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SymPy vs. Maple

SymPy vs. Maple

SymPy and Maple are Computer algebra systems.

Computer Algebra System
A software program that facilitates symbolic mathematics. The core functionality of a CAS is manipulation of mathematical expressions in symbolic form.

SymPy

Sympy is a Python library for symbolic computation that aims to become a full-featured computer algebra system and to keep the code simple to promote extensibility and comprehensibility.

SymPy was started by Ondřej Čertík in 2005 and he wrote some code in 2006 as well. In 11 March 2007, SymPy was realeased to the public. The latest stable release of SymPy is 0.7.1 (29 July 2011). As of beginning of December 2011 there have been over 150 people who contributed at least one commit to SymPy.

SymPy can be used:

  • Inside Python, as a library
  • As an interactive command line, using IPython

SymPy is entirely written in Python and does not require any external libraries, but various programs that can extend its capabilites can be installed:

  • gmpy, Cython --> speed improvement
  • Pyglet, Matplotlib --> 2d and 3d plotting
  • IPython --> interactive sessions

SymPy is available online at SymPy Live. The site was developed specifically for SymPy. It is a simple web shell that looks similar to iSymPy under the standard Python interpreter. SymPy Live uses Google App Engine as computational backend.

+ +: small library, pure Python, very functional, extensible, large community.

- -: slow, needs better documentation.

Maple

Maple is a general-purpose commercial computer algebra system.

Maple was created by the University of Waterloo, Canada and the development began in 1980. Since 1988, Maple has been developed and sold commercially by Waterloo Maple (Maplesoft). The first public release was in 1984. The latest stable release of Maple is Maple 15.01 (21 June 2011).

Maple is based on a small kernel, written in C, which provides the Maple language. Many libraries from a variety of sources provide functionality to Maple: NAG Numerical Libraries, ATLAS libraries, GMP libraries. Most of the libraries are written in the Maple language and have viewable source code.

Maple is proprietary software restricted by copyright law. You can get Maple for a while if you complete a registration form for an evaluation on their web site. The next step would be to talk to a Maple representative for further information. Maple isn't provided automatically after filling out that form. If you want to use Maple for more than the evaluation days, then you can choose one of these versions:

  • Commercial - $2,275
  • Government - $2,155
  • Academic - $1245
  • Personal Edition - $239
  • Student - $99
  • Student (12-Month term) - $79

+ +: full scientific stack, very functional, fast.

- -: very large, expensive, not a library, not open source (proprietary).

Sympy (!)= Maple

SymPy is a cost free open source CAS written entirely in Python released under a modified BSD license while Maple is proprietary software released under a proprietary commercial license.

One of the differences between SymPy and Maple is the fact that Maple comes with both a GUI and a command line interface. However, SymPy can use plotting as well, by installing Pyglet.

Operating System Support

System Windows Mac OS X Linux BSD Solaris Other
SymPy Yes Yes Yes Yes Yes Any system that supports Python
Maple Yes Yes Yes No Yes No

Download & Installation

Sympy is distributed in various forms. It is possible to download source tarballs and packages from the Google Code page but it is also possible to clone the main Git repository or browse the code online. The only prerequisite is Python since Sympy is Python-based library. It is recommended to install IPython as well, for a better experience.

Maple can be downloaded from the official site after you either get an evaluation version or purchase it.

Functionality

System

Formula

editor

Arbitrary

precision

Calculus Solvers
Integration Integral transforms* Equations Inequalities Diophantine equations Differential equations
SymPy No Yes Yes No Yes Yes No Yes
Maple Yes Yes Yes Yes Yes Yes No Yes
System Solvers

Graph

theory

Number

theory

Quantifier

elimination

Boolean

algebra

Tensors
Recurrence relations
SymPy Yes No Yes No Yes Yes
Maple Yes Yes Yes No No Yes

* Will be available in SymPy 0.7.2

Note

This document contains some examples from Maple's documentation and are under a different license than SymPy.

Some syntax differences

In SymPy, to raise something to a power, you must use **, not ^ as the latter uses the Python meaning, which is xor.

In [1]: (x+1)^2
---------------------------------------------------------------------------
TypeError                                 Traceback (most recent call last)
/home/aoi_hana/sympy/<ipython-input-6-52730bce1577> in <module>()
----> 1 (x+1)^2

TypeError: unsupported operand type(s) for ^: 'Add' and 'int'

In [2]: (x+1)**2
Out[2]:
       2
(x + 1)

However, in Maple, both ^ and ** mean exponentiation:

> (x+1)^2;
       2
(x + 1)
> (x+1)**2;
       2
(x + 1)

Another difference between SymPy and Maple is that you have to define symbols in SymPy before you can use them, while in Maple it isn't necessary.

SymPy

>>> x**2 + 2*x + 1
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
NameError: name 'x' is not defined

>>> from sympy import Symbol
>>> x = Symbol('x')
>>> x**2 + 2*x + 1
x**2 + 2*x + 1

Maple

> x**2 + 2*x + 1;
x^2 + 2*x + 1

Algebra

SymPy

To perform partial fraction decomposition apart(expr, x) must be used. To combine expressions, together(expr, x) is what you need. Here are some examples of these two and other common functions in iSymPy:

In [8]: 1/( (x**2+2*x+1)*(x**2-1) )
Out[8]:
           1
───────────────────────
⎛ 2    ⎞ ⎛ 2          ⎞
⎝x  - 1⎠⋅⎝x  + 2⋅x + 1⎠

In [9]: apart(1/( (x**2+2*x+1)*(x**2-1) ), x)
Out[9]:
      1           1            1            1
- ───────── - ────────── - ────────── + ─────────
  8⋅(x + 1)            2            3   8⋅(x - 1)
              4⋅(x + 1)    2⋅(x + 1)

In [10]: together(1/(x**2+2*x) - 3/(x+y) + 1/(x+y+z))
Out[10]:
x⋅(x + 2)⋅(x + y) - 3⋅x⋅(x + 2)⋅(x + y + z) + (x + y)⋅(x + y + z)
─────────────────────────────────────────────────────────────────
                  x⋅(x + 2)⋅(x + y)⋅(x + y + z)

The evalf() method and the N() function can be used to evaluate expressions:

In [20]: pi.evalf()
Out[20]: 3.14159265358979

In [23]: N(sqrt(2)*pi, 50)
Out[23]: 4.4428829381583662470158809900606936986146216893757

Integrals can be used like regular expressions and support arbitrary precision:

In [24]: Integral(x**(-2*x), (x, 0, oo)).evalf(20)
Out[24]: 2.0784499818221828310

Maple

Here are some examples of algebra in Maple:

Expand(expr, expr1, expr2,..., exprn) expands an expression. This method is equal to the apart(expr, x) method from SymPy.

> expand((x^2+x+1)/(x+2));
  2
 x        x       1
----- + ----- + -----
x + 2   x + 2   x + 2

The evalf() method evaluates expressions:

> evalf(Pi)
3.141592654

> evalf(sqrt(2)*Pi)
4.442882938

Divide(a, b, 'q', options) does a check for exact divisibility for polynomials with algebraic number coefficients.

> with(Algebraic):
> Divide(x^2+1, x+I, 'q');
true

> q;
x-I

Calculus

Limits

SymPy

Limits in SymPy have the following syntax: limit(function, variable, point). Here are some examples:

Limit of f(x)= sin(x)/x as x -> 0

In [20]: from sympy import *

In [21]: x = Symbol('x')

In [22]: limit(sin(x)/x, x, 0)
Out[22]: 1

Limit of f(x)= 2*x+1 as x -> 5/2

In [24]: limit(2*x+1, x, S(5)/2)     # The *S()* method must be used for 5/2 to be Rational in SymPy
Out[24]: 6

Maple

The limit(f, x=a, dir) function attempts to compute the limiting value of f as x approaches a.

> limit(sin(x)/x, x = 0);
1

Limit of f(x)= 2*x+1 as x -> 5/2

> limit(2*x+1, x = 5/2);
6
Differentiation

SymPy

In [1]: from sympy import *

In [2]: x = Symbol('x')

In [3]: diff(cos(x**3), x)
Out[3]:
    2    ⎛ 3⎞
-3⋅x ⋅sin⎝x ⎠

In [4]: diff(atan(2*x), x)
Out[4]:
   2
────────
   2
4⋅x  + 1

In [6]: diff(1/tan(x), x)
Out[6]:
     2
- tan (x) - 1
─────────────
     2
  tan (x)

This is how you create a Bessel function of the first kind object and differentiate it:

In [7]: from sympy import besselj, jn

In [8]: from sympy.abc import z, n

In [9]: b = besselj(n, z)

In [10]: # Differentiate it:

In [11]: b.diff(z)
Out[11]:
besselj(n - 1, z)   besselj(n + 1, z)
───────────────── - ─────────────────
        2                   2

Maple

Here are some examples of differentiation:

> diff(cos(x^3), x)
o17.png
> diff(1/tan(x), x)
o18.png
> diff(1/cot(x^2), x)
o19.png

BesselJ(v, x) is the Bessel function of the first kind. It satisfies Bessel's equation: x^2*y''+x*y'+(x^2-v^2)*y = 0

> BesselJ(v, x)
BesselJ(v, x)

> diff(BesselJ(v, x), x)
o20.png
> series(BesselJ(5, x), x)
o21.png
Series expansion

SymPy

The syntax for series expansion is: .series(var, point, order):

In [27]: from sympy import *

In [28]: x = Symbol('x')

In [29]: cos(x).series(x, 0, 14)
Out[29]:
     2    4     6      8       10         12
    x    x     x      x       x          x         ⎛ 14⎞
1 - ── + ── - ─── + ───── - ─────── + ───────── + O⎝x  ⎠
    2    24   720   40320   3628800   479001600

In [30]: (1/cos(x**2)).series(x, 0, 14)
Out[30]:
     4      8       12
    x    5⋅x    61⋅x      ⎛ 14⎞
1 + ── + ──── + ────── + O⎝x  ⎠
    2     24     720

It is possible to make use of series(x*cos(x), x) by creating a wrapper around Basic.series().

In [31]: from sympy import Symbol, cos, series
In [32]: x = Symbol('x')
In [33]: series(cos(x), x)
Out[33]:
     2    4
    x    x     ⎛ 6⎞
1 - ── + ── + O⎝x ⎠
    2    24

This module also implements automatic keeping track of the order of your expansion.

In [1]: from sympy import Symbol, Order

In [2]: x = Symbol('x')

In [3]: Order(x) + x**2
Out[3]: O(x)

In [4]: Order(x) + 28
Out[4]: 28 + O(x)

Maple

The taylor(expr, x=a, n) command computes the order n Taylor series expansion of expr, with respect to the variable x, about the point a.

> taylor(cos(x), x = 0, 14)
o15.png
> taylor(1/cos(x^2), x = 0, 14)
o16.png

order(expr) determines the truncation order of a series:

> order(taylor(1/cos(x^2), x = 0, 14))+28
42

> order(taylor(1/cos(x^2), x = 0, 14))+x^2
14+x^2

> series(1/(1-x), x)
1+x+x^2+x^3+x^4+x^5+O(x^6)          (1)

> order((1))
6
Integration

SymPy

The integrals module in SymPy implements methods calculating definite and indefinite integrals of expressions. Principal method in this module is integrate():

  • integrate(f, x) returns the indefinite integral int1
  • integrate(f, (x, a, b)) returns the definite integral int2

SymPy can integrate:

  • polynomial functions:
In [6]: from sympy import *

In [7]: import sys

In [8]: from sympy import init_printing

In [9]: init_printing(use_unicode=False, wrap_line=False, no_global=True)

In [10]: x = Symbol('x')

In [11]: integrate(x**2 + 2*x + 4, x)
 3
x     2
── + x  + 4⋅x
3
  • rational functions:
In [1]: integrate((x+1)/(x**2+4*x+4), x)
Out[1]:
               1
log(x + 2) + ─────
             x + 2
  • exponential-polynomial functions:
In [5]: integrate(5*x**2 * exp(x) * sin(x), x)
Out[5]:
   2  x             2  x                             x             x
5⋅x ⋅ℯ ⋅sin(x)   5⋅x ⋅ℯ ⋅cos(x)        x          5⋅ℯ ⋅sin(x)   5⋅ℯ ⋅cos(x)
────────────── - ────────────── + 5⋅x⋅ℯ ⋅cos(x) - ─────────── - ──────────
      2                2                               2             2
  • non-elementary integrals:
In [11]: integrate(exp(-x**2)*erf(x), x)
  ___    2
╲╱ π ⋅erf (x)
─────────────
      4

Here is an example of a definite integral (Calculate integral1):

In [1]: integrate(x**2 * cos(x), (x, 0, pi/2))
Out[1]:
      2
     π
-2 + ──
     4

Maple

The int(expr, x) calling sequence computes an indefinite integral of the expr with respect to the variable x.

  • polynomial functions:
> f := x^2+2*x+4:
> int(f, x)
o1.png
  • rational functions:
> f := (x+1)/(x^2+4*x+4):
> int(f, x)
o2.png
  • exponential-polynomial functions:
> f := 5*x^2*exp(x)*sin(x):
> int(f, x)
o3.png
  • non-exponential integrals:
> f := exp(-x^2)*erf(x):
> int(f, x)
o4.png

The int(expr, x=a..b) calling sequence computes the definite integral of the expr with respect to the variable x on the interval from a to b.

> int(x^2*cos(x), x = 0 .. (1/2)*Pi)
o5.png
Complex numbers

SymPy

In [1]: from sympy import Symbol, exp, I

In [2]: x = Symbol("x")

In [3]: exp(I*2*x).expand()
Out[3]:
 2⋅ⅈ⋅x
ℯ

In [4]: exp(I*2*x).expand(complex=True)
Out[4]:
   -2⋅im(x)                 -2⋅im(x)
ⅈ⋅ℯ        ⋅sin(2⋅re(x)) + ℯ        ⋅cos(2⋅re(x))

In [5]: x = Symbol("x", real=True)

In [6]: exp(I*2*x).expand(complex=True)
Out[6]: ⅈ⋅sin(2⋅x) + cos(2⋅x)

In [7]: exp(-2 + 3*I*x).expand(complex=True)
Out[7]:
  -2             -2
ⅈ⋅ℯ  ⋅sin(3⋅x) + ℯ  ⋅cos(3⋅x)

Complex number division in iSymPy:

In [4]: from sympy import I
In [5]: ((2 + 3*I)/(3 + 7*I)).expand(complex=True)
Out[5]:
27   5⋅ⅈ
── - ───
58    58

Maple

> exp(I*2*x);
o12.png

To return a complex number in 'a+bI' format in Maple, there is the evalc(expr) command, which is a symbolic evaluator over the complex field.

> evalc(exp(2*I*x));
cn1.png
> assume(x::real);
> evalc(exp((2*I)*x));
cn2.png
> assume(x::real);
> evalc(exp(-2+(3*I)*x));
cn3.png

Complex numbers division in Maple:

> (2+3*I)/(3+7*I);
cn4.png
Functions

SymPy

trigonometric

In [1]: cos(x-y).expand(trig=True)
Out[1]: sin(x)⋅sin(y) + cos(x)⋅cos(y)

In [2]: cos(2*x).expand(trig=True)
Out[2]:
     2
2⋅cos (x) - 1

In [3]: sinh(I*x**2)
Out[3]:
     ⎛ 2⎞
ⅈ⋅sin⎝x ⎠

In [11]: sinh(acosh(x))
Out[11]:
  _______   _______
╲╱ x - 1 ⋅╲╱ x + 1

zeta function

In [4]: zeta(5, x**2)
Out[4]:
 ⎛    2⎞
ζ⎝5, x ⎠

In [5]: zeta(5, 2)
Out[5]: ζ(5, 2)

In [6]: zeta(4, 1)
Out[6]:
 4
π
──
90

In [5]: zeta(28).evalf()
Out[5]: 1.00000000372533

factorials and gamma function

In [7]: a = Symbol('a')

In [8]: b = Symbol('b', integer=True)

In [9]: factorial(a)
Out[9]: a!

In [13]: gamma(b+2).series(b, 0, 3)
Out[13]:
                        2  2             2  2
                       π ⋅b    EulerGamma ⋅b                2    ⎛ 3⎞
1 + b - EulerGamma⋅b + ───── + ────────────── - EulerGamma⋅b  + O⎝b ⎠
                         12          2

polynomials

In [14]: chebyshevt(8,x)
Out[14]:
     8        6        4       2
128⋅x  - 256⋅x  + 160⋅x  - 32⋅x  + 1

In [15]: legendre(3, x)
Out[15]:
   3
5⋅x    3⋅x
──── - ───
 2      2

In [16]: hermite(3, x**2)
Out[16]:
   6       2
8⋅x  - 12⋅x

Maple

trigonometric

> expand(cos(x-y))
cos(x)*cos(y)+sin(x)*sin(y)

> expand(cos(2*x))
2*cos(x)^2-1

> sinh(I*x^2)
I*sin(x^2)

> simplify(sin(x)^2*cos(y)^2+cos(x)^2*sin(y)^2, trig)
o11.png

zeta function

> Zeta(5, 2)
o9.png
> Zeta(1, 1/2)
o10.png
> Zeta(2.2)
1.490543257

factorials and gamma function

> a!
a!

> 10!
3628800

> GAMMA(1.0+2.5*I, 2.0+3.5*I)
0.1314614269e-1+0.6253182683e-2*I

polynomials

> ChebyshevT(8, x)
ChebyshevT(8, x)

> series((4),'ChebyshevT')
o6.png
> LegendreP(3, x)
LegendreP(3, x)

> series((6),'LegendreP')
o7.png
> HermiteH(3, x^2)
HermiteH(3, x^2)            (8)

> series((8),'HermiteH')
o8.png
Differential equations

SymPy

In iSymPy:

In [10]: f(x).diff(x, x) + f(x)
Out[10]:
         2
        d
f(x) + ───(f(x))
         2
       dx

In [11]: dsolve(f(x).diff(x, x) + f(x), f(x))
Out[11]: f(x) = C₁⋅sin(x) + C₂⋅cos(x)

Maple

The D and diff commands can both compute derivatives. The D operator computes derivatives of operators, while diff computes derivatives of expressions.

> D(ln)(x)
1/x         (4)

> convert((4), diff)
1/x

> diff(sin(x), x)
cos(x)

The dsolve(ODE, y(x), options) command solves ordinary differential equations (ODEs):

> dsolve(diff(f(x), x)+f(x), f(x))
o26.png

In this example, we define a derivative using the diff command and solve the ODE.

> ode := diff(y(x), x, x) = 2*y(x)+1
o27.png
> dsolve(ode)
o28.png
Algebraic equations

SymPy

In iSymPy:

In [3]: solve(x**3 + 2*x**2 - 1, x)
Out[3]:
⎡            ___      ___    ⎤
⎢      1   ╲╱ 5     ╲╱ 5    1⎥
⎢-1, - ─ + ─────, - ───── - ─⎥
⎣      2     2        2     2⎦


In [5]: solve( [x**2 + 4*y**2 -2, -10*x + 2*y -15], [x, y])
Out[5]:
⎡⎛          ____              ____  ⎞  ⎛          ____              ____   ⎞⎤
⎢⎜  150   ╲╱ 23 ⋅ⅈ   15   5⋅╲╱ 23 ⋅ⅈ ⎟  ⎜  150   ╲╱ 23 ⋅ⅈ   15   5⋅╲╱ 23 ⋅  ⎟⎥
⎢⎜- ─── - ────────, ─── - ──────────⎟, ⎜- ─── + ────────, ─── + ────────── ⎟⎥
⎣⎝  101     101     202      101    ⎠  ⎝  101     101     202      101     ⎠⎦

Maple

> solve(x^3+2*x^3-1, x)
o13.png
> solve({x+2*y = 3, y+1/x = 1}, [x, y])
o14.png

Linear Algebra

Matrices

SymPy

In SymPy, matrices are created as instances from the Matrix class:

In [1]: from sympy import Matrix

In [2]: Matrix([ [1, 0 , 0], [0, 1, 0], [0, 0, 1] ])
Out[2]:
⎡1  0  0⎤
⎢       ⎥
⎢0  1  0⎥
⎢       ⎥
⎣0  0  1⎦

It is possible to slice submatrices, since this is Python:

In [4]: M = Matrix(2, 3, [1, 2, 3, 4, 5, 6])

In [5]: M[0:2,0:2]
Out[5]:
⎡1  2⎤
⎢    ⎥
⎣4  5⎦

In [6]: M[1:2,2]
Out[6]: [6]

In [7]: M[:,2]
Out[7]:
⎡3⎤
⎢ ⎥
⎣6⎦

One basic operation involving matrices is the determinant:

In [8]: M = Matrix(( [2, 5, 6], [4, 7, 10], [1, 0, 3] ))

In [9]: M.det()
Out[9]: -10

print_nonzero(symb='x') shows location of non-zero entries for fast shape lookup.

In [10]: M = Matrix(( [2, 0, 0, 1, 0], [3, 5, 0, 1, 0], [10, 4, 0, 1, 2], [1, 6, 0, 0, 0], [0, 4, 0, 2, 2] ))
In [12]: M
Out[12]:
⎡2   0  0  1  0⎤
⎢              ⎥
⎢3   5  0  1  0⎥
⎢              ⎥
⎢10  4  0  1  2⎥
⎢              ⎥
⎢1   6  0  0  0⎥
⎢              ⎥
⎣0   4  0  2  2⎦

In [13]: M.print_nonzero()
[X  X ]
[XX X ]
[XX XX]
[XX   ]
[ X XX]

Matrix transposition with transpose():

In [14]: from sympy import Matrix, I

In [15]: m = Matrix(( (1,2+I), (3,4) ))

In [16]: m
Out[16]:
⎡1  2 + ⅈ⎤
⎢        ⎥
⎣3    4  ⎦

In [17]: m.transpose()
Out[17]:
⎡  1    3⎤
⎢        ⎥
⎣2 + ⅈ  4⎦

In [19]: m.T == m.transpose()
Out[19]: True

The multiply_elementwise(b) method returns the Hadamard product (elementwise product) of A and B:

In [14]: import sympy

In [15]: A = sympy.Matrix([ [1, 3, 20], [1, 18, 3] ])
In [17]: B = sympy.Matrix([ [0, 5, 10], [4, 20, 6] ])

In [18]: print A.multiply_elementwise(B)
[0,  15, 200]
[4, 360,  18]

Maple

You can create a matrix in Maple by using the Matrix palette or by using Maple's matrix notation. Here are a few examples:

> <<1, 0, 0>|<0, 1, 0>|<0, 0, 1>>
(1)
ma1.png

To assign a name to a matrix you have to type name := * and use an equation label to refer to the matrix by typing Ctrl+L. In the *Insert Label box type 1.

> A := (1)
(2)
ma1.png

To perform matrix calculations, you must use the context menu. Right click on the matrix and select Standard Operations>Determinant to find the determinant.

> <<2, 4, 1>|<5, 7, 0>|<6, 10, 3>>
ma2.png

To compute the transpose of a matrix you have to go to Standard Operations>Transpose.

> <<1, 3>|<2+I, 4>>
ma3.png

The function hadamard(A) computes a bound on the maxnorm of det(A) where A is an n by n matrix.

> with(LinearAlgebra):
> A := matrix(2, 2, [1, 3, 18, 3]);
o22.png
> B := matrix(2, 2, [10, 4, 20, 6]);
o23.png
> hadamard(A);
o24.png
> hadamard(B);
o25.png

Geometry

SymPy

The geometry module can be used to create two-dimensional geometrical entities and query information about them. These entities are available:

  • Point
  • Line, Ray, Segment
  • Ellipse, Circle
  • Polygon, RegularPolygon, Triangle

Check if points are collinear:

In [37]: from sympy import *

In [38]: from sympy.geometry import *

In [39]: x = Point(0, 0)

In [40]: y = Point(3, 1)

In [41]: z = Point(5, 5)

In [42]: Point.is_collinear(x, y, z)
Out[42]: False

In [43]: Point.is_collinear(x, z)
Out[43]: True

Segment declaration, slope, length, midpoint:

In [1]: import sympy

In [2]: from sympy import Point

In [3]: from sympy.abc import s

In [4]: from sympy.geometry import Segment

In [5]: Segment( (1, 2), (2, -3))
Out[5]: ((1,), (2,))

In [6]: s = Segment(Point(4, 3), Point(1, 1))

In [7]: s
Out[7]: ((1,), (4,))

In [8]: s.points
Out[8]: ((1,), (4,))

In [9]: s.slope
Out[9]: 2/3

In [10]: s.length
Out[10]:
  ____
╲╱ 13

In [11]: s.midpoint
Out[11]: (5/2,)

Maple

The commands in the geometry module enable you to work in two-dimensional Euclidean geometry.

Define a point (point(P,Px,Py)):

> with(geometry):
> point(A, 2, 3);
A

The detail(P) command returns a detailed expression of the point P.

> detail(A);
o29.png

Check if points are collinear:

Note that it is necessary to define at least three points for the AreCollinear() command because it has only the following syntax: AreCollinear(P, Q, R, cond), where P, Q, R are three previously defined points and cond is an optional name.

> with(geometry):
> point(A, 0, 0), point(B, 3, 1), point(C, 5, 5), point(F, 2, 2);
> AreCollinear(A, B, C);
false
> AreCollinear(A, C, F);
true

Define a segment (segment(seg, [P1, P2])):

> with(geometry):
> point(A, 1, 2), point(B, 2, -3);
A, B
> segment(AB, [A,B])
AB
> DefinedAs(AB)
[A,B]               (3)
> map(coord
[ [1, 2], [2, -3] ]

Pattern matching

SymPy

Using the .match method and the Wild class you can perform pattern matching on expressions. The method returns a dictionary with the needed substitutions. Here is an example:

In [11]: from sympy import *

In [12]: x = Symbol('x')

In [13]: y = Wild('y')

In [14]: (10*x**3).match(y*x**3)
Out[14]: {y: 10}

In [15]: s = Wild('s')

In [16]: (x**4).match(y*x**s)
Out[16]: {s: 4, y: 1}

SymPy returns None if the match is unsuccessful:

In [19]: print (x+1).match(y**x)
None

Maple

The match(expr = pattern, v, 's') calling sequence returns true if it can match expr to pattern for some values of the variables (excluding the main variable, v). Otherwise, it returns false.

> match(10*x^3 = y*x^3, x, 's')
true

> s;
{y = 10}

> match(x^4 = y*x^q, x, 's')
true

> s;
{q = 4, y = 1}

Printing

SymPy

There are many ways of printing mathematical expressions. Two of the most common methods are:

  • Standard printing
  • Pretty printing using the pprint() function
  • Pretty printing using the init_printing() method

Standard printing is the return value of str(expression):

>>> from sympy import Integral   # Python session
>>> from sympy.abc import c
>>> print c**3
c**3
>>> print 2/c
2/c
>>> print Integral(c**2+2*c, c)
Integral(c**2 + 2*c, c)

Pretty printing is a nice ascii-art printing with the help of a pprint function.

In [1]: from sympy import Integral, pprint   # IPython session (pprint enabled by default)

In [2]: from sympy.abc import c

In [3]: pprint(c**3)
 3
c

In [4]: pprint(2/c)
2
─
c

In [5]: pprint(Integral(c**2+2*c, c))
⌠
⎮ ⎛ 2      ⎞
⎮ ⎝c  + 2⋅c⎠ dc
⌡

However, the proper way to set up pretty printing in SymPy is to use init_printing(pretty_print=True, order=None, use_unicode=None, wrap_line=None, num_columns=None, no_global=False, ip=None):

>>> from sympy import init_printing
>>> init_printing(use_unicode=False, wrap_line=False, no_global=True)
>>> from sympy import Integral, Symbol
>>> x = Symbol('x')
>>> Integral(x**3+2*x+1, x)
  /
 |
 | / 3          \
 | \x  + 2*x + 1/ dx
 |
/
>>> init_printing(pretty_print=True)
>>> Integral(x**3+2*x+1, x)
⌠
⎮ ⎛ 3          ⎞
⎮ ⎝x  + 2⋅x + 1⎠ dx
⌡

Maple

There are several methods to print expressions in Maple:

  • print(e1, e2, ...) command
  • lprint(expr1, expr2,...) command
  • fprintf, sprintf, nprintf, printf commands
  • 2d ascii pretty printing in command line

The print(e1, e2, ...) command is equal to the pprint() method from SymPy.

> print(c^3);
o30.png
> print(2/c);
o31.png
> print('int(c^2+2*c, c)');
o32.png

The lprint(expr1, expr2, ...) performs linear printing of expressions and is the same as the standard printing (the print() method) from SymPy.

> lprint(sin(x)^2+cos(x)^2);
o33.png
> lprint(int(sin(x+y)/(x-y), x))
o34.png

Note that in command-line Maple, the output of lprint cna be cut and paste into a Maple session while pretty-printed output cannot.

There are other printing commands that have similar syntax to the print command:

  • fprintf - prints expressions to a file or pipe based on a format string
  • sprintf - prints expressions to a string based on a format string
  • nprintf - prints expressions to a name based on a format string
  • printf - prints expressions to a default stream based on a format string

The fprintf() command returns a count of the number of characters written.

> fd := fopen("temp_file", WRITE);
1
> fprintf(fd, "x = %d, y = %g", 2, 1.5);
14
> fclose(fd);

The nprintf() command is the same as sprintf(), except that it returns a Maple symbol (a simple name) instead of a string.

> sprintf("%o %x", 2805, 2805); or nprintf("%o %x", 2805, 2805);
o35.png o36.png
> printf("%-2.5s:%2.5s:%2.5s", S, Sym, SymPyV);
o37.png

Maple also has a 2d ASCII pretty printer that is used with the command line interface.

Plotting

SymPy

Pyglet is required to use the plotting function of SymPy in 2d and 3d. Here is an example:

>>> from sympy import symbols, Plot, cos, sin
>>> x, y = symbols('x y')
>>> Plot(sin(x*10)*cos(y*5) - x*y)
[0]: -x*y + sin(10*x)*cos(5*y), 'mode=cartesian'
Output of the plotting example
In[1]: Plot(cos(x*y*10))
Out[1]: [0]: cos(10*x*y), 'mode=cartesian'
plot13.png
In [22]: Plot(1*x**2, [], [x], 'mode=cylindrical') # [unbound_theta,0,2*Pi,40], [x,-1,1,20]
Out[22]: [0]: x**2, 'mode=cylindrical'
plot20.png

Maple

There are two main methods to generate plots in Maple:

  • plot(f, x=x0..x1) command to create a 2d plot
  • plot3d(expr, x=a..b, y=c..d, opts) command for 3d plotting

Here are some examples:

> plot(BesselJ(1, x), x = -30 .. 30);
plot15.png
> plot3d({x+2*y, sin(x*y)}, x = -Pi .. Pi, y = -Pi .. Pi);
plot16.png
> plot3d(cos(10*x*y), x = -1 .. 1, y = -1 .. 1);
plot17.png
> plot3d(height, angle = 0 .. 2*Pi, height = -5 .. 5, coords = cylindrical, title = CONE);
plot18.png
> plot3d(r*cos(theta), r = 0 .. 10, theta = 0 .. 2*Pi, coords = cylindrical, orientation = [100, 71], axes = NONE);
plot19.png

Conclusion

SymPy aims to be a lightweight normal Python module so as to become a nice open source alternative to Maple. Its goal is to be reasonably fast, easily extended with your own ideas, be callable from Python and could be used in real world problems. Another advantage of SymPy compared to Maple is that since it is written in pure Python (and doesn't need anything else), it is perfectly multiplatform, it's small and easy to install and use.

You can choose to use either SymPy or Maple, depending on what your needs are. For more information you can go to the official sites of SymPy and Maple.

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