bvp: Boundary Value Problems
In pracma: Practical Numerical Math Functions
bvp R Documentation
Boundary Value Problems
Description
Solves boundary value problems of linear second order differential equations.
Usage
bvp(f, g, h, x, y, n = 50)
Arguments
f, g, h
functions on the right side of the differential equation.
If f, g or h is a scalar instead of a function, it is
assumed to be a constant coefficient in the differential equation.
x
x[1], x[2] are the interval borders where the solution
shall be computed.
y
boundary conditions such that
y(x[1]) = y[1], y(x[2]) = y[2].
n
number of intermediate grid points; default 50.
Details
Solves the two-point boundary value problem given as a linear differential
equation of second order in the form:
y'' = f(x) y' + g(x) y + h(x)
with the finite element method. The solution y(x) shall exist
on the interval [a, b] with boundary conditions y(a) = y_a
and y(b) = y_b.
Value
Returns a list list(xs, ys) with the grid points xs and the
values ys of the solution at these points, including the boundary
points.
Note
Uses a tridiagonal equation solver that may be faster then qr.solve
for large values of n.
References
Kutz, J. N. (2005). Practical Scientific Computing. Lecture Notes
98195-2420, University of Washington, Seattle.
See Also
shooting
Examples
## Solve y'' = 2*x/(1+x^2)*y' - 2/(1+x^2) * y + 1
## with y(0) = 1.25 and y(4) = -0.95 on the interval [0, 4]:
f1 <- function(x) 2*x / (1 + x^2)
f2 <- function(x) -2 / (1 + x^2)
f3 <- function(x) rep(1, length(x)) # vectorized constant function 1
x <- c(0.0, 4.0)
y <- c(1.25, -0.95)
sol <- bvp(f1, f2, f3, x, y)
## Not run:
plot(sol$xs, sol$ys, ylim = c(-2, 2),
xlab = "", ylab = "", main = "Boundary Value Problem")
# The analytic solution is
sfun <- function(x) 1.25 + 0.4860896526*x - 2.25*x^2 +
2*x*atan(x) - 1/2 * log(1+x^2) + 1/2 * x^2 * log(1+x^2)
xx <- linspace(0, 4)
yy <- sfun(xx)
lines(xx, yy, col="red")
grid()
## End(Not run)
pracma documentation built on March 19, 2024, 3:05 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
| bvp | R Documentation |
Boundary Value Problems
Description
Solves boundary value problems of linear second order differential equations.
Usage
bvp(f, g, h, x, y, n = 50)
Arguments
f, g, h |
functions on the right side of the differential equation.
If |
x |
|
y |
boundary conditions such that
|
n |
number of intermediate grid points; default 50. |
Details
Solves the two-point boundary value problem given as a linear differential equation of second order in the form:
y'' = f(x) y' + g(x) y + h(x)
with the finite element method. The solution y(x) shall exist
on the interval [a, b] with boundary conditions y(a) = y_a
and y(b) = y_b.
Value
Returns a list list(xs, ys) with the grid points xs and the
values ys of the solution at these points, including the boundary
points.
Note
Uses a tridiagonal equation solver that may be faster then qr.solve
for large values of n.
References
Kutz, J. N. (2005). Practical Scientific Computing. Lecture Notes 98195-2420, University of Washington, Seattle.
See Also
shooting
Examples
## Solve y'' = 2*x/(1+x^2)*y' - 2/(1+x^2) * y + 1
## with y(0) = 1.25 and y(4) = -0.95 on the interval [0, 4]:
f1 <- function(x) 2*x / (1 + x^2)
f2 <- function(x) -2 / (1 + x^2)
f3 <- function(x) rep(1, length(x)) # vectorized constant function 1
x <- c(0.0, 4.0)
y <- c(1.25, -0.95)
sol <- bvp(f1, f2, f3, x, y)
## Not run:
plot(sol$xs, sol$ys, ylim = c(-2, 2),
xlab = "", ylab = "", main = "Boundary Value Problem")
# The analytic solution is
sfun <- function(x) 1.25 + 0.4860896526*x - 2.25*x^2 +
2*x*atan(x) - 1/2 * log(1+x^2) + 1/2 * x^2 * log(1+x^2)
xx <- linspace(0, 4)
yy <- sfun(xx)
lines(xx, yy, col="red")
grid()
## End(Not run)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.