<p>好的,开始工作了。问题出在我的实现上。我用了另一种方法,分别构造样条曲线,而不是连续构造。这是一种功能完备的三次样条插值方法,首先构造样条多项式的系数(这是99%的工作),然后实现它们。显然这不是唯一的办法。如果有兴趣的话,我可以用另一种方式发布。有一件事可以澄清代码是一个线性系统的图像,这是解决了,但我不能张贴图片,直到我的代表达到10。如果您想深入了解算法,请参阅上面注释中的“教科书”链接。</p>
<pre><code>import matplotlib.pyplot as plt
from pylab import arange
from math import e
from math import pi
from math import sin
from math import cos
from numpy import poly1d
# need some zero vectors...
def zeroV(m):
z = [0]*m
return(z)
#INPUT: n; x0, x1, ... ,xn; a0 = f(x0), a1 =f(x1), ... , an = f(xn).
def cubic_spline(n, xn, a):
"""function cubic_spline(n,xn, a, xd) interpolates between the knots
specified by lists xn and a. The function computes the coefficients
and outputs the ranges of the piecewise cubic splines."""
h = zeroV(n-1)
# alpha will be values in a system of eq's that will allow us to solve for c
# and then from there we can find b, d through substitution.
alpha = zeroV(n-1)
# l, u, z are used in the method for solving the linear system
l = zeroV(n+1)
u = zeroV(n)
z = zeroV(n+1)
# b, c, d will be the coefficients along with a.
b = zeroV(n)
c = zeroV(n+1)
d = zeroV(n)
for i in range(n-1):
# h[i] is used to satisfy the condition that
# Si+1(xi+l) = Si(xi+l) for each i = 0,..,n-1
# i.e., the values at the knots are "doubled up"
h[i] = xn[i+1]-xn[i]
for i in range(1, n-1):
# Sets up the linear system and allows us to find c. Once we have
# c then b and d follow in terms of it.
alpha[i] = (3./h[i])*(a[i+1]-a[i])-(3./h[i-1])*(a[i] - a[i-1])
# I, II, (part of) III Sets up and solves tridiagonal linear system...
# I
l[0] = 1
u[0] = 0
z[0] = 0
# II
for i in range(1, n-1):
l[i] = 2*(xn[i+1] - xn[i-1]) - h[i-1]*u[i-1]
u[i] = h[i]/l[i]
z[i] = (alpha[i] - h[i-1]*z[i-1])/l[i]
l[n] = 1
z[n] = 0
c[n] = 0
# III... also find b, d in terms of c.
for j in range(n-2, -1, -1):
c[j] = z[j] - u[j]*c[j+1]
b[j] = (a[j+1] - a[j])/h[j] - h[j]*(c[j+1] + 2*c[j])/3.
d[j] = (c[j+1] - c[j])/(3*h[j])
# Now that we have the coefficients it's just a matter of constructing
# the appropriate polynomials and graphing.
for j in range(n-1):
cub_graph(a[j],b[j],c[j],d[j],xn[j],xn[j+1])
plt.show()
def cub_graph(a,b,c,d, x_i, x_i_1):
"""cub_graph takes the i'th coefficient set along with the x[i] and x[i+1]'th
data pts, and constructs the polynomial spline between the two data pts using
the poly1d python object (which simply returns a polynomial with a given root."""
# notice here that we are just building the cubic polynomial piece by piece
root = poly1d(x_i,True)
poly = 0
poly = d*(root)**3
poly = poly + c*(root)**2
poly = poly + b*root
poly = poly + a
# Set up our domain between data points, and plot the function
pts = arange(x_i,x_i_1, 0.001)
plt.plot(pts, poly(pts), '-')
return
</code></pre>
<p>如果您想测试它,这里有一些数据可以用来开始,这些数据来自
函数1.6e^(-2x)sin(3*pi*x)介于0和1之间:</p>
<pre><code># These are our data points
x_vals = [0, 1./6, 1./3, 1./2, 7./12, 2./3, 3./4, 5./6, 11./12, 1]
# Set up the domain
x_domain = arange(0,2, 1e-2)
fx = zeroV(10)
# Defines the function so we can get our fx values
def sine_func(x):
return(1.6*e**(-2*x)*sin(3*pi*x))
for i in range(len(x_vals)):
fx[i] = sine_func(x_vals[i])
# Run cubic_spline interpolant.
cubic_spline(10,x_vals,fx)
</code></pre>