""" Collection of Model instances for use with the odrpack fitting package. """ from __future__ import division, print_function, absolute_import import numpy as np from scipy.odr.odrpack import Model __all__ = ['Model', 'exponential', 'multilinear', 'unilinear', 'quadratic', 'polynomial'] def _lin_fcn(B, x): a, b = B[0], B[1:] b.shape = (b.shape[0], 1) return a + (x*b).sum(axis=0) def _lin_fjb(B, x): a = np.ones(x.shape[-1], float) res = np.concatenate((a, x.ravel())) res.shape = (B.shape[-1], x.shape[-1]) return res def _lin_fjd(B, x): b = B[1:] b = np.repeat(b, (x.shape[-1],)*b.shape[-1],axis=0) b.shape = x.shape return b def _lin_est(data): # Eh. The answer is analytical, so just return all ones. # Don't return zeros since that will interfere with # ODRPACK's auto-scaling procedures. if len(data.x.shape) == 2: m = data.x.shape[0] else: m = 1 return np.ones((m + 1,), float) def _poly_fcn(B, x, powers): a, b = B[0], B[1:] b.shape = (b.shape[0], 1) return a + np.sum(b * np.power(x, powers), axis=0) def _poly_fjacb(B, x, powers): res = np.concatenate((np.ones(x.shape[-1], float), np.power(x, powers).flat)) res.shape = (B.shape[-1], x.shape[-1]) return res def _poly_fjacd(B, x, powers): b = B[1:] b.shape = (b.shape[0], 1) b = b * powers return np.sum(b * np.power(x, powers-1),axis=0) def _exp_fcn(B, x): return B[0] + np.exp(B[1] * x) def _exp_fjd(B, x): return B[1] * np.exp(B[1] * x) def _exp_fjb(B, x): res = np.concatenate((np.ones(x.shape[-1], float), x * np.exp(B[1] * x))) res.shape = (2, x.shape[-1]) return res def _exp_est(data): # Eh. return np.array([1., 1.]) multilinear = Model(_lin_fcn, fjacb=_lin_fjb, fjacd=_lin_fjd, estimate=_lin_est, meta={'name': 'Arbitrary-dimensional Linear', 'equ':'y = B_0 + Sum[i=1..m, B_i * x_i]', 'TeXequ':'$y=\\beta_0 + \sum_{i=1}^m \\beta_i x_i$'}) def polynomial(order): """ Factory function for a general polynomial model. Parameters ---------- order : int or sequence If an integer, it becomes the order of the polynomial to fit. If a sequence of numbers, then these are the explicit powers in the polynomial. A constant term (power 0) is always included, so don't include 0. Thus, polynomial(n) is equivalent to polynomial(range(1, n+1)). Returns ------- polynomial : Model instance Model instance. """ powers = np.asarray(order) if powers.shape == (): # Scalar. powers = np.arange(1, powers + 1) powers.shape = (len(powers), 1) len_beta = len(powers) + 1 def _poly_est(data, len_beta=len_beta): # Eh. Ignore data and return all ones. return np.ones((len_beta,), float) return Model(_poly_fcn, fjacd=_poly_fjacd, fjacb=_poly_fjacb, estimate=_poly_est, extra_args=(powers,), meta={'name': 'Sorta-general Polynomial', 'equ':'y = B_0 + Sum[i=1..%s, B_i * (x**i)]' % (len_beta-1), 'TeXequ':'$y=\\beta_0 + \sum_{i=1}^{%s} \\beta_i x^i$' % (len_beta-1)}) exponential = Model(_exp_fcn, fjacd=_exp_fjd, fjacb=_exp_fjb, estimate=_exp_est, meta={'name':'Exponential', 'equ':'y= B_0 + exp(B_1 * x)', 'TeXequ':'$y=\\beta_0 + e^{\\beta_1 x}$'}) def _unilin(B, x): return x*B[0] + B[1] def _unilin_fjd(B, x): return np.ones(x.shape, float) * B[0] def _unilin_fjb(B, x): _ret = np.concatenate((x, np.ones(x.shape, float))) _ret.shape = (2,) + x.shape return _ret def _unilin_est(data): return (1., 1.) def _quadratic(B, x): return x*(x*B[0] + B[1]) + B[2] def _quad_fjd(B, x): return 2*x*B[0] + B[1] def _quad_fjb(B, x): _ret = np.concatenate((x*x, x, np.ones(x.shape, float))) _ret.shape = (3,) + x.shape return _ret def _quad_est(data): return (1.,1.,1.) unilinear = Model(_unilin, fjacd=_unilin_fjd, fjacb=_unilin_fjb, estimate=_unilin_est, meta={'name': 'Univariate Linear', 'equ': 'y = B_0 * x + B_1', 'TeXequ': '$y = \\beta_0 x + \\beta_1$'}) quadratic = Model(_quadratic, fjacd=_quad_fjd, fjacb=_quad_fjb, estimate=_quad_est, meta={'name': 'Quadratic', 'equ': 'y = B_0*x**2 + B_1*x + B_2', 'TeXequ': '$y = \\beta_0 x^2 + \\beta_1 x + \\beta_2'})