Time_Series_Course/holtswinter.py at master · prakashjayy/Time_Series_Course · GitHub

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
"""https://gist.github.com/andrequeiroz/5888967
"""
from __future__ import division
from sys import exit
from math import sqrt
from numpy import array
from scipy.optimize import fmin_l_bfgs_b

def RMSE(params, *args):

	Y = args[0]
	type = args[1]
	rmse = 0

	if type == 'linear':

		alpha, beta = params
		a = [Y[0]]
		b = [Y[1] - Y[0]]
		y = [a[0] + b[0]]

		for i in range(len(Y)):

			a.append(alpha * Y[i] + (1 - alpha) * (a[i] + b[i]))
			b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
			y.append(a[i + 1] + b[i + 1])

	else:

		alpha, beta, gamma = params
		m = args[2]
		a = [sum(Y[0:m]) / float(m)]
		b = [(sum(Y[m:2 * m]) - sum(Y[0:m])) / m ** 2]

		if type == 'additive':

			s = [Y[i] - a[0] for i in range(m)]
			y = [a[0] + b[0] + s[0]]

			for i in range(len(Y)):

				a.append(alpha * (Y[i] - s[i]) + (1 - alpha) * (a[i] + b[i]))
				b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
				s.append(gamma * (Y[i] - a[i] - b[i]) + (1 - gamma) * s[i])
				y.append(a[i + 1] + b[i + 1] + s[i + 1])

		elif type == 'multiplicative':

			s = [Y[i] / a[0] for i in range(m)]
			y = [(a[0] + b[0]) * s[0]]

			for i in range(len(Y)):

				a.append(alpha * (Y[i] / s[i]) + (1 - alpha) * (a[i] + b[i]))
				b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
				s.append(gamma * (Y[i] / (a[i] + b[i])) + (1 - gamma) * s[i])
				y.append((a[i + 1] + b[i + 1]) * s[i + 1])

		else:

			exit('Type must be either linear, additive or multiplicative')

	rmse = sqrt(sum([(m - n) ** 2 for m, n in zip(Y, y[:-1])]) / len(Y))

	return rmse

def linear(x, fc, alpha = None, beta = None):

	Y = x[:]

	if (alpha == None or beta == None):

		initial_values = array([0.3, 0.1])
		boundaries = [(0, 1), (0, 1)]
		type = 'linear'

		parameters = fmin_l_bfgs_b(RMSE, x0 = initial_values, args = (Y, type), bounds = boundaries, approx_grad = True)
		alpha, beta = parameters[0]

	a = [Y[0]]
	b = [Y[1] - Y[0]]
	y = [a[0] + b[0]]
	rmse = 0

	for i in range(len(Y) + fc):

		if i == len(Y):
			Y.append(a[-1] + b[-1])

		a.append(alpha * Y[i] + (1 - alpha) * (a[i] + b[i]))
		b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
		y.append(a[i + 1] + b[i + 1])

	rmse = sqrt(sum([(m - n) ** 2 for m, n in zip(Y[:-fc], y[:-fc - 1])]) / len(Y[:-fc]))

	return Y[-fc:], alpha, beta, rmse

def additive(x, m, fc, alpha = None, beta = None, gamma = None):

	Y = x[:]

	if (alpha == None or beta == None or gamma == None):

		initial_values = array([0.3, 0.1, 0.1])
		boundaries = [(0, 1), (0, 1), (0, 1)]
		type = 'additive'

		parameters = fmin_l_bfgs_b(RMSE, x0 = initial_values, args = (Y, type, m), bounds = boundaries, approx_grad = True)
		alpha, beta, gamma = parameters[0]

	a = [sum(Y[0:m]) / float(m)]
	b = [(sum(Y[m:2 * m]) - sum(Y[0:m])) / m ** 2]
	s = [Y[i] - a[0] for i in range(m)]
	y = [a[0] + b[0] + s[0]]
	rmse = 0

	for i in range(len(Y) + fc):

		if i == len(Y):
			Y.append(a[-1] + b[-1] + s[-m])

		a.append(alpha * (Y[i] - s[i]) + (1 - alpha) * (a[i] + b[i]))
		b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
		s.append(gamma * (Y[i] - a[i] - b[i]) + (1 - gamma) * s[i])
		y.append(a[i + 1] + b[i + 1] + s[i + 1])

	rmse = sqrt(sum([(m - n) ** 2 for m, n in zip(Y[:-fc], y[:-fc - 1])]) / len(Y[:-fc]))

	return Y[-fc:], alpha, beta, gamma, rmse

def multiplicative(x, m, fc, alpha = None, beta = None, gamma = None):

	Y = x[:]

	if (alpha == None or beta == None or gamma == None):

		initial_values = array([0.0, 1.0, 0.0])
		boundaries = [(0, 1), (0, 1), (0, 1)]
		type = 'multiplicative'

		parameters = fmin_l_bfgs_b(RMSE, x0 = initial_values, args = (Y, type, m), bounds = boundaries, approx_grad = True)
		alpha, beta, gamma = parameters[0]

	a = [sum(Y[0:m]) / float(m)]
	b = [(sum(Y[m:2 * m]) - sum(Y[0:m])) / m ** 2]
	s = [Y[i] / a[0] for i in range(m)]
	y = [(a[0] + b[0]) * s[0]]
	rmse = 0

	for i in range(len(Y) + fc):

		if i == len(Y):
			Y.append((a[-1] + b[-1]) * s[-m])

		a.append(alpha * (Y[i] / s[i]) + (1 - alpha) * (a[i] + b[i]))
		b.append(beta * (a[i + 1] - a[i]) + (1 - beta) * b[i])
		s.append(gamma * (Y[i] / (a[i] + b[i])) + (1 - gamma) * s[i])
		y.append((a[i + 1] + b[i + 1]) * s[i + 1])

	rmse = sqrt(sum([(m - n) ** 2 for m, n in zip(Y[:-fc], y[:-fc - 1])]) / len(Y[:-fc]))

	return Y[-fc:], alpha, beta, gamma, rmse