# Piecewise regresion Python

Hi I'm trying to figure out how to fit those values with a piecewise linear function. I have read this question but I can't get forward (How to apply piecewise linear fit in Python? ). In this example is show how to implement a piecewise function for a 2 segment case. But I need to do it in a three segment case as in figure.

I'have written this code:

``````from scipy import optimize
import matplotlib.pyplot as plt
import numpy as np

x1 = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10 ,11, 12, 13, 14, 15,16,17,18,19,20,21], dtype=float)
y1 = np.array([5, 7, 9, 11, 13, 15, 28.92, 42.81, 56.7, 70.59, 84.47, 98.36, 112.25, 126.14, 140.03,145,147,149,151,153,155])

x = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10 ,11, 12, 13, 14, 15], dtype=float)
y = np.array([5, 7, 9, 11, 13, 15, 28.92, 42.81, 56.7, 70.59, 84.47, 98.36, 112.25, 126.14, 140.03])

def piecewise(x,x0,x1,y0,y1,k0,k1,k2):
return np.piecewise(x , [x <= x0, (x>= x1)] , [lambda x:k0*x + y0-k0*x0, lambda x:k1*(x-(x1+x0))-y1, lambda x:k2*x + y1-k2*x1])

p , e = optimize.curve_fit(piecewise_linear, x1, y1)
xd = np.linspace(0, 15, 100)
plt.figure()
plt.plot(x1, y1, "o")
plt.plot(xd, piecewise_linear(xd, *p))
``````

but this is the output

Any suggestion? I belive that the problem is in `return np.piecewise(x , [x <= x0, (x>= x1)] , [lambda x:k0*x + y0-k0*x0, lambda x:k1*(x-(x1+x0))-y1, lambda x:k2*x + y1-k2*x1])` in particular in the second `lambda`.

EDIT 1:

If I try to different data the solution provided by A.L. I don't get good results.

I get this result:

with

``````x=[ 16.01690476,  16.13801587,  14.63628571,  15.32664399,
15.8145    ,  15.71507143,  15.56107143,  15.553     ,
15.08734524,  14.97275   ,  15.51958333,  16.61981859,
16.36589286,  14.78708333,  14.41565476,  13.47763158,
13.42412281,  12.95551378,  13.66601504,  13.63315789,
13.21463659,  13.53464286,  14.60130952,  14.7774881 ,
13.04319048,  12.53385965,  12.65745614,  13.90535714,
14.82412281,  14.6565    ,  15.09541667,  13.41434524,
13.66033333,  14.57964286,  13.55416667,  13.43041667,
13.01137566,  12.76429825,  11.55241667,  11.0634881 ,
10.92729762,  11.21625   ,  10.72092857,  11.80380952,
12.55233333,  12.11307143,  11.78892857,  12.45458333,
11.05539286,  10.69214286,  10.32566667,  11.3439881 ,
9.69563492,  10.72535714,  10.26180272,   7.77272727,
6.37704082,   8.49666667,   8.5389881 ,   5.68547619,
7.00616667,   8.22015873,  10.20315476,  15.35736842,
12.25158333,  11.09622153,  10.4118254 ,   9.8602381 ,
10.16727273,  15.10858333,  13.82215539,  12.44719298,
10.92341667,  11.44565476,  11.43333333,  10.5045    ,
11.14357143,  10.37625   ,   8.93421769,   9.48444444,
10.43483333,  10.8659881 ,  10.96166667,  10.12872619,
9.64663265,   9.29979762,   9.67173469,   8.978322  ,
9.10419501,   9.45411565,  10.46411565,   7.95739229,
8.72616667,   7.03892857,   7.32547619,   7.56441667,
6.61022676,   9.09014739,  10.78141667,  10.85918367,
11.11665476,  10.141     ,   9.17760771,   8.27968254,
11.02625   ,  12.34809524,  11.17807018,  11.25416667,
11.29236905,   9.28357143,   9.77033333,  11.52086168,
9.8625    ,  12.60281955,  12.42785714,  12.11902256,
13.1       ,  13.02791667,  13.87779449,  15.09857143,
13.93935185,  13.69821429,  13.39880952,  12.45692982,
12.76921053,  13.23708333,  13.71666667,  15.39807143,
15.27916667,  14.66464286,  13.38694444,  10.97555556,
10.02191667,  11.99608333,  14.26325   ,  15.40991667,
15.12908333,  15.76265476,  12.12763158,  15.01641667,
14.39602381,  12.98532143,  14.98807018,  18.30547619,
16.7564966 ,  16.82982143,  19.8487013 ,  19.18600907]
``````

and

``````y=[ 2.36846863,  2.73722628,  2.77177583,  2.63930636,  2.80864749,
2.57066667,  2.65277287,  2.57162347,  2.76295667,  2.79835391,
2.60431154,  2.17326401,  2.67740698,  2.47138153,  2.49882574,
2.60987338,  2.69935565,  2.60755362,  2.77702029,  2.62996942,
2.45959517,  2.52750434,  2.73833005,  2.52009   ,  2.80933226,
1.63807085,  2.49230099,  2.55441614,  3.19256506,  2.52609288,
1.02931596,  2.40266963,  2.3306463 ,  2.69094276,  2.60779985,
2.48351648,  2.45131766,  2.40526763,  2.03952569,  1.86217009,
1.79971848,  1.91772218,  1.85895421,  2.32725731,  2.28189713,
2.11835833,  2.09636517,  2.2230303 ,  1.85863317,  1.77550406,
1.68862391,  1.79187765,  1.70887476,  1.81911193,  1.74802483,
1.65776432,  1.58012849,  1.67781494,  1.62451541,  1.60555884,
1.56172214,  1.60083809,  1.65256994,  2.74794704,  2.27089627,
1.80364982,  1.51412482,  1.77738757,  1.56979564,  2.46538633,
2.37679625,  2.40389294,  2.04165763,  1.82086407,  1.90609219,
1.87480978,  1.8877854 ,  1.76080074,  1.68369028,  1.57419297,
1.66470126,  1.74522552,  1.72459756,  1.65510503,  1.72131148,
1.6254417 ,  1.57091907,  1.68755268,  1.70307911,  1.59445121,
1.74393783,  1.72913779,  1.66883237,  1.59859545,  1.62335831,
1.73378184,  1.62621588,  1.79532164,  1.78289992,  1.79475101,
1.7826266 ,  1.68778918,  1.64484127,  1.62332696,  1.75372393,
1.99038021,  1.87268137,  1.86124502,  1.82435911,  1.62927102,
1.66443723,  1.86743516,  1.62745098,  2.20200312,  2.09641026,
2.26649111,  2.63271605,  2.18050721,  2.57138433,  2.51833359,
2.74684184,  2.57209998,  2.63762019,  2.30027877,  2.28471286,
2.40323668,  2.37103313,  2.16414489,  1.01027109,  2.64181007,
2.45467765,  2.05773672,  1.73624917,  2.05233688,  2.70820669,
2.65594222,  2.67445635,  2.37212985,  2.48221803,  2.77655216,
2.62839879,  2.26481307,  2.58005799,  2.1188172 ,  2.14017268,
2.16459571,  1.95083406,  1.46224418]
``````
• Iam not sure if you should post a new question instead of editing the old one ? – A. L. Feb 16 '16 at 18:34
• Do you know which kind of noise is added to the original function ? – A. L. Feb 16 '16 at 18:34
• I edited my answer according to your edit of the question – A. L. Feb 16 '16 at 22:23

Fitting a piecewise linear function is a nonlinear optimization problem which may have local optimas. The result you see is probably one of the local optimas where your optimization algorithm gets stuck.

One way to solve this problem is to repeat your optimization algorithm with different initial values and take the best fit. I used the mean absolute error (MAE) to compare the different fits against each other.

``````perr = np.sum(np.abs(y1-piecewise(x1, *p)))
``````

I also changed your piecewise funtion because it was a bit confusing for me. But it still a piecewise function as before

Further think you forgot to extend the x and xd array to the value of 21. (thats why the green line ends early).

``````from scipy import optimize
import matplotlib.pyplot as plt
import numpy as np

def piecewise(x,x0,x1,y0,y1,k0,k1,k2):
return np.piecewise(x , [x <= x0, np.logical_and(x0<x, x<= x1),x>x1] , [lambda x:k0*x + y0, lambda x:k1*(x-x0)+y1+k0*x0,
lambda x:k2*(x-x1) + y0+y1+k0*x0+k1*(x1-x0)])

x1 = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10 ,11, 12, 13, 14, 15,16,17,18,19,20,21], dtype=float)
y1 = np.array([5, 7, 9, 11, 13, 15, 28.92, 42.81, 56.7, 70.59, 84.47, 98.36, 112.25, 126.14, 140.03,145,147,149,151,153,155])
x = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10 ,11, 12, 13, 14, 15,16,17,18,19,20,21], dtype=float)
y = np.array([5, 7, 9, 11, 13, 15, 28.92, 42.81, 56.7, 70.59, 84.47, 98.36, 112.25, 126.14, 140.03,145,147,149,151,153,155])

perr_min = np.inf
p_best = None
for n in range(100):
k = np.random.rand(7)*20
p , e = optimize.curve_fit(piecewise, x1, y1,p0=k)
perr = np.sum(np.abs(y1-piecewise(x1, *p)))
if(perr < perr_min):
perr_min = perr
p_best = p

xd = np.linspace(0, 21, 100)
plt.figure()
plt.plot(x1, y1, "o")
y_out = piecewise(xd, *p_best)
plt.plot(xd, y_out)
plt.show()
``````

this gives me:

with p = [ 6.34259491 15.00000023 2.97272604 7.05498314 2.00751828 13.88881542 1.99960597]

Edit1

You edited your question, and this ist the answer to the edited one. Sorry Iam new at stackoverlfow and not sure if I should post another answer instead

In your second dataset you added noise to data. In my opinion there are two kinds of noises. A gaussian one, which places the points close to the underlying piecewise line and outlier noise which places points far away from the original underlying line.

Under the hood the optimization algorithm you use optimizes the following according to p: E = sum(square(y-piecewise(x,p))) http://docs.scipy.org/doc/scipy/reference/generated/scipy.optimize.curve_fit.html#scipy.optimize.curve_fit

The gaussian noise is not very problematic. The optimization you use assumes indirectly this gaussian noise (by minimizing the least square error) and fits the line as good as possible. The real problem comes in with the outliers.

The problem is that outliers are far way from the original function. Even if the optimization tries the optimal parameters, the Energy function E will be not minimal, as your outliers are far away from the original function and this distance is even squared so it shifts away the minimum of the Function E far away from the true parameters of your function.

So whats the solution ? Get rid of the outliers.

An automized approach to to that is ransac https://en.wikipedia.org/wiki/RANSAC.

In Brief: You choose a random subset of the original data. You hope the subset has not outliers. You fit your function to the subset and discard the points, which are far way from the fitted function. If enough points survived this step, you take all the surviving points and repeat the fit. The error on this "inlier" set is a measure of the quality of your fit. Then you repeat the whole process and take the best final fit.

I ajusted my script accordingly:

``````from scipy import optimize
import matplotlib.pyplot as plt
import numpy as np
def piecewise(x,x0,x1,y0,y1,k0,k1,k2):
return np.piecewise(x , [x <= x0, np.logical_and(x0<x, x<= x1),x>x1] , [lambda x:k0*x + y0, lambda x:k1*(x-x0)+y1+k0*x0,
lambda x:k2*(x-x1) + y0+y1+k0*x0+k1*(x1-x0)])

x = np.array(x)
y = np.array(y)

x1 = x
y1 = y

perr_min = np.inf
p_best = None
for n in range(100):
idx = np.random.choice(np.arange(len(x)), 10, replace=False)
x_sample = x[idx]
y_sample = y[idx]
k = np.random.rand(7)*20
try:
p , e = optimize.curve_fit(piecewise, x_sample,y_sample ,p0=k)
each_error = np.abs(y-piecewise(x, *p))
x_inliner = x[each_error < 1]
y_inlier = y[each_error < 1]
if(x_inliner.shape[0] < 0.8 * x.shape[0]):
continue

p_inlier , e_inlier = optimize.curve_fit(piecewise, x_inliner,y_inlier ,p0=p)
perr = np.sum(np.abs(y-piecewise(x, *p_inlier)))

if(perr < perr_min):
perr_min = perr
p_best = p_inlier
except RuntimeError:
pass

xd = np.linspace(0, 21, 100)
plt.figure()
plt.plot(x, y, "o")
y_out = piecewise(xd, *p_best)
plt.plot(xd, y_out)
print p_best
plt.show()
``````

With 100 repetitions I get the following result:

• Check my Edit. Tnx – Lorenzo Bottaccioli Feb 16 '16 at 12:13
• Does this answer your question ? – A. L. Feb 19 '16 at 18:51
• Not realy, the one that you have found is not the best fitting possible. But tnx any way for the help! – Lorenzo Bottaccioli Feb 23 '16 at 15:58