nalgebra/nalgebra-lapack/tests/linalg/complex_eigen.rs
2022-10-30 17:22:08 +01:00

48 lines
1.6 KiB
Rust

use na::Matrix3;
use nalgebra_lapack::Eigen;
use num_complex::Complex;
#[test]
fn complex_eigen() {
let m = Matrix3::<f64>::new(
4.0 / 5.0,
-3.0 / 5.0,
0.0,
3.0 / 5.0,
4.0 / 5.0,
0.0,
1.0,
2.0,
2.0,
);
let eigen = Eigen::new(m, true, true).expect("Eigen Creation Failed!");
let (some_eigenvalues, some_left_vec, some_right_vec) = eigen.get_complex_elements();
let eigenvalues = some_eigenvalues.expect("Eigenvalues Failed");
let _left_eigenvectors = some_left_vec.expect("Left Eigenvectors Failed");
let eigenvectors = some_right_vec.expect("Right Eigenvectors Failed");
assert_relative_eq!(
eigenvalues[0].re,
Complex::<f64>::new(4.0 / 5.0, 3.0 / 5.0).re
);
assert_relative_eq!(
eigenvalues[0].im,
Complex::<f64>::new(4.0 / 5.0, 3.0 / 5.0).im
);
assert_relative_eq!(
eigenvalues[1].re,
Complex::<f64>::new(4.0 / 5.0, -3.0 / 5.0).re
);
assert_relative_eq!(
eigenvalues[1].im,
Complex::<f64>::new(4.0 / 5.0, -3.0 / 5.0).im
);
assert_relative_eq!(eigenvectors[0][0].re, -12.0 / 32.7871926215100059134410999);
assert_relative_eq!(eigenvectors[0][0].im, -9.0 / 32.7871926215100059134410999);
assert_relative_eq!(eigenvectors[0][1].re, -9.0 / 32.7871926215100059134410999);
assert_relative_eq!(eigenvectors[0][1].im, 12.0 / 32.7871926215100059134410999);
assert_relative_eq!(eigenvectors[0][2].re, 25.0 / 32.7871926215100059134410999);
assert_relative_eq!(eigenvectors[0][2].im, 0.0);
}