def interpolate2d(x, y, z, points, mode='linear', bounds_error=False): """Fundamental 2D interpolation routine :param x: 1D array of x-coordinates of the mesh on which to interpolate :type x: numpy.ndarray :param y: 1D array of y-coordinates of the mesh on which to interpolate :type y: numpy.ndarray :param z: 2D array of values for each x, y pair :type z: numpy.ndarry :param points: Nx2 array of coordinates where interpolated values are sought :type points: numpy.narray :param mode: Determines the interpolation order. Options are: * 'constant' - piecewise constant nearest neighbour interpolation * 'linear' - bilinear interpolation using the four nearest neighbours (default) :type mode: str :param bounds_error: If True (default) a BoundsError exception will be raised when interpolated values are requested outside the domain of the input data. If False, nan is returned for those values :type bounds_error: bool :returns: 1D array with same length as points with interpolated values :raises: Exception, BoundsError (see note about bounds_error) ..notes:: Input coordinates x and y are assumed to be monotonically increasing, but need not be equidistantly spaced. No such assumption regarding ordering of points is made. z is assumed to have dimension M x N, where M = len(x) and N = len(y). In other words it is assumed that the x values follow the first (vertical) axis downwards and y values the second (horizontal) axis from left to right. If this routine is to be used for interpolation of raster grids where data is typically organised with longitudes (x) going from left to right and latitudes (y) from left to right then user interpolate_raster in this module """ # Input checks validate_mode(mode) x, y, z, xi, eta = validate_inputs( x=x, y=y, z=z, points=points, bounds_error=bounds_error) # Identify elements that are outside interpolation domain or NaN outside = (xi < x[0]) + (eta < y[0]) + (xi > x[-1]) + (eta > y[-1]) outside += numpy.isnan(xi) + numpy.isnan(eta) inside = -outside xi = xi[inside] eta = eta[inside] # Find upper neighbours for each interpolation point idx = numpy.searchsorted(x, xi, side='left') idy = numpy.searchsorted(y, eta, side='left') # Internal check (index == 0 is OK) if len(idx) > 0 or len(idy) > 0: if (max(idx) >= len(x)) or (max(idy) >= len(y)): msg = ( 'Interpolation point outside domain. ' 'This should never happen. ' 'Please email [email protected]') raise InaSAFEError(msg) # Get the four neighbours for each interpolation point x0 = x[idx - 1] x1 = x[idx] y0 = y[idy - 1] y1 = y[idy] z00 = z[idx - 1, idy - 1] z01 = z[idx - 1, idy] z10 = z[idx, idy - 1] z11 = z[idx, idy] # Coefficients for weighting between lower and upper bounds old_set = numpy.seterr(invalid='ignore') # Suppress warnings alpha = (xi - x0) / (x1 - x0) beta = (eta - y0) / (y1 - y0) numpy.seterr(**old_set) # Restore if mode == 'linear': # Bilinear interpolation formula dx = z10 - z00 dy = z01 - z00 z = z00 + alpha * dx + beta * dy + alpha * beta * (z11 - dx - dy - z00) else: # Piecewise constant (as verified in input_check) # Set up masks for the quadrants left = alpha < 0.5 right = -left lower = beta < 0.5 upper = -lower lower_left = lower * left lower_right = lower * right upper_left = upper * left # Initialise result array with all elements set to upper right z = z11 # Then set the other quadrants z[lower_left] = z00[lower_left] z[lower_right] = z10[lower_right] z[upper_left] = z01[upper_left] # Self test if len(z) > 0: mz = numpy.nanmax(z) mZ = numpy.nanmax(z) # noinspection PyStringFormat msg = ('Internal check failed. Max interpolated value %.15f ' 'exceeds max grid value %.15f ' % (mz, mZ)) if not(numpy.isnan(mz) or numpy.isnan(mZ)): if not mz <= mZ: raise InaSAFEError(msg) # Populate result with interpolated values for points inside domain # and NaN for values outside r = numpy.zeros(len(points)) r[inside] = z r[outside] = numpy.nan return r
def interpolate1d(x, z, points, mode='linear', bounds_error=False): """Fundamental 1D interpolation routine. :param x: 1D array of x-coordinates on which to interpolate :type x: numpy.ndarray :param z: 1D array of values for each x :type z: numpy.ndarray :param points: 1D array of coordinates where interpolated values are sought :type points: numpy.ndarray :param mode: Determines the interpolation order. Options are: * 'constant' - piecewise constant nearest neighbour interpolation * 'linear' - bilinear interpolation using the two nearest \ neighbours (default) :type mode: str :param bounds_error: Flag to indicate whether an exception will be raised when interpolated values are requested outside the domain of the input data. If False, nan is returned for those values. :type bounds_error: bool :returns: 1D array with same length as points with interpolated values :rtype: numpy.ndarry :raises: RuntimeError ..note:: Input coordinates x are assumed to be monotonically increasing, but need not be equidistantly spaced. z is assumed to have dimension M where M = len(x). """ # Input checks validate_mode(mode) #pylint: disable=W0632 x, z, xi = validate_inputs(x=x, z=z, points=points, bounds_error=bounds_error) #pylint: enable=W0632 # Identify elements that are outside interpolation domain or NaN outside = (xi < x[0]) + (xi > x[-1]) outside += numpy.isnan(xi) inside = -outside xi = xi[inside] # Find upper neighbours for each interpolation point idx = numpy.searchsorted(x, xi, side='left') # Internal check (index == 0 is OK) msg = ('Interpolation point outside domain. This should never happen. ' 'Please email [email protected]') if len(idx) > 0: if not max(idx) < len(x): raise RuntimeError(msg) # Get the two neighbours for each interpolation point x0 = x[idx - 1] x1 = x[idx] z0 = z[idx - 1] z1 = z[idx] # Coefficient for weighting between lower and upper bounds alpha = (xi - x0) / (x1 - x0) if mode == 'linear': # Bilinear interpolation formula dx = z1 - z0 zeta = z0 + alpha * dx else: # Piecewise constant (as verified in input_check) # Set up masks for the quadrants left = alpha < 0.5 # Initialise result array with all elements set to right neighbour zeta = z1 # Then set the left neigbours zeta[left] = z0[left] # Self test if len(zeta) > 0: mzeta = numpy.nanmax(zeta) mz = numpy.nanmax(z) # noinspection PyStringFormat msg = ('Internal check failed. Max interpolated value %.15f ' 'exceeds max grid value %.15f ' % (mzeta, mz)) if not (numpy.isnan(mzeta) or numpy.isnan(mz)): if not mzeta <= mz: raise RuntimeError(msg) # Populate result with interpolated values for points inside domain # and NaN for values outside r = numpy.zeros(len(points)) r[inside] = zeta r[outside] = numpy.nan return r
def interpolate1d(x, z, points, mode='linear', bounds_error=False): """Fundamental 1D interpolation routine. :param x: 1D array of x-coordinates on which to interpolate :type x: numpy.ndarray :param z: 1D array of values for each x :type z: numpy.ndarray :param points: 1D array of coordinates where interpolated values are sought :type points: numpy.ndarray :param mode: Determines the interpolation order. Options are: * 'constant' - piecewise constant nearest neighbour interpolation * 'linear' - bilinear interpolation using the two nearest \ neighbours (default) :type mode: str :param bounds_error: Flag to indicate whether an exception will be raised when interpolated values are requested outside the domain of the input data. If False, nan is returned for those values. :type bounds_error: bool :returns: 1D array with same length as points with interpolated values :rtype: numpy.ndarry :raises: RuntimeError ..note:: Input coordinates x are assumed to be monotonically increasing, but need not be equidistantly spaced. z is assumed to have dimension M where M = len(x). """ # Input checks validate_mode(mode) x, z, xi = validate_inputs( x=x, z=z, points=points, bounds_error=bounds_error) # Identify elements that are outside interpolation domain or NaN outside = (xi < x[0]) + (xi > x[-1]) outside += numpy.isnan(xi) inside = -outside xi = xi[inside] # Find upper neighbours for each interpolation point idx = numpy.searchsorted(x, xi, side='left') # Internal check (index == 0 is OK) msg = ('Interpolation point outside domain. This should never happen. ' 'Please email [email protected]') if len(idx) > 0: if not max(idx) < len(x): raise RuntimeError(msg) # Get the two neighbours for each interpolation point x0 = x[idx - 1] x1 = x[idx] z0 = z[idx - 1] z1 = z[idx] # Coefficient for weighting between lower and upper bounds alpha = (xi - x0) / (x1 - x0) if mode == 'linear': # Bilinear interpolation formula dx = z1 - z0 zeta = z0 + alpha * dx else: # Piecewise constant (as verified in input_check) # Set up masks for the quadrants left = alpha < 0.5 # Initialise result array with all elements set to right neighbour zeta = z1 # Then set the left neigbours zeta[left] = z0[left] # Self test if len(zeta) > 0: mzeta = numpy.nanmax(zeta) mz = numpy.nanmax(z) # noinspection PyStringFormat msg = ('Internal check failed. Max interpolated value %.15f ' 'exceeds max grid value %.15f ' % (mzeta, mz)) if not(numpy.isnan(mzeta) or numpy.isnan(mz)): if not mzeta <= mz: raise RuntimeError(msg) # Populate result with interpolated values for points inside domain # and NaN for values outside r = numpy.zeros(len(points)) r[inside] = zeta r[outside] = numpy.nan return r