Struct bacon_sci::ivp::BDF6

pub struct BDF6<N: ComplexField> { /* fields omitted */ }

6th order backwards differentiation formula method for solving an initial value problem.

Defines the higher and lower order coefficients. Uses BDFInfo for the actual solving.

Examples

use nalgebra::DVector;
use bacon_sci::ivp::{IVPSolver, BDF6, BDFSolver};
fn derivatives(_t: f64, state: &[f64], _p: &mut ()) -> Result<DVector<f64>, String> {
    Ok(-DVector::from_column_slice(state))
}

fn example() -> Result<(), String> {
    let bdf = BDF6::new()
        .with_dt_max(0.1)?
        .with_dt_min(0.00001)?
        .with_tolerance(0.00001)?
        .with_start(0.0)?
        .with_end(10.0)?
        .with_initial_conditions(&[1.0])?
        .build();
    let path = bdf.solve_ivp(derivatives, &mut ())?;
    for (time, state) in &path {
        assert!(((-time).exp() - state.column(0)[0]).abs() < 0.001);
    }
    Ok(())
}

Implementations

impl<N: ComplexField> BDF6<N>

pub fn new() -> Self

Trait Implementations

impl<N: ComplexField> BDFSolver<N> for BDF6<N>

pub fn higher_coefficients() -> Vec<N::RealField>

The polynomial interpolation coefficients for the higher-order method. Should start with the coefficient for the derivative function without h, then n - 1. The coefficients for the previous terms should have the sign as if they're on the same side of the = as the next state.

pub fn lower_coefficients() -> Vec<N::RealField>

The polynomial interpolation coefficients for the lower-order method. Must be one less in length than higher_coefficients. Should start with the coefficient for the derivative function without h, then n-1. The coefficients for the previous terms should have the sign as if they're on the same side of the = as the next state.

pub fn solve_ivp<T: Clone, F: Fn(N::RealField, &[N], &mut T) -> Result<DVector<N>, String>>(
    self,
    f: F,
    params: &mut T
) -> Result<Vec<(N::RealField, DVector<N>)>, String>

Use BDFInfo to solve an initial value problem

pub fn with_tolerance(self, tol: N::RealField) -> Result<Self, String>

Set the error tolerance for this solver.

pub fn with_dt_max(self, max: N::RealField) -> Result<Self, String>

Set the maximum time step for this solver.

pub fn with_dt_min(self, min: N::RealField) -> Result<Self, String>

Set the minimum time step for this solver.

pub fn with_start(self, t_initial: N::RealField) -> Result<Self, String>

Set the initial time for this solver.

pub fn with_end(self, t_final: N::RealField) -> Result<Self, String>

Set the end time for this solver.

pub fn with_initial_conditions(self, start: &[N]) -> Result<Self, String>

Set the initial conditions for this solver.

pub fn build(self) -> Self

Build this solver.

impl<N: Clone + ComplexField> Clone for BDF6<N>

pub fn clone(&self) -> BDF6<N>

Returns a copy of the value.

pub fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl<N: Debug + ComplexField> Debug for BDF6<N>

pub fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter.

impl<N: ComplexField> Default for BDF6<N>

pub fn default() -> Self

Returns the "default value" for a type.

impl<N: ComplexField> From<BDF6<N>> for BDFInfo<N>

pub fn from(bdf: BDF6<N>) -> BDFInfo<N>

Performs the conversion.