# Copyright (c) DataLab Platform Developers, BSD 3-Clause license, see LICENSE file. """ Curve Fitting Algorithms ========================= This module provides curve fitting functions without GUI dependencies. The functions take x,y data and return fitted curves and parameters. These functions are designed to be used programmatically and in tests, providing the core fitting algorithms without PlotPy GUI components. """ from __future__ import annotations import string import warnings from typing import Type import numpy as np import scipy.optimize import scipy.special from sigima.tools.signal import peakdetection, pulse class FitComputer: """Base class for fit computers""" PARAMS_NAMES: tuple[str] = () # To be defined by subclasses def __init__(self, x: np.ndarray, y: np.ndarray) -> None: self.x = x self.y = y def get_params_names(self) -> tuple[str]: """Return the names of the parameters used in this fit.""" return self.PARAMS_NAMES def check_params(self, **params) -> None: """Check that all required parameters are provided.""" missing = [p for p in self.get_params_names() if p not in params] if missing: raise ValueError(f"Missing required parameters: {missing}") @classmethod def args_kwargs_to_list(cls, *args, **kwargs) -> list[float]: """Convert args and kwargs to a parameter list.""" if kwargs and args: raise ValueError("Cannot mix positional and keyword arguments") if cls.PARAMS_NAMES: param_names = cls.PARAMS_NAMES else: if not kwargs: raise ValueError("No parameter names available and no kwargs provided") param_names = cls.infer_param_names_from_kwargs(kwargs) if len(args) > len(param_names): raise ValueError("Too many positional arguments") if args: params = list(args) else: params = [] for name in param_names: if name in kwargs: params.append(kwargs[name]) else: raise ValueError(f"Missing required parameter: {name}") return params @classmethod def infer_param_names_from_kwargs(cls, kwargs: dict) -> tuple[str, ...]: """Infer parameter names from kwargs. Override in subclasses if needed.""" return tuple(kwargs.keys()) @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate the fit function at given x values.""" raise NotImplementedError("Subclasses must implement evaluate method") def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for fitting. To be implemented by subclasses.""" raise NotImplementedError( "Subclasses must implement compute_initial_params method" ) # pylint: disable=unused-argument def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for fitting.""" return None def create_params(self, y_fitted: np.ndarray, **params) -> dict[str, float]: """Create a fit parameters dictionary from given parameters.""" self.check_params(**params) params["fit_type"] = self.__class__.__name__.replace("FitComputer", "").lower() params["residual_rms"] = np.sqrt(np.mean((self.y - y_fitted) ** 2)) return params def fit(self) -> tuple[np.ndarray, dict[str, float]]: """Fit the model to the data.""" # Default implementation uses scipy curve_fit return self.optimize_fit_with_scipy() def optimize_fit_with_scipy(self) -> tuple[np.ndarray, np.ndarray]: """Generic fitting function using `scipy.optimize.curve_fit` Returns: tuple: (fitted_y_values, fitted_parameters) """ initial_params = self.compute_initial_params() bounds = self.compute_bounds(**initial_params) # pylint: disable=E1128 if bounds is not None: # Convert bounds to scipy format lower_bounds = [b[0] for b in bounds] upper_bounds = [b[1] for b in bounds] bounds_scipy = (lower_bounds, upper_bounds) else: bounds_scipy = (-np.inf, np.inf) # Create a wrapper function that unpacks parameters correctly def objective_func(x, *params): """Wrapper function for scipy curve_fit.""" param_dict = dict(zip(self.get_params_names(), params)) try: # Try as classmethod first return self.__class__.evaluate(x, **param_dict) except TypeError: # Fall back to instance method return self.evaluate(x, **param_dict) try: with warnings.catch_warnings(): warnings.filterwarnings( "ignore", category=scipy.optimize.OptimizeWarning ) popt, _ = scipy.optimize.curve_fit( objective_func, self.x, self.y, p0=list(initial_params.values()), bounds=bounds_scipy, maxfev=5000, ) except (RuntimeError, ValueError, TypeError) as err: # Fallback to initial parameters if optimization fails warnings.warn(f"Optimization failed: {err}. Using initial parameters.") try: # Try as classmethod first fitted_y = self.__class__.evaluate(self.x, **initial_params) except TypeError: # Fall back to instance method fitted_y = self.evaluate(self.x, **initial_params) result_params = self.create_params(fitted_y, **initial_params) return fitted_y, result_params names = self.get_params_names() assert len(popt) == len(names), "Unexpected number of parameters" param_dict = dict(zip(names, popt)) try: # Try as classmethod first fitted_y = self.__class__.evaluate(self.x, **param_dict) except TypeError: # Fall back to instance method fitted_y = self.evaluate(self.x, **param_dict) params = self.create_params(fitted_y, **param_dict) return fitted_y, params class LinearFitComputer(FitComputer): """Linear fit computer""" PARAMS_NAMES = ("a", "b") # slope and intercept @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate linear function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking a, b = cls.args_kwargs_to_list(*args, **kwargs) return a * x + b def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for linear fitting using numpy polyfit.""" coeffs = np.polyfit(self.x, self.y, 1) a, b = coeffs return {"a": a, "b": b} class PolynomialFitComputer(FitComputer): """Polynomial fit computer of given degree""" def __init__(self, x: np.ndarray, y: np.ndarray, degree: int = 2) -> None: super().__init__(x, y) if degree < 1: raise ValueError("Degree must be at least 1") self.degree = degree def get_params_names(self) -> tuple[str]: """Return the names of the parameters used in this fit.""" return tuple(string.ascii_lowercase[: self.degree + 1]) @classmethod def infer_param_names_from_kwargs(cls, kwargs: dict) -> tuple[str, ...]: """Infer parameter names for polynomial from kwargs.""" # Parameters are named 'a', 'b', 'c', ... in order param_keys = [k for k in kwargs.keys() if k in string.ascii_lowercase] if not param_keys: raise ValueError("No valid polynomial parameters found") # Sort to ensure correct order (a, b, c, ...) return tuple(sorted(param_keys)) @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate polynomial function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking coeffs = cls.args_kwargs_to_list(*args, **kwargs) return np.polyval(coeffs, x) def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for polynomial fitting using numpy polyfit.""" coeffs = np.polyfit(self.x, self.y, self.degree) param_names = self.get_params_names() # Map numpy polyfit coefficients (highest to lowest degree) to parameter names return dict(zip(param_names, coeffs)) class GaussianFitComputer(FitComputer): """Gaussian fit computer""" PARAMS_NAMES = ("amp", "sigma", "x0", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate Gaussian function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amp, sigma, x0, y0 = cls.args_kwargs_to_list(*args, **kwargs) return pulse.GaussianModel.func(x, amp, sigma, x0, y0) def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Gaussian fitting.""" dx = np.max(self.x) - np.min(self.x) dy = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) sigma = dx * 0.1 amp = pulse.GaussianModel.get_amp_from_amplitude(dy, sigma) x0 = peakdetection.xpeak(self.x, self.y) y0 = y_min return {"amp": amp, "sigma": sigma, "x0": x0, "y0": y0} def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Gaussian fitting.""" dy = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) return [ (0.0, initial_params["amp"] * 2), # amp (initial_params["sigma"] * 0.1, initial_params["sigma"] * 10), # sigma (np.min(self.x), np.max(self.x)), # x0 (y_min - 0.2 * dy, y_min + 0.2 * dy), # y0 ] class LorentzianFitComputer(FitComputer): """Lorentzian fit computer""" PARAMS_NAMES = ("amp", "sigma", "x0", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate Lorentzian function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amp, sigma, x0, y0 = cls.args_kwargs_to_list(*args, **kwargs) return pulse.LorentzianModel.func(x, amp, sigma, x0, y0) def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Lorentzian fitting.""" dx = np.max(self.x) - np.min(self.x) dy = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) sigma = dx * 0.1 amp = pulse.LorentzianModel.get_amp_from_amplitude(dy, sigma) x0 = peakdetection.xpeak(self.x, self.y) y0 = y_min return {"amp": amp, "sigma": sigma, "x0": x0, "y0": y0} def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Lorentzian fitting.""" dy = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) return [ (0.0, initial_params["amp"] * 2), # amp (initial_params["sigma"] * 0.1, initial_params["sigma"] * 10), # sigma (np.min(self.x), np.max(self.x)), # x0 (y_min - 0.2 * dy, y_min + 0.2 * dy), # y0 ] class VoigtFitComputer(FitComputer): """Voigt fit computer""" PARAMS_NAMES = ("amp", "sigma", "x0", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate Voigt function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amp, sigma, x0, y0 = cls.args_kwargs_to_list(*args, **kwargs) return pulse.VoigtModel.func(x, amp, sigma, x0, y0) def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Voigt fitting.""" dx = np.max(self.x) - np.min(self.x) dy = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) sigma = dx * 0.1 amp = pulse.VoigtModel.get_amp_from_amplitude(dy, sigma) x0 = peakdetection.xpeak(self.x, self.y) y0 = y_min return {"amp": amp, "sigma": sigma, "x0": x0, "y0": y0} def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Voigt fitting.""" sigma = initial_params["sigma"] amp = initial_params["amp"] return [ (0.0, 10 * amp), # amp (sigma * 0.01, sigma * 10), # sigma (np.min(self.x), np.max(self.x)), # x0 (initial_params["y0"] - amp, initial_params["y0"] + amp), # y0 ] class ExponentialFitComputer(FitComputer): """Exponential fit computer: y = a * exp(b * x) + y0""" PARAMS_NAMES = ("a", "b", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate exponential function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking a, b, y0 = cls.args_kwargs_to_list(*args, **kwargs) # Clip b to prevent overflow b_clipped = np.clip(b, -50, 50) return a * np.exp(b_clipped * x) + y0 def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for exponential fitting.""" y_range = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) # Estimate from data if len(self.y) > 1: # Try to determine if it's growth or decay if self.y[0] > self.y[-1]: # Decay a = y_range b = -1.0 / (np.max(self.x) - np.min(self.x)) else: # Growth a = y_range * 0.1 b = 1.0 / (np.max(self.x) - np.min(self.x)) else: a = y_range b = -1.0 y0 = y_min return {"a": a, "b": b, "y0": y0} def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for exponential fitting.""" y_range = np.max(self.y) - np.min(self.y) y_min = np.min(self.y) return [ (-y_range * 1000, y_range * 1000), # a (-10, 10), # b (reasonable range to prevent overflow) (y_min - 0.5 * y_range, y_min + 0.5 * y_range), # y0 ] class PlanckianFitComputer(FitComputer): """Planckian fit computer""" PARAMS_NAMES = ("amp", "x0", "sigma", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Return Planckian fitting function Args: x: wavelength values (in nm or other units) amp: amplitude scaling factor x0: peak wavelength (Wien's displacement law) sigma: width parameter (larger sigma = wider peak) y0: baseline offset """ # pylint: disable=unbalanced-tuple-unpacking amp, x0, sigma, y0 = cls.args_kwargs_to_list(*args, **kwargs) # Planck-like function with Wien's displacement law behavior # The function peaks at approximately x0 when properly parameterized x = np.asarray(x, dtype=float) y = np.full_like(x, y0, dtype=float) # Only compute for positive wavelengths valid_mask = x > 0 if not np.any(valid_mask): return y x_valid = x[valid_mask] try: # Wien's displacement law: λ_max * T = constant # For a proper Planckian curve, we need: # d/dx [x^(-5) / (exp(c/x) - 1)] = 0 at x = x0 # This gives us c = 5*x0 for the peak condition # The exponential argument that produces peak at x0 wien_constant = 5.0 # Use sigma to control the effective temperature/width # sigma=1.0 gives the canonical Planck curve # sigma>1.0 gives broader curves (cooler) # sigma<1.0 gives sharper curves (hotter) temperature_factor = sigma exp_argument = wien_constant * x0 / (x_valid * temperature_factor) # Clip to prevent overflow exp_argument = np.clip(exp_argument, 0, 50) # Planck function components: # 1. The wavelength dependence: x^(-5) wavelength_factor = (x_valid / x0) ** (-5) # 2. The exponential term: 1/(exp(arg) - 1) exp_denominator = np.expm1(exp_argument) # exp(x) - 1 # Avoid division by very small numbers exp_denominator = np.where( np.abs(exp_denominator) < 1e-12, 1e-12, exp_denominator ) # Combine the Planckian terms planck_curve = wavelength_factor / exp_denominator # Apply amplitude and add to baseline y[valid_mask] += amp * planck_curve except (OverflowError, ZeroDivisionError, RuntimeWarning): # If computation fails, return baseline only pass return y def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Planckian fitting.""" dy = np.max(self.y) - np.min(self.y) x_peak = self.x[np.argmax(self.y)] y_min = np.min(self.y) return {"amp": dy, "x0": x_peak, "sigma": 1.0, "y0": y_min} def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Planckian fitting.""" return [ (initial_params["amp"] * 0.01, initial_params["amp"] * 100), # amp (np.min(self.x), np.max(self.x)), # x0 (0.1, 5.0), # sigma ( initial_params["y0"] - 0.2 * initial_params["amp"], initial_params["y0"] + 0.2 * initial_params["amp"], ), # y0 ] class TwoHalfGaussianFitComputer(FitComputer): """Two Half-Gaussian fit computer""" PARAMS_NAMES = ( "amp_left", "amp_right", "sigma_left", "sigma_right", "x0", "y0_left", "y0_right", ) @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Return two half-Gaussian with separate left/right amplitudes Args: x: x values amp_left: amplitude for left side (x < x0) amp_right: amplitude for right side (x >= x0) sigma_left: standard deviation for x < x0 sigma_right: standard deviation for x > x0 x0: center position y0_left: baseline offset for x < x0 y0_right: baseline offset for x >= x0 """ # pylint: disable=unbalanced-tuple-unpacking amp_left, amp_right, sigma_left, sigma_right, x0, y0_left, y0_right = ( cls.args_kwargs_to_list(*args, **kwargs) ) y = np.zeros_like(x) # Left side (x < x0): use amp_left, sigma_left and y0_left left_mask = x < x0 if np.any(left_mask): exp_left = np.exp(-0.5 * ((x[left_mask] - x0) / sigma_left) ** 2) y[left_mask] = y0_left + amp_left * exp_left # Right side (x >= x0): use amp_right, sigma_right and y0_right right_mask = x >= x0 if np.any(right_mask): exp_right = np.exp(-0.5 * ((x[right_mask] - x0) / sigma_right) ** 2) y[right_mask] = y0_right + amp_right * exp_right return y def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Two Half-Gaussian fitting.""" # Parameter estimation with separate baseline analysis dx = np.max(self.x) - np.min(self.x) dy = np.max(self.y) - np.min(self.y) x_peak = self.x[np.argmax(self.y)] # Estimate separate baselines for left and right sides left_mask = self.x < x_peak right_mask = self.x >= x_peak # Use the lower quartile of each side for robust baseline estimation if np.any(left_mask): y0_left = np.percentile(self.y[left_mask], 25) else: y0_left = np.min(self.y) if np.any(right_mask): y0_right = np.percentile(self.y[right_mask], 25) else: y0_right = np.min(self.y) # Peak amplitude estimation (above average baseline) avg_baseline = (y0_left + y0_right) / 2 amp_guess = np.max(self.y) - avg_baseline half_max = avg_baseline + amp_guess * 0.5 # Find points at half maximum left_points = np.where((self.x < x_peak) & (self.y >= half_max))[0] right_points = np.where((self.x > x_peak) & (self.y >= half_max))[0] # Estimate sigma values from half-width measurements if len(left_points) > 0: left_hw = x_peak - self.x[left_points[0]] sigma_left = left_hw / np.sqrt(2 * np.log(2)) else: sigma_left = dx * 0.05 if len(right_points) > 0: right_hw = self.x[right_points[-1]] - x_peak sigma_right = right_hw / np.sqrt(2 * np.log(2)) else: sigma_right = dx * 0.05 x0 = x_peak if np.any(left_mask): left_peak_val = np.max(self.y[left_mask]) amp_left = left_peak_val - y0_left else: amp_left = dy * 0.5 if np.any(right_mask): right_peak_val = np.max(self.y[right_mask]) amp_right = right_peak_val - y0_right else: amp_right = dy * 0.5 return { "amp_left": amp_left, "amp_right": amp_right, "sigma_left": sigma_left, "sigma_right": sigma_right, "x0": x0, "y0_left": y0_left, "y0_right": y0_right, } class DoubleExponentialFitComputer(FitComputer): """Piecewise exponential (raise-decay) fit computer.""" PARAMS_NAMES = ("x_center", "a_left", "b_left", "a_right", "b_right", "y0") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Return piecewise exponential (raise-decay) fitting function Args: x: time values x_center: center position (boundary between left and right components) a_left: left component amplitude coefficient b_left: left component time constant coefficient a_right: right component amplitude coefficient b_right: right component time constant coefficient y0: baseline offset """ # pylint: disable=unbalanced-tuple-unpacking x_center, a_left, b_left, a_right, b_right, y0 = cls.args_kwargs_to_list( *args, **kwargs ) y = np.zeros_like(x) y[x < x_center] = a_left * np.exp(b_left * x[x < x_center]) + y0 y[x >= x_center] = a_right * np.exp(b_right * x[x >= x_center]) + y0 return y def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for piecewise exponential (raise-decay) fitting.""" y_range = np.max(self.y) - np.min(self.y) x_range = np.max(self.x) - np.min(self.x) y_max = np.max(self.y) # Baseline is rarely different from zero: y0 = 0.0 # Analyze signal characteristics for better initial guesses peak_idx = np.argmax(self.y) # Estimate x_center as the peak position x_center = self.x[peak_idx] # Estimate parameters (a_left, b_left, a_right, b_right) by decomposing # the signal into growth and decay components based on peak position, and # fitting each curve with exponential functions using exponential_fit(). # X center estimation is very rough here, so we need to remove say 10% of # the x range on each side to avoid fitting artifacts. x_range = np.max(self.x) - np.min(self.x) x_left_mask = self.x < (x_center - 0.1 * x_range) x_right_mask = self.x >= (x_center + 0.1 * x_range) x_left, y_left = self.x[x_left_mask], self.y[x_left_mask] x_right, y_right = self.x[x_right_mask], self.y[x_right_mask] left_params = {"a": 0.0, "b": 0.1, "y0": 0.0} right_params = {"a": 0.0, "b": 0.1, "y0": 0.0} if np.any(x_left_mask): _y_fitted, left_params = ExponentialFitComputer(x_left, y_left).fit() if np.any(x_right_mask): _y_fitted, right_params = ExponentialFitComputer(x_right, y_right).fit() a_left = left_params["a"] b_left = left_params["b"] a_right = right_params["a"] b_right = right_params["b"] y0 = (left_params["y0"] + right_params["y0"]) / 2 # Set bounds for parameters - b can be positive or negative amp_bound = max(abs(y_max - y0), y_range) * 2 rate_bound = 5.0 / max(x_range, 1e-6) # Avoid division by zero # Ensure initial parameters are within bounds b_left = np.clip(b_left, -rate_bound, rate_bound) b_right = np.clip(b_right, -rate_bound, rate_bound) a_left = np.clip(a_left, -amp_bound, amp_bound) a_right = np.clip(a_right, -amp_bound, amp_bound) return { "x_center": x_center, "a_left": a_left, "b_left": b_left, "a_right": a_right, "b_right": b_right, "y0": y0, } class BaseMultiPeakFitComputer(FitComputer): """Base class for multi-peak fit computers""" PULSE_MODEL: Type[pulse.PulseFitModel] # To be defined by subclasses def __init__( self, x: np.ndarray, y: np.ndarray, peak_indices: list[int] | None = None ) -> None: super().__init__(x, y) self.peak_indices = peak_indices def get_params_names(self) -> tuple[str]: """Return the names of the parameters used in this fit.""" n_peaks = len(self.peak_indices) names = [] for i in range(n_peaks): names.extend([f"amp_{i + 1}", f"sigma_{i + 1}", f"x0_{i + 1}"]) names.append("y0") return tuple(names) @classmethod def infer_param_names_from_kwargs(cls, kwargs: dict) -> tuple[str, ...]: """Infer parameter names for multi-gaussian from kwargs.""" # Find all amp_X parameters to count peaks amp_params = [k for k in kwargs.keys() if k.startswith("amp_")] n_peaks = len(amp_params) if n_peaks == 0: raise ValueError("No amp parameters found") names = [] for i in range(1, n_peaks + 1): names.extend([f"amp_{i}", f"sigma_{i}", f"x0_{i}"]) names.append("y0") return tuple(names) @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate the fit function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking paramlist = cls.args_kwargs_to_list(*args, **kwargs) # Determine number of peaks from parameter count n_peaks = ( len(paramlist) - 1 ) // 3 # -1 for y0, then divide by 3 params per peak y_result = np.zeros_like(x) + paramlist[-1] for i in range(n_peaks): amp, sigma, x0 = paramlist[3 * i : 3 * i + 3] y_result += cls.PULSE_MODEL.func(x, amp, sigma, x0, 0.0) return y_result def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Multi Gaussian fitting.""" params = {} for i, peak_idx in enumerate(self.peak_indices): if i > 0: istart = (self.peak_indices[i - 1] + peak_idx) // 2 else: istart = 0 if i < len(self.peak_indices) - 1: iend = (self.peak_indices[i + 1] + peak_idx) // 2 else: iend = len(self.x) - 1 local_dx = 0.5 * (self.x[iend] - self.x[istart]) local_dy = np.max(self.y[istart:iend]) - np.min(self.y[istart:iend]) amp = self.PULSE_MODEL.get_amp_from_amplitude(local_dy, local_dx * 0.1) sigma = local_dx * 0.1 x0 = self.x[peak_idx] params[f"amp_{i + 1}"] = amp params[f"sigma_{i + 1}"] = sigma params[f"x0_{i + 1}"] = x0 params["y0"] = np.min(self.y) return params def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Multi Lorentzian fitting.""" bounds = [] for i, peak_idx in enumerate(self.peak_indices): if i > 0: istart = (self.peak_indices[i - 1] + peak_idx) // 2 else: istart = 0 if i < len(self.peak_indices) - 1: iend = (self.peak_indices[i + 1] + peak_idx) // 2 else: iend = len(self.x) - 1 local_dx = 0.5 * (self.x[iend] - self.x[istart]) bounds.extend( [ (0.0, initial_params[f"amp_{i + 1}"] * 10.0), # amp (local_dx * 0.001, local_dx * 10.0), # sigma (self.x[istart], self.x[iend]), # x0 ] ) y0 = initial_params["y0"] dy = np.max(self.y) - np.min(self.y) bounds.append((y0 - dy, y0 + dy)) return bounds def create_params(self, y_fitted: np.ndarray, **params) -> dict[str, float]: """Create a flat fit parameters dictionary.""" self.check_params(**params) params["fit_type"] = self.__class__.__name__.replace("FitComputer", "").lower() params["residual_rms"] = np.sqrt(np.mean((self.y - y_fitted) ** 2)) return params class MultiGaussianFitComputer(BaseMultiPeakFitComputer): """Multi Gaussian fit computer""" PULSE_MODEL = pulse.GaussianModel class MultiLorentzianFitComputer(BaseMultiPeakFitComputer): """Multi Lorentzian fit computer""" PULSE_MODEL = pulse.LorentzianModel class SinusoidalFitComputer(FitComputer): """Sinusoidal fit computer.""" PARAMS_NAMES = ("amplitude", "frequency", "phase", "offset") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate sinusoidal function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amplitude, frequency, phase, offset = cls.args_kwargs_to_list(*args, **kwargs) return amplitude * np.sin(2 * np.pi * frequency * x + phase) + offset def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for sinusoidal fitting.""" # Parameter estimation using FFT for frequency dy = np.max(self.y) - np.min(self.y) amplitude = dy / 2 offset = np.mean(self.y) phase = 0.0 # Estimate frequency using FFT if len(self.x) > 2: dt = self.x[1] - self.x[0] # Assuming evenly spaced fft_y = np.fft.fft(self.y - offset) freqs = np.fft.fftfreq(len(self.y), dt) # Find dominant frequency (excluding DC component) dominant_idx = np.argmax(np.abs(fft_y[1 : len(fft_y) // 2])) + 1 frequency = np.abs(freqs[dominant_idx]) else: frequency = 1.0 / (np.max(self.x) - np.min(self.x)) return { "amplitude": amplitude, "frequency": frequency, "phase": phase, "offset": offset, } def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for sinusoidal fitting.""" dy = initial_params["amplitude"] * 2 y0 = initial_params["offset"] return [ (0.0, dy), # amplitude (0.0, 2.0 * initial_params["frequency"]), # frequency (-2 * np.pi, 2 * np.pi), # phase (y0 - dy, y0 + dy), # offset ] class CDFFitComputer(FitComputer): """Cumulative Distribution Function (CDF) fit computer""" PARAMS_NAMES = ("amplitude", "mu", "sigma", "baseline") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate CDF function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amplitude, mu, sigma, baseline = cls.args_kwargs_to_list(*args, **kwargs) erf = scipy.special.erf # pylint: disable=no-member return amplitude * erf((x - mu) / (sigma * np.sqrt(2))) + baseline def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for CDF fitting.""" # Parameter estimation y_min, y_max = np.min(self.y), np.max(self.y) dy = y_max - y_min x_min, x_max = np.min(self.x), np.max(self.x) dx = x_max - x_min return { "amplitude": dy, "mu": (x_max + np.abs(x_min)) / 2, "sigma": dx / 10, "baseline": dy / 2, } def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for CDF fitting.""" y_min, y_max = np.min(self.y), np.max(self.y) dy = initial_params["amplitude"] x_min, x_max = np.min(self.x), np.max(self.x) dx = x_max - x_min return [ (0.0, dy * 2), # amplitude (x_min, x_max), # mu (dx * 0.001, dx), # sigma (y_min - dy, y_max + dy), # baseline ] class SigmoidFitComputer(FitComputer): """Sigmoid fit computer.""" PARAMS_NAMES = ("amplitude", "k", "x0", "offset") @classmethod def evaluate(cls, x: np.ndarray, *args, **kwargs) -> np.ndarray: """Evaluate Sigmoid function at given x values.""" # pylint: disable=unbalanced-tuple-unpacking amplitude, k, x0, offset = cls.args_kwargs_to_list(*args, **kwargs) return amplitude / (1 + np.exp(-k * (x - x0))) + offset def compute_initial_params(self) -> dict[str, float]: """Compute initial parameters for Sigmoid fitting.""" y_min, y_max = np.min(self.y), np.max(self.y) dy = y_max - y_min x_min, x_max = np.min(self.x), np.max(self.x) dx = x_max - x_min return { "amplitude": dy, "k": 4.0 / dx, "x0": (x_max + np.abs(x_min)) / 2, "offset": y_min, } def compute_bounds(self, **initial_params) -> list[tuple[float, float]] | None: """Compute parameter bounds for Sigmoid fitting.""" y_min, y_max = np.min(self.y), np.max(self.y) dy = initial_params["amplitude"] x_min, x_max = np.min(self.x), np.max(self.x) dx = x_max - x_min return [ (0.0, 10 * dy), # amplitude (0.1 / dx, 100.0 / dx), # k (x_min, x_max), # x0 (y_min - dy, y_max + dy), # offset ] def linear_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute linear fit: y = a*x + b. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return LinearFitComputer(x, y).fit() def polynomial_fit( x: np.ndarray, y: np.ndarray, degree: int = 2 ) -> tuple[np.ndarray, dict[str, float]]: """Compute polynomial fit. Args: x: x data array y: y data array degree: polynomial degree Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return PolynomialFitComputer(x, y, degree).fit() def gaussian_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute Gaussian fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return GaussianFitComputer(x, y).fit() def lorentzian_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict]: """Compute Lorentzian fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return LorentzianFitComputer(x, y).fit() def exponential_fit( x: np.ndarray, y: np.ndarray ) -> tuple[np.ndarray, dict[str, float]]: """Compute exponential fit: y = a * exp(b * x) + y0. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return ExponentialFitComputer(x, y).fit() def planckian_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute Planckian (blackbody radiation) fit. Args: x: wavelength data array y: intensity data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return PlanckianFitComputer(x, y).fit() def twohalfgaussian_fit( x: np.ndarray, y: np.ndarray ) -> tuple[np.ndarray, dict[str, float]]: """Compute two half-Gaussian fit for asymmetric peaks with separate baselines. Now supports separate amplitudes for even better asymmetric peak fitting. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return TwoHalfGaussianFitComputer(x, y).fit() def piecewiseexponential_fit( x: np.ndarray, y: np.ndarray ) -> tuple[np.ndarray, dict[str, float]]: """Compute piecewise exponential fit (raise-decay). Args: x: time data array y: intensity data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return DoubleExponentialFitComputer(x, y).fit() def multilorentzian_fit( x: np.ndarray, y: np.ndarray, peak_indices: list[int] ) -> tuple[np.ndarray, dict[str, float]]: """Compute multi-Lorentzian fit for multiple peaks. Args: x: x data array y: y data array peak_indices: list of peak indices Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return MultiLorentzianFitComputer(x, y, peak_indices).fit() def multigaussian_fit( x: np.ndarray, y: np.ndarray, peak_indices: list[int] ) -> tuple[np.ndarray, dict[str, float]]: """Compute multi-Gaussian fit for multiple peaks. Args: x: x data array y: y data array peak_indices: list of peak indices Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return MultiGaussianFitComputer(x, y, peak_indices).fit() def sinusoidal_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute sinusoidal fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return SinusoidalFitComputer(x, y).fit() def voigt_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute Voigt fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return VoigtFitComputer(x, y).fit() def cdf_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute Cumulative Distribution Function (CDF) fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return CDFFitComputer(x, y).fit() def sigmoid_fit(x: np.ndarray, y: np.ndarray) -> tuple[np.ndarray, dict[str, float]]: """Compute Sigmoid (Logistic) fit. Args: x: x data array y: y data array Returns: A tuple containing the fitted y values and a dictionary of fit parameters. """ return SigmoidFitComputer(x, y).fit() FIT_TYPE_MAPPING = { "linear": LinearFitComputer, "polynomial": PolynomialFitComputer, "gaussian": GaussianFitComputer, "lorentzian": LorentzianFitComputer, "exponential": ExponentialFitComputer, "planckian": PlanckianFitComputer, "twohalfgaussian": TwoHalfGaussianFitComputer, "doubleexponential": DoubleExponentialFitComputer, "multilorentzian": MultiLorentzianFitComputer, "multigaussian": MultiGaussianFitComputer, "sinusoidal": SinusoidalFitComputer, "voigt": VoigtFitComputer, "cdf": CDFFitComputer, "sigmoid": SigmoidFitComputer, } def evaluate_fit(x: np.ndarray, **fit_params) -> np.ndarray: """Evaluate fit function with given parameters at x values. Args: x: X values to evaluate at **fit_params: Fit parameters (any of the ``*Params`` dataclasses) Returns: Y values computed from the fit function """ params = fit_params.copy() params.pop("residual_rms", None) fcclass: Type[FitComputer] = FIT_TYPE_MAPPING.get(params.pop("fit_type", None)) if fcclass is None: raise ValueError(f"Unsupported fit type: {fit_params.get('fit_type')}") return fcclass.evaluate(x, **params)