1Math::Symbolic::VectorCUaslecrulCuosn(t3r)ibuted Perl DoMcautmhe:n:tSaytmiboonlic::VectorCalculus(3)
2
3
4
6 Math::Symbolic::VectorCalculus - Symbolically comp. grad, Jacobi
7 matrices etc.
8
10 use Math::Symbolic qw/:all/;
11 use Math::Symbolic::VectorCalculus; # not loaded by Math::Symbolic
12
13 @gradient = grad 'x+y*z';
14 # or:
15 $function = parse_from_string('a*b^c');
16 @gradient = grad $function;
17 # or:
18 @signature = qw(x y z);
19 @gradient = grad 'a*x+b*y+c*z', @signature; # Gradient only for x, y, z
20 # or:
21 @gradient = grad $function, @signature;
22
23 # Similar syntax variations as with the gradient:
24 $divergence = div @functions;
25 $divergence = div @functions, @signature;
26
27 # Again, similar DWIM syntax variations as with grad:
28 @rotation = rot @functions;
29 @rotation = rot @functions, @signature;
30
31 # Signatures always inferred from the functions here:
32 @matrix = Jacobi @functions;
33 # $matrix is now array of array references. These hold
34 # Math::Symbolic trees. Or:
35 @matrix = Jacobi @functions, @signature;
36
37 # Similar to Jacobi:
38 @matrix = Hesse $function;
39 # or:
40 @matrix = Hesse $function, @signature;
41
42 $wronsky_determinant = WronskyDet @functions, @vars;
43 # or:
44 $wronsky_determinant = WronskyDet @functions; # functions of 1 variable
45
46 $differential = TotalDifferential $function;
47 $differential = TotalDifferential $function, @signature;
48 $differential = TotalDifferential $function, @signature, @point;
49
50 $dir_deriv = DirectionalDerivative $function, @vector;
51 $dir_deriv = DirectionalDerivative $function, @vector, @signature;
52
53 $taylor = TaylorPolyTwoDim $function, $var1, $var2, $degree;
54 $taylor = TaylorPolyTwoDim $function, $var1, $var2,
55 $degree, $var1_0, $var2_0;
56 # example:
57 $taylor = TaylorPolyTwoDim 'sin(x)*cos(y)', 'x', 'y', 2;
58
60 This module provides several subroutines related to vector calculus
61 such as computing gradients, divergence, rotation, and Jacobi/Hesse
62 Matrices of Math::Symbolic trees. Furthermore it provides means of
63 computing directional derivatives and the total differential of a
64 scalar function and the Wronsky Determinant of a set of n scalar
65 functions.
66
67 Please note that the code herein may or may not be refactored into the
68 OO-interface of the Math::Symbolic module in the future.
69
70 EXPORT
71 None by default.
72
73 You may choose to have any of the following routines exported to the
74 calling namespace. ':all' tag exports all of the following:
75
76 grad
77 div
78 rot
79 Jacobi
80 Hesse
81 WronskyDet
82 TotalDifferential
83 DirectionalDerivative
84 TaylorPolyTwoDim
85
87 grad
88 This subroutine computes the gradient of a Math::Symbolic tree
89 representing a function.
90
91 The gradient of a function f(x1, x2, ..., xn) is defined as the vector:
92
93 ( df(x1, x2, ..., xn) / d(x1),
94 df(x1, x2, ..., xn) / d(x2),
95 ...,
96 df(x1, x2, ..., xn) / d(xn) )
97
98 (These are all partial derivatives.) Any good book on calculus will
99 have more details on this.
100
101 grad uses prototypes to allow for a variety of usages. In its most
102 basic form, it accepts only one argument which may either be a
103 Math::Symbolic tree or a string both of which will be interpreted as
104 the function to compute the gradient for. Optionally, you may specify a
105 second argument which must be a (literal) array of
106 Math::Symbolic::Variable objects or valid Math::Symbolic variable names
107 (strings). These variables will the be used for the gradient instead of
108 the x1, ..., xn inferred from the function signature.
109
110 div
111 This subroutine computes the divergence of a set of Math::Symbolic
112 trees representing a vectorial function.
113
114 The divergence of a vectorial function F = (f1(x1, ..., xn), ...,
115 fn(x1, ..., xn)) is defined like follows:
116
117 sum_from_i=1_to_n( dfi(x1, ..., xn) / dxi )
118
119 That is, the sum of all partial derivatives of the i-th component
120 function to the i-th coordinate. See your favourite book on calculus
121 for details. Obviously, it is important to keep in mind that the
122 number of function components must be equal to the number of
123 variables/coordinates.
124
125 Similar to grad, div uses prototypes to offer a comfortable interface.
126 First argument must be a (literal) array of strings and Math::Symbolic
127 trees which represent the vectorial function's components. If no second
128 argument is passed, the variables used for computing the divergence
129 will be inferred from the functions. That means the function signatures
130 will be joined to form a signature for the vectorial function.
131
132 If the optional second argument is specified, it has to be a (literal)
133 array of Math::Symbolic::Variable objects and valid variable names
134 (strings). These will then be interpreted as the list of variables for
135 computing the divergence.
136
137 rot
138 This subroutine computes the rotation of a set of three Math::Symbolic
139 trees representing a vectorial function.
140
141 The rotation of a vectorial function F = (f1(x1, x2, x3), f2(x1, x2,
142 x3), f3(x1, x2, x3)) is defined as the following vector:
143
144 ( ( df3/dx2 - df2/dx3 ),
145 ( df1/dx3 - df3/dx1 ),
146 ( df2/dx1 - df1/dx2 ) )
147
148 Or "nabla x F" for short. Again, I have to refer to the literature for
149 the details on what rotation is. Please note that there have to be
150 exactly three function components and three coordinates because the
151 cross product and hence rotation is only defined in three dimensions.
152
153 As with the previously introduced subroutines div and grad, rot offers
154 a prototyped interface. First argument must be a (literal) array of
155 strings and Math::Symbolic trees which represent the vectorial
156 function's components. If no second argument is passed, the variables
157 used for computing the rotation will be inferred from the functions.
158 That means the function signatures will be joined to form a signature
159 for the vectorial function.
160
161 If the optional second argument is specified, it has to be a (literal)
162 array of Math::Symbolic::Variable objects and valid variable names
163 (strings). These will then be interpreted as the list of variables for
164 computing the rotation. (And please excuse my copying the last two
165 paragraphs from above.)
166
167 Jacobi
168 Jacobi() returns the Jacobi matrix of a given vectorial function. It
169 expects any number of arguments (strings and/or Math::Symbolic trees)
170 which will be interpreted as the vectorial function's components.
171 Variables used for computing the matrix are, by default, inferred from
172 the combined signature of the components. By specifying a second
173 literal array of variable names as (second) argument, you may override
174 this behaviour.
175
176 The Jacobi matrix is the vector of gradient vectors of the vectorial
177 function's components.
178
179 Hesse
180 Hesse() returns the Hesse matrix of a given scalar function. First
181 argument must be a string (to be parsed as a Math::Symbolic tree) or a
182 Math::Symbolic tree. As with Jacobi(), Hesse() optionally accepts an
183 array of signature variables as second argument.
184
185 The Hesse matrix is the Jacobi matrix of the gradient of a scalar
186 function.
187
188 TotalDifferential
189 This function computes the total differential of a scalar function of
190 multiple variables in a certain point.
191
192 First argument must be the function to derive. The second argument is
193 an optional (literal) array of variable names (strings) and
194 Math::Symbolic::Variable objects to be used for deriving. If the
195 argument is not specified, the functions signature will be used. The
196 third argument is also an optional array and denotes the set of
197 variable (names) to use for indicating the point for which to evaluate
198 the differential. It must have the same number of elements as the
199 second argument. If not specified the variable names used as
200 coordinated (the second argument) with an appended '_0' will be used as
201 the point's components.
202
203 DirectionalDerivative
204 DirectionalDerivative computes the directional derivative of a scalar
205 function in the direction of a specified vector. With f being the
206 function and X, A being vectors, it looks like this: (this is a partial
207 derivative)
208
209 df(X)/dA = grad(f(X)) * (A / |A|)
210
211 First argument must be the function to derive (either a string or a
212 valid Math::Symbolic tree). Second argument must be vector into whose
213 direction to derive. It is to be specified as an array of variable
214 names and objects. Third argument is the optional signature to be used
215 for computing the gradient. Please see the documentation of the grad
216 function for details. It's dimension must match that of the directional
217 vector.
218
219 TaylorPolyTwoDim
220 This subroutine computes the Taylor Polynomial for functions of two
221 variables. Please refer to the documentation of the TaylorPolynomial
222 function in the Math::Symbolic::MiscCalculus package for an explanation
223 of single dimensional Taylor Polynomials. This is the counterpart in
224 two dimensions.
225
226 First argument must be the function to approximate with the Taylor
227 Polynomial either as a string or a Math::Symbolic tree. Second and
228 third argument must be the names of the two coordinates. (These may
229 alternatively be Math::Symbolic::Variable objects.) Fourth argument
230 must be the degree of the Taylor Polynomial. Fifth and Sixth arguments
231 are optional and specify the names of the variables to introduce as the
232 point of approximation. These default to the names of the coordinates
233 with '_0' appended.
234
235 WronskyDet
236 WronskyDet() computes the Wronsky Determinant of a set of n functions.
237
238 First argument is required and a (literal) array of n functions. Second
239 argument is optional and a (literal) array of n variables or variable
240 names. If the second argument is omitted, the variables used for
241 deriving are inferred from function signatures. This requires, however,
242 that the function signatures have exactly one element. (And the
243 function this exactly one variable.)
244
246 Please send feedback, bug reports, and support requests to the
247 Math::Symbolic support mailing list: math-symbolic-support at lists dot
248 sourceforge dot net. Please consider letting us know how you use
249 Math::Symbolic. Thank you.
250
251 If you're interested in helping with the development or extending the
252 module's functionality, please contact the developers' mailing list:
253 math-symbolic-develop at lists dot sourceforge dot net.
254
255 List of contributors:
256
257 Steffen Mueller, symbolic-module at steffen-mueller dot net
258 Stray Toaster, mwk at users dot sourceforge dot net
259 Oliver Ebenhoeh
260
262 New versions of this module can be found on http://steffen-mueller.net
263 or CPAN. The module development takes place on Sourceforge at
264 http://sourceforge.net/projects/math-symbolic/
265
266 Math::Symbolic
267
268
269
270perl v5.32.1 2021-01-27 Math::Symbolic::VectorCalculus(3)