scipy.special.
jnyn_zeros#
- scipy.special.jnyn_zeros(n, nt)[source]#
- Compute nt zeros of Bessel functions Jn(x), Jn’(x), Yn(x), and Yn’(x). - Returns 4 arrays of length nt, corresponding to the first nt zeros of Jn(x), Jn’(x), Yn(x), and Yn’(x), respectively. The zeros are returned in ascending order. - Parameters:
- nint
- Order of the Bessel functions 
- ntint
- Number (<=1200) of zeros to compute 
 
- Returns:
- Jnndarray
- First nt zeros of Jn 
- Jnpndarray
- First nt zeros of Jn’ 
- Ynndarray
- First nt zeros of Yn 
- Ynpndarray
- First nt zeros of Yn’ 
 
 - References [1]- Zhang, Shanjie and Jin, Jianming. “Computation of Special Functions”, John Wiley and Sons, 1996, chapter 5. https://people.sc.fsu.edu/~jburkardt/f77_src/special_functions/special_functions.html - Examples - Compute the first three roots of \(J_1\), \(J_1'\), \(Y_1\) and \(Y_1'\). - >>> from scipy.special import jnyn_zeros >>> jn_roots, jnp_roots, yn_roots, ynp_roots = jnyn_zeros(1, 3) >>> jn_roots, yn_roots (array([ 3.83170597, 7.01558667, 10.17346814]), array([2.19714133, 5.42968104, 8.59600587])) - Plot \(J_1\), \(J_1'\), \(Y_1\), \(Y_1'\) and their roots. - >>> import numpy as np >>> import matplotlib.pyplot as plt >>> from scipy.special import jnyn_zeros, jvp, jn, yvp, yn >>> jn_roots, jnp_roots, yn_roots, ynp_roots = jnyn_zeros(1, 3) >>> fig, ax = plt.subplots() >>> xmax= 11 >>> x = np.linspace(0, xmax) >>> x[0] += 1e-15 >>> ax.plot(x, jn(1, x), label=r"$J_1$", c='r') >>> ax.plot(x, jvp(1, x, 1), label=r"$J_1'$", c='b') >>> ax.plot(x, yn(1, x), label=r"$Y_1$", c='y') >>> ax.plot(x, yvp(1, x, 1), label=r"$Y_1'$", c='c') >>> zeros = np.zeros((3, )) >>> ax.scatter(jn_roots, zeros, s=30, c='r', zorder=5, ... label=r"$J_1$ roots") >>> ax.scatter(jnp_roots, zeros, s=30, c='b', zorder=5, ... label=r"$J_1'$ roots") >>> ax.scatter(yn_roots, zeros, s=30, c='y', zorder=5, ... label=r"$Y_1$ roots") >>> ax.scatter(ynp_roots, zeros, s=30, c='c', zorder=5, ... label=r"$Y_1'$ roots") >>> ax.hlines(0, 0, xmax, color='k') >>> ax.set_ylim(-0.6, 0.6) >>> ax.set_xlim(0, xmax) >>> ax.legend(ncol=2, bbox_to_anchor=(1., 0.75)) >>> plt.tight_layout() >>> plt.show() 