aboutsummaryrefslogtreecommitdiff
path: root/src/hyper/pages/exseries.ht
blob: 0746c2b041f878bb81156e31dbc75ea9460b4aea (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
% Copyright The Numerical Algorithms Group Limited 1991.
% Certain derivative-work portions Copyright (C) 1988 by Leslie Lamport.
% All rights reserved

% Title: Series
 
% Address comments and questions to the
%   Computer Algebra Group, Mathematical Sciences Department
%   IBM Thomas J. Watson Research Center, Box 218
%   Yorktown Heights, New York  10598  USA
 
%  Author: Clifton J. Williamson
%  Date created: 2 November 1989
%  Date last updated: 2 November 1989
 
\begin{page}{ExSeriesConvert}{Converting Expressions to Series}
\beginscroll
You can convert a functional expression to a power series by using the
function 'series'.
Here's an example:
\spadpaste{series(sin(a*x),x = 0)}
This causes {\em sin(a*x)} to be expanded in powers of {\em (x - 0)}, that is, in powers
of {\em x}.
You can have {\em sin(a*x)} expanded in powers of {\em (a - \%pi/4)} by
issuing the following command:
\spadpaste{series(sin(a*x),a = \%pi/4)}
\endscroll
\autobuttons\end{page}
 
\begin{page}{ExSeriesManipulate}{Manipulating Power Series}
\beginscroll
Once you have created a power series, you can perform arithmetic operations
on that series.
First compute the Taylor expansion of {\em 1/(1-x)}:
\spadpaste{f := series(1/(1-x),x = 0) \bound{f}}
Now compute the square of that series:
\spadpaste{f ** 2 \free{f}}
It's as easy as 1, 2, 3,...
\endscroll
\autobuttons\end{page}
 
\begin{page}{ExSeriesFunctions}{Functions on Power Series}
\beginscroll
The usual elementary functions ({\em log}, {\em exp}, trigonometric functions, etc.)
are defined for power series.
You can create a power series:
% Warning: currently there are (interpretor) problems with converting
% rational functions and polynomials to power series.
\spadpaste{f := series(1/(1-x),x = 0) \bound{f1}}
and then apply these functions to the series:
\spadpaste{g := log(f) \free{f1} \bound{g}}
\spadpaste{exp(g) \free{g}}
\endscroll
\autobuttons\end{page}
 
\begin{page}{ExSeriesSubstitution}{Substituting Numerical Values in Power Series}
\beginscroll
Here's a way to obtain numerical approximations of {\em e} from the Taylor series
expansion of {\em exp(x)}.
First you create the desired Taylor expansion:
\spadpaste{f := taylor(exp(x)) \bound{f2}}
Now you evaluate the series at the value {\em 1.0}:
% Warning: syntax for evaluating power series may change.
\spadpaste{eval(f,1.0) \free{f2}}
You get a sequence of partial sums.
\endscroll
\autobuttons\end{page}