import warnings import numpy as np from . import distributions from .._lib._bunch import _make_tuple_bunch from ._stats_pythran import siegelslopes as siegelslopes_pythran from . import _mstats_basic __all__ = ['_find_repeats', 'linregress', 'theilslopes', 'siegelslopes'] # This is not a namedtuple for backwards compatibility. See PR #12983 LinregressResult = _make_tuple_bunch('LinregressResult', ['slope', 'intercept', 'rvalue', 'pvalue', 'stderr'], extra_field_names=['intercept_stderr']) TheilslopesResult = _make_tuple_bunch('TheilslopesResult', ['slope', 'intercept', 'low_slope', 'high_slope']) SiegelslopesResult = _make_tuple_bunch('SiegelslopesResult', ['slope', 'intercept']) def linregress(x, y=None, alternative='two-sided'): """ Calculate a linear least-squares regression for two sets of measurements. Parameters ---------- x, y : array_like Two sets of measurements. Both arrays should have the same length. If only `x` is given (and ``y=None``), then it must be a two-dimensional array where one dimension has length 2. The two sets of measurements are then found by splitting the array along the length-2 dimension. In the case where ``y=None`` and `x` is a 2x2 array, ``linregress(x)`` is equivalent to ``linregress(x[0], x[1])``. alternative : {'two-sided', 'less', 'greater'}, optional Defines the alternative hypothesis. Default is 'two-sided'. The following options are available: * 'two-sided': the slope of the regression line is nonzero * 'less': the slope of the regression line is less than zero * 'greater': the slope of the regression line is greater than zero .. versionadded:: 1.7.0 Returns ------- result : ``LinregressResult`` instance The return value is an object with the following attributes: slope : float Slope of the regression line. intercept : float Intercept of the regression line. rvalue : float The Pearson correlation coefficient. The square of ``rvalue`` is equal to the coefficient of determination. pvalue : float The p-value for a hypothesis test whose null hypothesis is that the slope is zero, using Wald Test with t-distribution of the test statistic. See `alternative` above for alternative hypotheses. stderr : float Standard error of the estimated slope (gradient), under the assumption of residual normality. intercept_stderr : float Standard error of the estimated intercept, under the assumption of residual normality. See Also -------- scipy.optimize.curve_fit : Use non-linear least squares to fit a function to data. scipy.optimize.leastsq : Minimize the sum of squares of a set of equations. Notes ----- Missing values are considered pair-wise: if a value is missing in `x`, the corresponding value in `y` is masked. For compatibility with older versions of SciPy, the return value acts like a ``namedtuple`` of length 5, with fields ``slope``, ``intercept``, ``rvalue``, ``pvalue`` and ``stderr``, so one can continue to write:: slope, intercept, r, p, se = linregress(x, y) With that style, however, the standard error of the intercept is not available. To have access to all the computed values, including the standard error of the intercept, use the return value as an object with attributes, e.g.:: result = linregress(x, y) print(result.intercept, result.intercept_stderr) Examples -------- >>> import numpy as np >>> import matplotlib.pyplot as plt >>> from scipy import stats >>> rng = np.random.default_rng() Generate some data: >>> x = rng.random(10) >>> y = 1.6*x + rng.random(10) Perform the linear regression: >>> res = stats.linregress(x, y) Coefficient of determination (R-squared): >>> print(f"R-squared: {res.rvalue**2:.6f}") R-squared: 0.717533 Plot the data along with the fitted line: >>> plt.plot(x, y, 'o', label='original data') >>> plt.plot(x, res.intercept + res.slope*x, 'r', label='fitted line') >>> plt.legend() >>> plt.show() Calculate 95% confidence interval on slope and intercept: >>> # Two-sided inverse Students t-distribution >>> # p - probability, df - degrees of freedom >>> from scipy.stats import t >>> tinv = lambda p, df: abs(t.ppf(p/2, df)) >>> ts = tinv(0.05, len(x)-2) >>> print(f"slope (95%): {res.slope:.6f} +/- {ts*res.stderr:.6f}") slope (95%): 1.453392 +/- 0.743465 >>> print(f"intercept (95%): {res.intercept:.6f}" ... f" +/- {ts*res.intercept_stderr:.6f}") intercept (95%): 0.616950 +/- 0.544475 """ TINY = 1.0e-20 if y is None: # x is a (2, N) or (N, 2) shaped array_like x = np.asarray(x) if x.shape[0] == 2: x, y = x elif x.shape[1] == 2: x, y = x.T else: raise ValueError("If only `x` is given as input, it has to " "be of shape (2, N) or (N, 2); provided shape " f"was {x.shape}.") else: x = np.asarray(x) y = np.asarray(y) if x.size == 0 or y.size == 0: raise ValueError("Inputs must not be empty.") if np.amax(x) == np.amin(x) and len(x) > 1: raise ValueError("Cannot calculate a linear regression " "if all x values are identical") n = len(x) xmean = np.mean(x, None) ymean = np.mean(y, None) # Average sums of square differences from the mean # ssxm = mean( (x-mean(x))^2 ) # ssxym = mean( (x-mean(x)) * (y-mean(y)) ) ssxm, ssxym, _, ssym = np.cov(x, y, bias=1).flat # R-value # r = ssxym / sqrt( ssxm * ssym ) if ssxm == 0.0 or ssym == 0.0: # If the denominator was going to be 0 r = 0.0 else: r = ssxym / np.sqrt(ssxm * ssym) # Test for numerical error propagation (make sure -1 < r < 1) if r > 1.0: r = 1.0 elif r < -1.0: r = -1.0 slope = ssxym / ssxm intercept = ymean - slope*xmean if n == 2: # handle case when only two points are passed in if y[0] == y[1]: prob = 1.0 else: prob = 0.0 slope_stderr = 0.0 intercept_stderr = 0.0 else: df = n - 2 # Number of degrees of freedom # n-2 degrees of freedom because 2 has been used up # to estimate the mean and standard deviation t = r * np.sqrt(df / ((1.0 - r + TINY)*(1.0 + r + TINY))) t, prob = _mstats_basic._ttest_finish(df, t, alternative) slope_stderr = np.sqrt((1 - r**2) * ssym / ssxm / df) # Also calculate the standard error of the intercept # The following relationship is used: # ssxm = mean( (x-mean(x))^2 ) # = ssx - sx*sx # = mean( x^2 ) - mean(x)^2 intercept_stderr = slope_stderr * np.sqrt(ssxm + xmean**2) return LinregressResult(slope=slope, intercept=intercept, rvalue=r, pvalue=prob, stderr=slope_stderr, intercept_stderr=intercept_stderr) def theilslopes(y, x=None, alpha=0.95, method='separate'): r""" Computes the Theil-Sen estimator for a set of points (x, y). `theilslopes` implements a method for robust linear regression. It computes the slope as the median of all slopes between paired values. Parameters ---------- y : array_like Dependent variable. x : array_like or None, optional Independent variable. If None, use ``arange(len(y))`` instead. alpha : float, optional Confidence degree between 0 and 1. Default is 95% confidence. Note that `alpha` is symmetric around 0.5, i.e. both 0.1 and 0.9 are interpreted as "find the 90% confidence interval". method : {'joint', 'separate'}, optional Method to be used for computing estimate for intercept. Following methods are supported, * 'joint': Uses np.median(y - slope * x) as intercept. * 'separate': Uses np.median(y) - slope * np.median(x) as intercept. The default is 'separate'. .. versionadded:: 1.8.0 Returns ------- result : ``TheilslopesResult`` instance The return value is an object with the following attributes: slope : float Theil slope. intercept : float Intercept of the Theil line. low_slope : float Lower bound of the confidence interval on `slope`. high_slope : float Upper bound of the confidence interval on `slope`. See Also -------- siegelslopes : a similar technique using repeated medians Notes ----- The implementation of `theilslopes` follows [1]_. The intercept is not defined in [1]_, and here it is defined as ``median(y) - slope*median(x)``, which is given in [3]_. Other definitions of the intercept exist in the literature such as ``median(y - slope*x)`` in [4]_. The approach to compute the intercept can be determined by the parameter ``method``. A confidence interval for the intercept is not given as this question is not addressed in [1]_. For compatibility with older versions of SciPy, the return value acts like a ``namedtuple`` of length 4, with fields ``slope``, ``intercept``, ``low_slope``, and ``high_slope``, so one can continue to write:: slope, intercept, low_slope, high_slope = theilslopes(y, x) References ---------- .. [1] P.K. Sen, "Estimates of the regression coefficient based on Kendall's tau", J. Am. Stat. Assoc., Vol. 63, pp. 1379-1389, 1968. .. [2] H. Theil, "A rank-invariant method of linear and polynomial regression analysis I, II and III", Nederl. Akad. Wetensch., Proc. 53:, pp. 386-392, pp. 521-525, pp. 1397-1412, 1950. .. [3] W.L. Conover, "Practical nonparametric statistics", 2nd ed., John Wiley and Sons, New York, pp. 493. .. [4] https://en.wikipedia.org/wiki/Theil%E2%80%93Sen_estimator Examples -------- >>> import numpy as np >>> from scipy import stats >>> import matplotlib.pyplot as plt >>> x = np.linspace(-5, 5, num=150) >>> y = x + np.random.normal(size=x.size) >>> y[11:15] += 10 # add outliers >>> y[-5:] -= 7 Compute the slope, intercept and 90% confidence interval. For comparison, also compute the least-squares fit with `linregress`: >>> res = stats.theilslopes(y, x, 0.90, method='separate') >>> lsq_res = stats.linregress(x, y) Plot the results. The Theil-Sen regression line is shown in red, with the dashed red lines illustrating the confidence interval of the slope (note that the dashed red lines are not the confidence interval of the regression as the confidence interval of the intercept is not included). The green line shows the least-squares fit for comparison. >>> fig = plt.figure() >>> ax = fig.add_subplot(111) >>> ax.plot(x, y, 'b.') >>> ax.plot(x, res[1] + res[0] * x, 'r-') >>> ax.plot(x, res[1] + res[2] * x, 'r--') >>> ax.plot(x, res[1] + res[3] * x, 'r--') >>> ax.plot(x, lsq_res[1] + lsq_res[0] * x, 'g-') >>> plt.show() """ if method not in ['joint', 'separate']: raise ValueError("method must be either 'joint' or 'separate'." f"'{method}' is invalid.") # We copy both x and y so we can use _find_repeats. y = np.array(y, dtype=float, copy=True).ravel() if x is None: x = np.arange(len(y), dtype=float) else: x = np.array(x, dtype=float, copy=True).ravel() if len(x) != len(y): raise ValueError(f"Incompatible lengths ! ({len(y)}<>{len(x)})") # Compute sorted slopes only when deltax > 0 deltax = x[:, np.newaxis] - x deltay = y[:, np.newaxis] - y slopes = deltay[deltax > 0] / deltax[deltax > 0] if not slopes.size: msg = "All `x` coordinates are identical." warnings.warn(msg, RuntimeWarning, stacklevel=2) slopes.sort() medslope = np.median(slopes) if method == 'joint': medinter = np.median(y - medslope * x) else: medinter = np.median(y) - medslope * np.median(x) # Now compute confidence intervals if alpha > 0.5: alpha = 1. - alpha z = distributions.norm.ppf(alpha / 2.) # This implements (2.6) from Sen (1968) _, nxreps = _find_repeats(x) _, nyreps = _find_repeats(y) nt = len(slopes) # N in Sen (1968) ny = len(y) # n in Sen (1968) # Equation 2.6 in Sen (1968): sigsq = 1/18. * (ny * (ny-1) * (2*ny+5) - sum(k * (k-1) * (2*k + 5) for k in nxreps) - sum(k * (k-1) * (2*k + 5) for k in nyreps)) # Find the confidence interval indices in `slopes` try: sigma = np.sqrt(sigsq) Ru = min(int(np.round((nt - z*sigma)/2.)), len(slopes)-1) Rl = max(int(np.round((nt + z*sigma)/2.)) - 1, 0) delta = slopes[[Rl, Ru]] except (ValueError, IndexError): delta = (np.nan, np.nan) return TheilslopesResult(slope=medslope, intercept=medinter, low_slope=delta[0], high_slope=delta[1]) def _find_repeats(arr): # This function assumes it may clobber its input. if len(arr) == 0: return np.array(0, np.float64), np.array(0, np.intp) # XXX This cast was previously needed for the Fortran implementation, # should we ditch it? arr = np.asarray(arr, np.float64).ravel() arr.sort() # Taken from NumPy 1.9's np.unique. change = np.concatenate(([True], arr[1:] != arr[:-1])) unique = arr[change] change_idx = np.concatenate(np.nonzero(change) + ([arr.size],)) freq = np.diff(change_idx) atleast2 = freq > 1 return unique[atleast2], freq[atleast2] def siegelslopes(y, x=None, method="hierarchical"): r""" Computes the Siegel estimator for a set of points (x, y). `siegelslopes` implements a method for robust linear regression using repeated medians (see [1]_) to fit a line to the points (x, y). The method is robust to outliers with an asymptotic breakdown point of 50%. Parameters ---------- y : array_like Dependent variable. x : array_like or None, optional Independent variable. If None, use ``arange(len(y))`` instead. method : {'hierarchical', 'separate'} If 'hierarchical', estimate the intercept using the estimated slope ``slope`` (default option). If 'separate', estimate the intercept independent of the estimated slope. See Notes for details. Returns ------- result : ``SiegelslopesResult`` instance The return value is an object with the following attributes: slope : float Estimate of the slope of the regression line. intercept : float Estimate of the intercept of the regression line. See Also -------- theilslopes : a similar technique without repeated medians Notes ----- With ``n = len(y)``, compute ``m_j`` as the median of the slopes from the point ``(x[j], y[j])`` to all other `n-1` points. ``slope`` is then the median of all slopes ``m_j``. Two ways are given to estimate the intercept in [1]_ which can be chosen via the parameter ``method``. The hierarchical approach uses the estimated slope ``slope`` and computes ``intercept`` as the median of ``y - slope*x``. The other approach estimates the intercept separately as follows: for each point ``(x[j], y[j])``, compute the intercepts of all the `n-1` lines through the remaining points and take the median ``i_j``. ``intercept`` is the median of the ``i_j``. The implementation computes `n` times the median of a vector of size `n` which can be slow for large vectors. There are more efficient algorithms (see [2]_) which are not implemented here. For compatibility with older versions of SciPy, the return value acts like a ``namedtuple`` of length 2, with fields ``slope`` and ``intercept``, so one can continue to write:: slope, intercept = siegelslopes(y, x) References ---------- .. [1] A. Siegel, "Robust Regression Using Repeated Medians", Biometrika, Vol. 69, pp. 242-244, 1982. .. [2] A. Stein and M. Werman, "Finding the repeated median regression line", Proceedings of the Third Annual ACM-SIAM Symposium on Discrete Algorithms, pp. 409-413, 1992. Examples -------- >>> import numpy as np >>> from scipy import stats >>> import matplotlib.pyplot as plt >>> x = np.linspace(-5, 5, num=150) >>> y = x + np.random.normal(size=x.size) >>> y[11:15] += 10 # add outliers >>> y[-5:] -= 7 Compute the slope and intercept. For comparison, also compute the least-squares fit with `linregress`: >>> res = stats.siegelslopes(y, x) >>> lsq_res = stats.linregress(x, y) Plot the results. The Siegel regression line is shown in red. The green line shows the least-squares fit for comparison. >>> fig = plt.figure() >>> ax = fig.add_subplot(111) >>> ax.plot(x, y, 'b.') >>> ax.plot(x, res[1] + res[0] * x, 'r-') >>> ax.plot(x, lsq_res[1] + lsq_res[0] * x, 'g-') >>> plt.show() """ if method not in ['hierarchical', 'separate']: raise ValueError("method can only be 'hierarchical' or 'separate'") y = np.asarray(y).ravel() if x is None: x = np.arange(len(y), dtype=float) else: x = np.asarray(x, dtype=float).ravel() if len(x) != len(y): raise ValueError(f"Incompatible lengths ! ({len(y)}<>{len(x)})") dtype = np.result_type(x, y, np.float32) # use at least float32 y, x = y.astype(dtype), x.astype(dtype) medslope, medinter = siegelslopes_pythran(y, x, method) return SiegelslopesResult(slope=medslope, intercept=medinter)