation and products matrix operations including products inverses etc statistical computation theorem proving and verification which is very useful in the area of experimental mathematics optimized code generationIn the above the word some indicates that the operation cannot always be performed Additional capabilities editMany also include a programming language allowing users to implement their own algorithms arbitrary precision numeric operations exact integer arithmetic and number theory functionality Editing of mathematical expressions in two dimensional form plotting graphs and parametric plots of functions in two and three dimensions and animating them drawing charts and diagrams APIs for linking it on an external program such as a database or using in a programming language to use the computer algebra system string manipulation such as matching and searching add ons for use in applied mathematics such as physics bioinformatics computational chemistry and packages for physical computation citation needed solvers for differential equations 6 7 8 9 Some include graphic production and editing such as computer generated imagery and signal processing as image processing sound synthesisSome computer algebra systems focus on specialized disciplines these are typically developed in academia and are free They can be inefficient for numeric operations as compared to numeric systems Types of expressions editThe expressions manipulated by the CAS typically include polynomials in multiple variables standard functions of expressions sine exponential etc various special functions G z erf Bessel functions etc arbitrary functions of expressions optimization derivatives integrals simplifications sums and products of expressions truncated series with expressions as coefficients matrices of expressions and so on Numeric domains supported typically include floating point representation of real numbers integers of unbounded size complex floating point representation interval representation of reals rational number exact representation and algebraic numbers Use in education editThere have been many advocates for increasing the use of computer algebra systems in primary and secondary school classrooms The primary reason for such advocacy is that computer algebra systems represent real world math more than do paper and pencil or hand calculator based mathematics 10 This push for increasing computer usage in mathematics classrooms has been supported by some boards of education It has even been mandated in the curriculum of some regions 11 Computer algebra systems have been extensively used in higher education 12 13 Many universities offer either specific courses on developing their use or they implicitly expect students to use them for their course work The companies that develop computer algebra systems have pushed to increase their prevalence among university and college programs 14 15 CAS equipped calculators are not permitted on the ACT the PLAN and in some classrooms 16 though it may be permitted on all of College Board s calculator permitted tests including the SAT some SAT Subject Tests and the AP Calculus Chemistry Physics and Statistics exams Mathematics used in computer algebra systems editKnuth Bendix completion algorithm 17 Root finding algorithms 17 Symbolic integration via e g Risch algorithm or Risch Norman algorithm Hypergeometric summation via e g Gosper s algorithm Limit computation via e g Gruntz s algorithm Polynomial factorization via e g over finite fields 18 Berlekamp s algorithm or Cantor Zassenhaus algorithm Greatest common divisor via e g Euclidean algorithm Gaussian elimination 19 Grobner basis via e g Buchberger s algorithm generalization of Euclidean algorithm and Gaussian elimination Pade approximant Schwartz Zippel lemma and testing polynomial identities Chinese remainder theorem Diophantine equations Quantifier elimination over real numbers via e g Tarski s method Cylindrical algebraic decomposition Landau s algorithm nested radicals Derivatives of elementary functions and special functions e g See derivatives of the incomplete gamma function Cylindrical algebraic decompositionSee also edit nbsp Mathematics portalList of computer algebra systems Scientific computation Statistical package Automated theorem proving Algebraic modeling language Constraint logic programming Satisfiability modulo theoriesReferences edit Nelson Richard Hewlett Packard Calculator Firsts Hewlett Packard Archived from the original on 2010 07 03 REDUCE Computer Algebra System at SourceForge reduce algebra sourceforge net Retrieved 2015 09 28 Interview with Gaston Gonnet co creator of Maple Archived 2007 12 29 at the Wayback Machine SIAM History of Numerical Analysis and Computing March 16 2005 Bhattacharya Jyotirmoy 2022 05 12 Wolfram Alpha a free online computer algebra system The Hindu ISSN 0971 751X Retrieved 2023 04 26 Ornes Stephen Symbolic Mathematics Finally Yields to Neural Networks Quanta Magazine Retrieved 2020 11 04 dsolve Maple Programming Help www maplesoft com Retrieved 2020 05 09 DSolve Wolfram Language Documentation www wolfram com Retrieved 2020 06 28 Basic Algebra and Calculus Sage Tutorial v9 0 doc sagemath org Retrieved 2020 05 09 Symbolic algebra and Mathematics with Xcas PDF Teaching kids real math with computers Ted com Retrieved 2017 08 12 Mathematics Manitoba Education Edu gov mb ca Retrieved 2017 08 12 Mathematica for Faculty Staff and Students Information Technology Northwestern University It northwestern edu Retrieved 2017 08 12 Mathematica for Students Columbia University Information Technology cuit columbia edu Retrieved 2017 08 12 Mathematica for Higher Education Uses for University amp College Courses Wolfram com Retrieved 2017 08 12 MathWorks Academia MATLAB amp Simulink Mathworks com Retrieved 2017 08 12 ACT s CAAP Tests Use of Calculators on the CAAP Mathematics Test Archived August 31 2009 at the Wayback Machine a b B Buchberger G E Collins R Loos 2013 06 29 Computer Algebra Symbolic and Algebraic Computation Springer Science amp Business Media ISBN 978 3 7091 3406 1 Joachim von zur Gathen Jurgen Gerhard 2013 04 25 Modern Computer Algebra Cambridge University Press ISBN 978 1 107 03903 2 Keith O Geddes Stephen R Czapor George Labahn 2007 06 30 Algorithms for Computer Algebra Springer Science amp Business Media ISBN 978 0 585 33247 5 External links editCurriculum and Assessment in an Age of Computer Algebra Systems Archived 2009 12 01 at the Wayback Machine From the Education Resources Information Center Clearinghouse for Science Mathematics and Environmental Education Columbus Ohio Richard J Fateman Essays in algebraic simplification Technical report MIT LCS TR 095 1972 Of historical interest in showing the direction of research in computer algebra At the MIT LCS website 1 Retrieved from https en wikipedia org w index php title Computer algebra system amp oldid 1190834372, wikipedia, wiki, book, books, library,

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