Difference between revisions of "Maple/Differential Equations/Old"
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== Derivatives in Maple == | == Derivatives in Maple == | ||
− | Maple uses the <code>diff</code> command to calculate and represent | + | [[Maple]] uses the <code>diff</code> command to calculate and represent |
derivatives. The first argument will be the variable or function of | derivatives. The first argument will be the variable or function of | ||
which you want the derivative, and the second and later arguments will | which you want the derivative, and the second and later arguments will | ||
Line 16: | Line 16: | ||
you could first define a variable to hold on to the function and then | you could first define a variable to hold on to the function and then | ||
use the <code>diff</code> command to perform the required differentiation. | use the <code>diff</code> command to perform the required differentiation. | ||
− | Start a Maple worksheet with the following lines | + | Start a Maple worksheet with the following lines: |
<source lang=text> | <source lang=text> | ||
− | restart | + | restart; |
− | + | f:=exp(-t)*cos(omega*t-k*x); | |
− | f:=exp(-t)*cos(omega*t-k*x) | + | a:=diff(f, t); |
− | + | b:=diff(f, x); | |
− | a:=diff(f, t) | ||
− | |||
− | b:=diff(f, x) | ||
</source> | </source> | ||
Notice, among other things, that Maple properly renders the <math>\omega</math> | Notice, among other things, that Maple properly renders the <math>\omega</math> | ||
Line 40: | Line 37: | ||
you should add: | you should add: | ||
<source lang=text> | <source lang=text> | ||
− | c:=diff(f, t$3) | + | c:=diff(f, t$3); |
</source> | </source> | ||
to the worksheet. | to the worksheet. | ||
+ | |||
+ | [[Category:EGR 224]] | ||
+ | [[Category:ECE 382]] | ||
+ | [[Category:ME 344]] | ||
==Ordinary Differential Equations in Maple== | ==Ordinary Differential Equations in Maple== | ||
Line 57: | Line 58: | ||
differential. Add the following to your Maple script: | differential. Add the following to your Maple script: | ||
<source lang=text> | <source lang=text> | ||
− | deqn1:=diff(x(t), t)+x(t)=cos(t) | + | deqn1:=diff(x(t), t)+x(t)=cos(t); |
</source> | </source> | ||
Note in this case that you ''must'' explicitly define the variable | Note in this case that you ''must'' explicitly define the variable | ||
Line 70: | Line 71: | ||
command: | command: | ||
<source lang=text> | <source lang=text> | ||
− | dsolve({deqn1, x(0)=1}, [x(t)]) | + | dsolve({deqn1, x(0)=1}, [x(t)]); |
</source> | </source> | ||
and Maple will produce the answer: | and Maple will produce the answer: | ||
Line 88: | Line 89: | ||
can write: | can write: | ||
<source lang=text> | <source lang=text> | ||
− | acceqns := diff(x(t), t$2)=0, diff(y(t), t$2) = -g | + | acceqns := diff(x(t), t$2)=0, diff(y(t), t$2) = -g; |
− | dsolve({acceqns, x(0)=x0, y(0)=y0, (D)(x)(0)=vx0, (D)(y)(0)=vy0}, [x(t), y(t)]) | + | dsolve({acceqns, x(0)=x0, y(0)=y0, (D)(x)(0)=vx0, (D)(y)(0)=vy0}, [x(t), y(t)]); |
</source> | </source> | ||
which will produce the by-now very familiar answers: | which will produce the by-now very familiar answers: | ||
Line 102: | Line 103: | ||
== Using Solutions and Substituting Parameters for Differential Equations == | == Using Solutions and Substituting Parameters for Differential Equations == | ||
In order to use these solutions, you should give them a name. Click | In order to use these solutions, you should give them a name. Click | ||
− | at the start of the <code>solve</code> line and pre-pend it with <code> | + | at the start of the <code>solve</code> line and pre-pend it with <code>soln:=</code> so it resembles: |
<source lang=text> | <source lang=text> | ||
− | + | soln:=dsolve({acceqns, x(0)=x0, y(0)=y0, (D)(x)(0)=vx0, (D)(y)(0)=vy0}, [x(t), y(t)]); | |
</source> | </source> | ||
This will assign the solution list to a variable that we can use | This will assign the solution list to a variable that we can use | ||
Line 117: | Line 118: | ||
In a similar fashion to the first lab, add the following lines of code: | In a similar fashion to the first lab, add the following lines of code: | ||
<source lang=text> | <source lang=text> | ||
− | Vals := x0=0, y0=5, vx0=5, vy0=5, g=9.8 | + | Vals := x0=0, y0=5, vx0=5, vy0=5, g=9.8; |
− | subs(Vals, | + | subs(Vals, soln); |
</source> | </source> | ||
− | The list in <code> | + | The list in <code>soln</code> will now be shown with numerical values |
instead of symbols. Remember that you have {\it not} made any actual | instead of symbols. Remember that you have {\it not} made any actual | ||
changes to any of the variables. | changes to any of the variables. | ||
Line 127: | Line 128: | ||
==Using Representations of Differential Equations== | ==Using Representations of Differential Equations== | ||
Note that you can also use the <code>subs</code> command to replace variables | Note that you can also use the <code>subs</code> command to replace variables | ||
− | contained in <code> | + | contained in <code>soln</code>. This is very useful if, for example, the |
answer you are | answer you are | ||
looking for is some function of the variables <math>x(t)</math> and <math>y(t)</math>. | looking for is some function of the variables <math>x(t)</math> and <math>y(t)</math>. | ||
Line 140: | Line 141: | ||
symbolic representation for <code>speed</code>: | symbolic representation for <code>speed</code>: | ||
<source lang=text> | <source lang=text> | ||
− | speed := subs( | + | speed := subs(soln, sqrt((diff(x(t), t))^2+(diff(y(t), t))^2)); |
</source> | </source> | ||
To get Maple to take the derivatives, you can write | To get Maple to take the derivatives, you can write | ||
<source lang=text> | <source lang=text> | ||
− | speed := expand(subs( | + | speed := expand(subs(soln, sqrt((diff(x(t), t))^2+(diff(y(t), t))^2))); |
</source> | </source> | ||
If you want a numerical value, | If you want a numerical value, | ||
Line 150: | Line 151: | ||
before: | before: | ||
<source lang=text> | <source lang=text> | ||
− | subs(Vals, speed) | + | subs(Vals, speed); |
</source> | </source> | ||
− | To both substitute both equations in <code> | + | To both substitute both equations in <code>soln</code> and the values in |
<code>Vals</code> simultaneously, you would need to write: | <code>Vals</code> simultaneously, you would need to write: | ||
<source lang=text> | <source lang=text> | ||
− | subs( | + | subs(soln[], Vals, speed); |
</source> | </source> | ||
− | where the <code> | + | where the <code>soln[]</code> is used to take the two equations in <code> soln</code> out of their brackets. Depending on the number and organization of solutions, the solution variable may be stored in different kinds of list. Unfortunately, Maple is somewhat picky about "unlisting" or "unset-ting" things. |
The following table shows how to make substitutions for different | The following table shows how to make substitutions for different | ||
kinds of lists. Note that "row" refers to the row on which the | kinds of lists. Note that "row" refers to the row on which the | ||
Line 165: | Line 166: | ||
{|style="border-collapse: separate; border-spacing: 0; border-width: 1px; border-style: solid; border-color: #000; padding: 0" | {|style="border-collapse: separate; border-spacing: 0; border-width: 1px; border-style: solid; border-color: #000; padding: 0" | ||
|- | |- | ||
− | !style="border-style: solid; border-width: 0 1px 1px 0"| | + | !style="border-style: solid; border-width: 0 1px 1px 0"| soln |
!style="border-style: solid; border-width: 0 1px 1px 0"| Substitution format | !style="border-style: solid; border-width: 0 1px 1px 0"| Substitution format | ||
!style="border-style: solid; border-width: 0 0 1px 0"| Comment | !style="border-style: solid; border-width: 0 0 1px 0"| Comment | ||
|- | |- | ||
− | |style="border-style: solid; border-width: 0 1px 0 0"| | + | |style="border-style: solid; border-width: 0 1px 0 0"| soln:= a=1 |
− | |style="border-style: solid; border-width: 0 1px 0 0"| subs( | + | |style="border-style: solid; border-width: 0 1px 0 0"| subs(soln, Other eqns., Target eqn.) |
|style="border-style: solid; border-width: 0" | Single solution | |style="border-style: solid; border-width: 0" | Single solution | ||
|- | |- | ||
− | |style="border-style: solid; border-width: 0 1px 0 0"| <nowiki> | + | |style="border-style: solid; border-width: 0 1px 0 0"| <nowiki>soln:=[[a=1, b=2]]</nowiki> |
− | |style="border-style: solid; border-width: 0 1px 0 0"| subs( | + | |style="border-style: solid; border-width: 0 1px 0 0"| subs(soln[1][], Other eqns., Target eqn.) |
|style="border-style: solid; border-width: 0" | Single solution list | |style="border-style: solid; border-width: 0" | Single solution list | ||
|- | |- | ||
− | |style="border-style: solid; border-width: 0 1px 0 0"| | + | |style="border-style: solid; border-width: 0 1px 0 0"| soln:=[[a=1, b=2], [a=3, b=4]] |
− | |style="border-style: solid; border-width: 0 1px 0 0"| subs( | + | |style="border-style: solid; border-width: 0 1px 0 0"| subs(soln[row][], Other eqns., Target eqn.) |
|style="border-style: solid; border-width: 0" | Multiple solution list | |style="border-style: solid; border-width: 0" | Multiple solution list | ||
|- | |- | ||
− | |style="border-style: solid; border-width: 0 1px 0 0"| | + | |style="border-style: solid; border-width: 0 1px 0 0"| soln:={a=1, b=2} |
− | |style="border-style: solid; border-width: 0 1px 0 0"| subs( | + | |style="border-style: solid; border-width: 0 1px 0 0"| subs(soln[], Other eqns., Target eqn.) |
|style="border-style: solid; border-width: 0" | Single solution set | |style="border-style: solid; border-width: 0" | Single solution set | ||
|- | |- | ||
− | |style="border-style: solid; border-width: 0 1px 0 0"| | + | |style="border-style: solid; border-width: 0 1px 0 0"| soln:={{a=1, b=2}, {a=3, b=4}} |
− | |style="border-style: solid; border-width: 0 1px 0 0"| subs( | + | |style="border-style: solid; border-width: 0 1px 0 0"| subs(soln[row][], Other eqns., Target eqn.) |
|style="border-style: solid; border-width: 0" | Multiple solution set | |style="border-style: solid; border-width: 0" | Multiple solution set | ||
|} | |} | ||
</center> | </center> | ||
+ | |||
+ | == Extra Information == | ||
+ | === Complicated Results === | ||
+ | If your results look overly complicated - for example, there are several complicated exponentials (including complex exponentials) or there is a phrase "RootOf" and a bunch of Z's, there are a few things to try: | ||
+ | * Use <code>method=laplace</code> in the <solve>line</solve>:<syntaxhighlight>soln:=dsolve({numeqn}, [var], method=laplace)</syntaxhighlight> | ||
+ | * If that still produces something huge, you can look at a simplified and numerical version of the solution by using some Maple conversion and simplification commands:<syntaxhighlight>solnn := evalf[4](combine(expand(convert(soln, expsincos))))</syntaxhighlight> If this works, you may want to put a : after the <code>soln</code> line so you do not have to see the very complicated version. | ||
+ | |||
+ | === Initial and Long-Term Behavior === | ||
+ | Once you have your solutions, you can use the following to look at the initial values and the long-term values (for constant sources): <syntaxhighlight>map(k -> limit(k, t = 0), soln) | ||
+ | map(k -> limit(k, t = infinity), soln)</syntaxhighlight> If one or more of these produce complicated-looking results, you can use the numerical version of the solutions to hopefully get something clearer: <syntaxhighlight>map(k -> limit(k, t = 0), solnn) | ||
+ | map(k -> limit(k, t = infinity), solnn)</syntaxhighlight> Try the <code>soln</code> version first as the <code>solnn</code> version may have roudoff error. | ||
+ | |||
+ | |||
+ | == Examples == | ||
+ | * [[Maple/Differential Equations/RC Example]] - Example with a simple RC-Circuit using DC Steady State to determine initial conditions |
Latest revision as of 22:00, 26 February 2024
Contents
Derivatives in Maple
Maple uses the diff
command to calculate and represent
derivatives. The first argument will be the variable or function of
which you want the derivative, and the second and later arguments will
be the differentiation variables. For example, to find:
you could first define a variable to hold on to the function and then
use the diff
command to perform the required differentiation.
Start a Maple worksheet with the following lines:
restart;
f:=exp(-t)*cos(omega*t-k*x);
a:=diff(f, t);
b:=diff(f, x);
Notice, among other things, that Maple properly renders the \(\omega\) and that it understands that \(f\) is a function of at least \(t\) and \(x\). You can take multiple derivatives of the same variable by appending a dollar-sign and the order of the derivative to the differentiation variable. For example, to complete:
you should add:
c:=diff(f, t$3);
to the worksheet.
Ordinary Differential Equations in Maple
Since the diff
function can be used to represent derivatives, it
can also be used to define differential equations. For example, to
solve the system:
you would start by defining an equation to represent the differential. Add the following to your Maple script:
deqn1:=diff(x(t), t)+x(t)=cos(t);
Note in this case that you must explicitly define the variable \(x\) to be a function of \(t\); otherwise, Maple will assume that the derivative of undefined variable \(x\) with respect to undefined variable \(t\) is simply 0!
Thus defined, you can solve for the system using Maple's dsolve
function. This function takes two arguments - a set of equations
(including initial conditions) to solve and a list of the
variable(s) for which to solve. In this particular case, add the
command:
dsolve({deqn1, x(0)=1}, [x(t)]);
and Maple will produce the answer:
If you are solving second or higher order derivatives, or for a multiple variable system, you will need to provide initial values for the variables and some of their derivatives. For instance, to solve for the mathematical expression of a cannonball launched into a frictionless sky from some initial position (\(x_0\), \(y_0\)) at some initial velocity (\(u_0\), \(v_0\)), you can write:
acceqns := diff(x(t), t$2)=0, diff(y(t), t$2) = -g;
dsolve({acceqns, x(0)=x0, y(0)=y0, (D)(x)(0)=vx0, (D)(y)(0)=vy0}, [x(t), y(t)]);
which will produce the by-now very familiar answers:
Using Solutions and Substituting Parameters for Differential Equations
In order to use these solutions, you should give them a name. Click
at the start of the solve
line and pre-pend it with soln:=
so it resembles:
soln:=dsolve({acceqns, x(0)=x0, y(0)=y0, (D)(x)(0)=vx0, (D)(y)(0)=vy0}, [x(t), y(t)]);
This will assign the solution list to a variable that we can use later.
Now that you have the symbolic answers to the variables \(x(t)\) and \(y(t)\), you may want to substitute the actual coefficient values to obtain a numerical solution, though you will likely leave at least one variable alone. For example, in this case, you will not substitute anything in for \(t\).
In a similar fashion to the first lab, add the following lines of code:
Vals := x0=0, y0=5, vx0=5, vy0=5, g=9.8;
subs(Vals, soln);
The list in soln
will now be shown with numerical values
instead of symbols. Remember that you have {\it not} made any actual
changes to any of the variables.
Using Representations of Differential Equations
Note that you can also use the subs
command to replace variables
contained in soln
. This is very useful if, for example, the
answer you are
looking for is some function of the variables \(x(t)\) and \(y(t)\).
Assuming that you have determined the variable you are looking for,
speed
, is
you can now use the symbolic representations in Maple to generate a
symbolic representation for speed
:
speed := subs(soln, sqrt((diff(x(t), t))^2+(diff(y(t), t))^2));
To get Maple to take the derivatives, you can write
speed := expand(subs(soln, sqrt((diff(x(t), t))^2+(diff(y(t), t))^2)));
If you want a numerical value,
you can again use the subs
command and the value list from
before:
subs(Vals, speed);
To both substitute both equations in soln
and the values in
Vals
simultaneously, you would need to write:
subs(soln[], Vals, speed);
where the soln[]
is used to take the two equations in soln
out of their brackets. Depending on the number and organization of solutions, the solution variable may be stored in different kinds of list. Unfortunately, Maple is somewhat picky about "unlisting" or "unset-ting" things.
The following table shows how to make substitutions for different
kinds of lists. Note that "row" refers to the row on which the
specific substitutions to be used are:
soln | Substitution format | Comment |
---|---|---|
soln:= a=1 | subs(soln, Other eqns., Target eqn.) | Single solution |
soln:=[[a=1, b=2]] | subs(soln[1][], Other eqns., Target eqn.) | Single solution list |
soln:=[[a=1, b=2], [a=3, b=4]] | subs(soln[row][], Other eqns., Target eqn.) | Multiple solution list |
soln:={a=1, b=2} | subs(soln[], Other eqns., Target eqn.) | Single solution set |
soln:={{a=1, b=2}, {a=3, b=4}} | subs(soln[row][], Other eqns., Target eqn.) | Multiple solution set |
Extra Information
Complicated Results
If your results look overly complicated - for example, there are several complicated exponentials (including complex exponentials) or there is a phrase "RootOf" and a bunch of Z's, there are a few things to try:
- Use
method=laplace
in the <solve>line</solve>:soln:=dsolve({numeqn}, [var], method=laplace)
- If that still produces something huge, you can look at a simplified and numerical version of the solution by using some Maple conversion and simplification commands:If this works, you may want to put a : after the
solnn := evalf[4](combine(expand(convert(soln, expsincos))))
soln
line so you do not have to see the very complicated version.
Initial and Long-Term Behavior
Once you have your solutions, you can use the following to look at the initial values and the long-term values (for constant sources):
map(k -> limit(k, t = 0), soln)
map(k -> limit(k, t = infinity), soln)
If one or more of these produce complicated-looking results, you can use the numerical version of the solutions to hopefully get something clearer:
map(k -> limit(k, t = 0), solnn)
map(k -> limit(k, t = infinity), solnn)
Try the soln
version first as the solnn
version may have roudoff error.
Examples
- Maple/Differential Equations/RC Example - Example with a simple RC-Circuit using DC Steady State to determine initial conditions