Babylonian clay tablet
YBC 7289 (c. 1800–1600 BC) with annotations. The approximation of the
square root of 2 is four
sexagesimal figures, which is about six
decimal figures. 1 + 24/60 + 51/60
^{2} + 10/60
^{3} = 1.41421296...
^{[1]}
Numerical analysis is the study of algorithms that use numerical approximation (as opposed to general symbolic manipulations) for the problems of mathematical analysis (as distinguished from discrete mathematics).
One of the earliest mathematical writings is a Babylonian tablet from the Yale Babylonian Collection (YBC 7289), which gives a sexagesimal numerical approximation of \sqrt{2}, the length of the diagonal in a unit square. Being able to compute the sides of a triangle (and hence, being able to compute square roots) is extremely important, for instance, in astronomy, carpentry and construction.^{[2]}
Numerical analysis continues this long tradition of practical mathematical calculations. Much like the Babylonian approximation of \sqrt{2}, modern numerical analysis does not seek exact answers, because exact answers are often impossible to obtain in practice. Instead, much of numerical analysis is concerned with obtaining approximate solutions while maintaining reasonable bounds on errors.
Numerical analysis naturally finds applications in all fields of engineering and the physical sciences, but in the 21st century also the life sciences and even the arts have adopted elements of scientific computations. Ordinary differential equations appear in celestial mechanics (planets, stars and galaxies); numerical linear algebra is important for data analysis; stochastic differential equations and Markov chains are essential in simulating living cells for medicine and biology.
Before the advent of modern computers numerical methods often depended on hand interpolation in large printed tables. Since the mid 20th century, computers calculate the required functions instead. These same interpolation formulas nevertheless continue to be used as part of the software algorithms for solving differential equations.
Contents

General introduction 1

History 1.1

Direct and iterative methods 1.2

Discretization and numerical integration 1.2.1

Discretization 1.3

Generation and propagation of errors 2

Roundoff 2.1

Truncation and discretization error 2.2

Numerical stability and wellposed problems 2.3

Areas of study 3

Computing values of functions 3.1

Interpolation, extrapolation, and regression 3.2

Solving equations and systems of equations 3.3

Solving eigenvalue or singular value problems 3.4

Optimization 3.5

Evaluating integrals 3.6

Differential equations 3.7

Software 4

See also 5

Notes 6

References 7

External links 8
General introduction
The overall goal of the field of numerical analysis is the design and analysis of techniques to give approximate but accurate solutions to hard problems, the variety of which is suggested by the following:

Advanced numerical methods are essential in making numerical weather prediction feasible.

Computing the trajectory of a spacecraft requires the accurate numerical solution of a system of ordinary differential equations.

Car companies can improve the crash safety of their vehicles by using computer simulations of car crashes. Such simulations essentially consist of solving partial differential equations numerically.

Hedge funds (private investment funds) use tools from all fields of numerical analysis to attempt to calculate the value of stocks and derivatives more precisely than other market participants.

Airlines use sophisticated optimization algorithms to decide ticket prices, airplane and crew assignments and fuel needs. Historically, such algorithms were developed within the overlapping field of operations research.

Insurance companies use numerical programs for actuarial analysis.
The rest of this section outlines several important themes of numerical analysis.
History
The field of numerical analysis predates the invention of modern computers by many centuries. Linear interpolation was already in use more than 2000 years ago. Many great mathematicians of the past were preoccupied by numerical analysis, as is obvious from the names of important algorithms like Newton's method, Lagrange interpolation polynomial, Gaussian elimination, or Euler's method.
To facilitate computations by hand, large books were produced with formulas and tables of data such as interpolation points and function coefficients. Using these tables, often calculated out to 16 decimal places or more for some functions, one could look up values to plug into the formulas given and achieve very good numerical estimates of some functions. The canonical work in the field is the NIST publication edited by Abramowitz and Stegun, a 1000plus page book of a very large number of commonly used formulas and functions and their values at many points. The function values are no longer very useful when a computer is available, but the large listing of formulas can still be very handy.
The mechanical calculator was also developed as a tool for hand computation. These calculators evolved into electronic computers in the 1940s, and it was then found that these computers were also useful for administrative purposes. But the invention of the computer also influenced the field of numerical analysis, since now longer and more complicated calculations could be done.
Direct and iterative methods
Direct vs iterative methods
Consider the problem of solving

3x^{3} + 4 = 28
for the unknown quantity x.
Direct method

3x^{3} + 4 = 28.

Subtract 4

3x^{3} = 24.

Divide by 3

x^{3} = 8.

Take cube roots

x = 2.

For the iterative method, apply the bisection method to f(x) = 3x^{3} − 24. The initial values are a = 0, b = 3, f(a) = −24, f(b) = 57.
Iterative method
a

b

mid

f(mid)

0

3

1.5

−13.875

1.5

3

2.25

10.17...

1.5

2.25

1.875

−4.22...

1.875

2.25

2.0625

2.32...

We conclude from this table that the solution is between 1.875 and 2.0625. The algorithm might return any number in that range with an error less than 0.2.
Discretization and numerical integration
In a twohour race, we have measured the speed of the car at three instants and recorded them in the following table.
Time

0:20

1:00

1:40

km/h

140

150

180

A discretization would be to say that the speed of the car was constant from 0:00 to 0:40, then from 0:40 to 1:20 and finally from 1:20 to 2:00. For instance, the total distance traveled in the first 40 minutes is approximately (2/3h × 140 km/h) = 93.3 km. This would allow us to estimate the total distance traveled as 93.3 km + 100 km + 120 km = 313.3 km, which is an example of numerical integration (see below) using a Riemann sum, because displacement is the integral of velocity.
Illconditioned problem: Take the function f(x) = 1/(x − 1). Note that f(1.1) = 10 and f(1.001) = 1000: a change in x of less than 0.1 turns into a change in f(x) of nearly 1000. Evaluating f(x) near x = 1 is an illconditioned problem.
Wellconditioned problem: By contrast, evaluating the same function f(x) = 1/(x − 1) near x = 10 is a wellconditioned problem. For instance, f(10) = 1/9 ≈ 0.111 and f(11) = 0.1: a modest change in x leads to a modest change in f(x).

Direct methods compute the solution to a problem in a finite number of steps. These methods would give the precise answer if they were performed in infinite precision arithmetic. Examples include Gaussian elimination, the QR factorization method for solving systems of linear equations, and the simplex method of linear programming. In practice, finite precision is used and the result is an approximation of the true solution (assuming stability).
In contrast to direct methods, iterative methods are not expected to terminate in a finite number of steps. Starting from an initial guess, iterative methods form successive approximations that converge to the exact solution only in the limit. A convergence test, often involving the residual, is specified in order to decide when a sufficiently accurate solution has (hopefully) been found. Even using infinite precision arithmetic these methods would not reach the solution within a finite number of steps (in general). Examples include Newton's method, the bisection method, and Jacobi iteration. In computational matrix algebra, iterative methods are generally needed for large problems.
Iterative methods are more common than direct methods in numerical analysis. Some methods are direct in principle but are usually used as though they were not, e.g. GMRES and the conjugate gradient method. For these methods the number of steps needed to obtain the exact solution is so large that an approximation is accepted in the same manner as for an iterative method.
Discretization
Furthermore, continuous problems must sometimes be replaced by a discrete problem whose solution is known to approximate that of the continuous problem; this process is called discretization. For example, the solution of a differential equation is a function. This function must be represented by a finite amount of data, for instance by its value at a finite number of points at its domain, even though this domain is a continuum.
Generation and propagation of errors
The study of errors forms an important part of numerical analysis. There are several ways in which error can be introduced in the solution of the problem.
Roundoff
Roundoff errors arise because it is impossible to represent all real numbers exactly on a machine with finite memory (which is what all practical digital computers are).
Truncation and discretization error
Truncation errors are committed when an iterative method is terminated or a mathematical procedure is approximated, and the approximate solution differs from the exact solution. Similarly, discretization induces a discretization error because the solution of the discrete problem does not coincide with the solution of the continuous problem. For instance, in the iteration in the sidebar to compute the solution of ''3x^3+4=28'', after 10 or so iterations, we conclude that the root is roughly 1.99 (for example). We therefore have a truncation error of 0.01.
Once an error is generated, it will generally propagate through the calculation. For instance, we have already noted that the operation + on a calculator (or a computer) is inexact. It follows that a calculation of the type a+b+c+d+e is even more inexact.
What does it mean when we say that the truncation error is created when we approximate a mathematical procedure? We know that to integrate a function exactly requires one to find the sum of infinite trapezoids. But numerically one can find the sum of only finite trapezoids, and hence the approximation of the mathematical procedure. Similarly, to differentiate a function, the differential element approaches to zero but numerically we can only choose a finite value of the differential element.
Numerical stability and wellposed problems
Numerical stability is an important notion in numerical analysis. An algorithm is called numerically stable if an error, whatever its cause, does not grow to be much larger during the calculation. This happens if the problem is wellconditioned, meaning that the solution changes by only a small amount if the problem data are changed by a small amount. To the contrary, if a problem is illconditioned, then any small error in the data will grow to be a large error.
Both the original problem and the algorithm used to solve that problem can be wellconditioned and/or illconditioned, and any combination is possible.
So an algorithm that solves a wellconditioned problem may be either numerically stable or numerically unstable. An art of numerical analysis is to find a stable algorithm for solving a wellposed mathematical problem. For instance, computing the square root of 2 (which is roughly 1.41421) is a wellposed problem. Many algorithms solve this problem by starting with an initial approximation x_{1} to \sqrt{2}, for instance x_{1}=1.4, and then computing improved guesses x_{2}, x_{3}, etc.. One such method is the famous Babylonian method, which is given by x_{k+1} = x_{k}/2 + 1/x_{k}. Another iteration, which we will call Method X, is given by x_{k + 1} = (x_{k}^{2}−2)^{2} + x_{k}.^{[3]} We have calculated a few iterations of each scheme in table form below, with initial guesses x_{1} = 1.4 and x_{1} = 1.42.
Babylonian

Babylonian

Method X

Method X

x_{1} = 1.4

x_{1} = 1.42

x_{1} = 1.4

x_{1} = 1.42

x_{2} = 1.4142857...

x_{2} = 1.41422535...

x_{2} = 1.4016

x_{2} = 1.42026896

x_{3} = 1.414213564...

x_{3} = 1.41421356242...

x_{3} = 1.4028614...

x_{3} = 1.42056...



...

...



x_{1000000} = 1.41421...

x_{28} = 7280.2284...

Observe that the Babylonian method converges quickly regardless of the initial guess, whereas Method X converges extremely slowly with initial guess 1.4 and diverges for initial guess 1.42. Hence, the Babylonian method is numerically stable, while Method X is numerically unstable.

Numerical stability is affected by the number of the significant digits the machine keeps on, if we use a machine that keeps only the four most significant decimal digits, a good example on loss of significance is given by these two equivalent functions

f(x)=x\left(\sqrt{x+1}\sqrt{x}\right) \text{ and } g(x)=\frac{x}{\sqrt{x+1}+\sqrt{x}}.

If we compare the results of

f(500)=500 \left(\sqrt{501}\sqrt{500} \right)=500 \left(22.3822.36 \right)=500(0.02)=10

and

\begin{alignat}{3}g(500)&=\frac{500}{\sqrt{501}+\sqrt{500}}\\ &=\frac{500}{22.38+22.36}\\ &=\frac{500}{44.74}=11.17 \end{alignat}

by looking to the two results above, we realize that loss of significance (caused here by catastrophic cancelation) has a huge effect on the results, even though both functions are equivalent, as shown below

\begin{alignat}{4} f(x)&=x \left(\sqrt{x+1}\sqrt{x} \right)\\ &=x \left(\sqrt{x+1}\sqrt{x} \right)\frac{\sqrt{x+1}+\sqrt{x}}{\sqrt{x+1}+\sqrt{x}}\\ &=x\frac{(\sqrt{x+1})^2(\sqrt{x})^2}{\sqrt{x+1}+\sqrt{x}}\\ &=x\frac{x+1x}{\sqrt{x+1}+\sqrt{x}} \\ &=x\frac{1}{\sqrt{x+1}+\sqrt{x}} \\ &=\frac {x}{\sqrt{x+1}+\sqrt{x}} \\ &=g(x) \end{alignat}

The desired value, computed using infinite precision, is 11.174755...

The example is a modification of one taken from Mathew; Numerical methods using Matlab, 3rd ed.
Areas of study
The field of numerical analysis includes many subdisciplines. Some of the major ones are:
Computing values of functions
Interpolation: We have observed the temperature to vary from 20 degrees Celsius at 1:00 to 14 degrees at 3:00. A linear interpolation of this data would conclude that it was 17 degrees at 2:00 and 18.5 degrees at 1:30pm.
Extrapolation: If the gross domestic product of a country has been growing an average of 5% per year and was 100 billion dollars last year, we might extrapolate that it will be 105 billion dollars this year.
Regression: In linear regression, given n points, we compute a line that passes as close as possible to those n points.
Optimization: Say you sell lemonade at a lemonade stand, and notice that at $1, you can sell 197 glasses of lemonade per day, and that for each increase of $0.01, you will sell one glass of lemonade less per day. If you could charge $1.485, you would maximize your profit, but due to the constraint of having to charge a whole cent amount, charging $1.48 or $1.49 per glass will both yield the maximum income of $220.52 per day.
Differential equation: If you set up 100 fans to blow air from one end of the room to the other and then you drop a feather into the wind, what happens? The feather will follow the air currents, which may be very complex. One approximation is to measure the speed at which the air is blowing near the feather every second, and advance the simulated feather as if it were moving in a straight line at that same speed for one second, before measuring the wind speed again. This is called the Euler method for solving an ordinary differential equation.

One of the simplest problems is the evaluation of a function at a given point. The most straightforward approach, of just plugging in the number in the formula is sometimes not very efficient. For polynomials, a better approach is using the Horner scheme, since it reduces the necessary number of multiplications and additions. Generally, it is important to estimate and control roundoff errors arising from the use of floating point arithmetic.
Interpolation, extrapolation, and regression
Interpolation solves the following problem: given the value of some unknown function at a number of points, what value does that function have at some other point between the given points?
Extrapolation is very similar to interpolation, except that now we want to find the value of the unknown function at a point which is outside the given points.
Regression is also similar, but it takes into account that the data is imprecise. Given some points, and a measurement of the value of some function at these points (with an error), we want to determine the unknown function. The least squaresmethod is one popular way to achieve this.
Solving equations and systems of equations
Another fundamental problem is computing the solution of some given equation. Two cases are commonly distinguished, depending on whether the equation is linear or not. For instance, the equation 2x+5=3 is linear while 2x^2+5=3 is not.
Much effort has been put in the development of methods for solving systems of linear equations. Standard direct methods, i.e., methods that use some matrix decomposition are Gaussian elimination, LU decomposition, Cholesky decomposition for symmetric (or hermitian) and positivedefinite matrix, and QR decomposition for nonsquare matrices. Iterative methods such as the Jacobi method, Gauss–Seidel method, successive overrelaxation and conjugate gradient method are usually preferred for large systems. General iterative methods can be developed using a matrix splitting.
Rootfinding algorithms are used to solve nonlinear equations (they are so named since a root of a function is an argument for which the function yields zero). If the function is differentiable and the derivative is known, then Newton's method is a popular choice. Linearization is another technique for solving nonlinear equations.
Solving eigenvalue or singular value problems
Several important problems can be phrased in terms of eigenvalue decompositions or singular value decompositions. For instance, the spectral image compression algorithm^{[4]} is based on the singular value decomposition. The corresponding tool in statistics is called principal component analysis.
Optimization
Optimization problems ask for the point at which a given function is maximized (or minimized). Often, the point also has to satisfy some constraints.
The field of optimization is further split in several subfields, depending on the form of the objective function and the constraint. For instance, linear programming deals with the case that both the objective function and the constraints are linear. A famous method in linear programming is the simplex method.
The method of Lagrange multipliers can be used to reduce optimization problems with constraints to unconstrained optimization problems.
Evaluating integrals
Numerical integration, in some instances also known as numerical quadrature, asks for the value of a definite integral. Popular methods use one of the Newton–Cotes formulas (like the midpoint rule or Simpson's rule) or Gaussian quadrature. These methods rely on a "divide and conquer" strategy, whereby an integral on a relatively large set is broken down into integrals on smaller sets. In higher dimensions, where these methods become prohibitively expensive in terms of computational effort, one may use Monte Carlo or quasiMonte Carlo methods (see Monte Carlo integration), or, in modestly large dimensions, the method of sparse grids.
Differential equations
Numerical analysis is also concerned with computing (in an approximate way) the solution of differential equations, both ordinary differential equations and partial differential equations.
Partial differential equations are solved by first discretizing the equation, bringing it into a finitedimensional subspace. This can be done by a finite element method, a finite difference method, or (particularly in engineering) a finite volume method. The theoretical justification of these methods often involves theorems from functional analysis. This reduces the problem to the solution of an algebraic equation.
Software
Since the late twentieth century, most algorithms are implemented in a variety of programming languages. The Netlib repository contains various collections of software routines for numerical problems, mostly in Fortran and C. Commercial products implementing many different numerical algorithms include the IMSL and NAG libraries; a free alternative is the GNU Scientific Library.
There are several popular numerical computing applications such as MATLAB, TK Solver, SPLUS, LabVIEW, and IDL as well as free and open source alternatives such as FreeMat, Scilab, GNU Octave (similar to Matlab), IT++ (a C++ library), R (similar to SPLUS) and certain variants of Python. Performance varies widely: while vector and matrix operations are usually fast, scalar loops may vary in speed by more than an order of magnitude.^{[5]}^{[6]}
Many computer algebra systems such as Mathematica also benefit from the availability of arbitrary precision arithmetic which can provide more accurate results.
Also, any spreadsheet software can be used to solve simple problems relating to numerical analysis.
See also
Notes

^ tablet from the Yale Babylonian Collectionroot(2)Photograph, illustration, and description of the

^ The New Zealand Qualification authority specifically mentions this skill in document 13004 version 2, dated 17 October 2003 titled CARPENTRY THEORY: Demonstrate knowledge of setting out a building

^ This is a fixed point iteration for the equation x=(x^22)^2+x=f(x), whose solutions include \sqrt{2}. The iterates always move to the right since f(x)\geq x. Hence x_1=1.4<\sqrt{2} converges and x_1=1.42>\sqrt{2} diverges.

^ The Singular Value Decomposition and Its Applications in Image Compression

^ Speed comparison of various number crunching packages

^ Comparison of mathematical programs for data analysis Stefan Steinhaus, ScientificWeb.com
References






(examples of the importance of accurate arithmetic).

Trefethen, Lloyd N. (2006). "Numerical analysis", 20 pages. In: Timothy Gowers and June BarrowGreen (editors), Princeton Companion of Mathematics, Princeton University Press.
External links
Journals

Numerische Mathematik, volumes 166, Springer, 19591994 (searchable; pages are images). (English) (German)

Numerische Mathematik at SpringerLink, volumes 1112, Springer, 1959–2009

SIAM Journal on Numerical Analysis, volumes 147, SIAM, 1964–2009
Online texts


Numerical Recipes, William H. Press (free, downloadable previous editions)

First Steps in Numerical Analysis (archived), R.J.Hosking, S.Joe, D.C.Joyce, and J.C.Turner

(Computational Science Education Project)CSEP, U.S. Department of Energy
Online course material

Numerical Methods, Stuart Dalziel University of Cambridge

Lectures on Numerical Analysis, Dennis Deturck and Herbert S. Wilf University of Pennsylvania

Numerical methods, John D. Fenton University of Karlsruhe

Numerical Methods for Science, Technology, Engineering and Mathematics, Autar Kaw University of South Florida

Numerical Analysis Project, John H. Mathews California State University, Fullerton

Numerical Methods  Online Course, Aaron Naiman Jerusalem College of Technology

Numerical Methods for Physicists, Anthony O’Hare Oxford University

Lectures in Numerical Analysis (archived), R. Radok Mahidol University

Introduction to Numerical Analysis for Engineering, Henrik Schmidt Massachusetts Institute of Technology

Numerical Methods for timedependent Partial Differential Equations, J.W. Haverkort, based on a course by P.A. Zegeling Utrecht University

Numerical Analysis for Engineering, D. W. Harder University of Waterloo


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