Metadata-Version: 2.2
Name: zeroguess
Version: 0.8.3
Summary: Machine Learning for Curve Fitting Parameter Estimation
Home-page: https://github.com/deniz195/zeroguess
Author: Deniz Bozyigit
Author-email: Deniz Bozyigit <deniz195@gmail.com>
License: MIT
Project-URL: Homepage, https://github.com/deniz195/zeroguess
Project-URL: Bug Tracker, https://github.com/deniz195/zeroguess/issues
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.10
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Classifier: Topic :: Scientific/Engineering
Classifier: Topic :: Scientific/Engineering :: Artificial Intelligence
Classifier: Topic :: Scientific/Engineering :: Mathematics
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License-File: LICENSE
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Provides-Extra: lmfit
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# ZeroGuess: Machine Learning for Curve Fitting Parameter Estimation

[![Build Status](https://github.com/deniz195/zeroguess/actions/workflows/test.yml/badge.svg)](https://github.com/deniz195/zeroguess/actions/workflows/test.yml)
[![Coverage Status](https://codecov.io/gh/deniz195/zeroguess/branch/main/graph/badge.svg)](https://codecov.io/gh/deniz195/zeroguess)
[![License: MIT](https://img.shields.io/badge/License-MIT-yellow.svg)](https://opensource.org/licenses/MIT)
[![Python Versions](https://img.shields.io/pypi/pyversions/zeroguess.svg)](https://pypi.org/project/zeroguess/)
[![Benchmark Results](https://img.shields.io/badge/benchmarks-view%20results-blue)](https://deniz195.github.io/zeroguess/)

ZeroGuess uses machine learning to improve curve fitting parameter estimation. It generates optimal starting parameters for fitting functions, reducing computation time and increasing fitting reliability.

## Problem Statement

Curve fitting in scientific applications often encounters issues with initial parameter estimation:
- Convergence to local rather than global minima
- High computational cost for complex functions
- Failed convergence with inadequate starting points

Conventional approaches rely on domain expertise, manual adjustment, or computationally intensive global optimization methods.

ZeroGuess addresses these limitations through machine learning models trained on synthetic data, providing effective parameter estimates that allow simpler fitting algorithms to achieve results comparable to advanced methods with significantly reduced computation time.

## Installation

```bash
pip install zeroguess
```

## Quick Start

### Setup experimental data

```python
import numpy as np

# Define a simple wavelet function directly
def wavelet(x, frequency, phase, position, width):
    z = (x - position) / width
    return np.exp(-z**2) * np.cos(2 * np.pi * frequency * z + phase)

# Create some synthetic experimental data with known parameters
true_params = {
    "frequency": 0.5,
    "phase": 1.0,
    "position": 7.0,
    "width": 1.5
}

# Generate x, y data points
x_data = np.linspace(0, 20, 200)
y_clean = wavelet(x_data, **true_params)

# Add noise
np.random.seed(42)  # For reproducibility
noise_level = 0.05
y_data = y_clean + np.random.normal(0, noise_level * (np.max(y_clean) - np.min(y_clean)), size=y_clean.shape)
```

### lmfit Integration

```python
from zeroguess.integration import ZeroGuessModel

# Enhanced lmfit Model with parameter estimation
model = ZeroGuessModel(
    wavelet,
    independent_vars_sampling={"x": x_data},
    estimator_settings={
        # Configure training parameters
        # "n_samples": 1000,
        # "n_epochs": 200,
        # "validation_split": 0.2,
        # "add_noise": True,
        # "noise_level": 0.1,
        # 'verbose': True
        # Provide a function to make parameters canonical
        # "make_canonical": ...,
        # Save and load model automatically
        "snapshot_path": "model_test.pth",
    },
)

# Set parameter hints
model.set_param_hint("frequency", min=0.05, max=1.0)
model.set_param_hint("phase", min=0.0, max=2.0 * np.pi)
model.set_param_hint("position", min=5.0, max=15.0)
model.set_param_hint("width", min=0.1, max=3.0)

# Guess parameters with ZeroGuess estimator
params = model.guess(y_data, x=x_data)

# Run the fit
result = model.fit(y_data, x=x_data, params=params)
```

### Scipy usage

```python
from scipy import optimize
import zeroguess

# Create and train parameter estimator
estimator = zeroguess.create_estimator(
    function=wavelet,
    param_ranges={
        "frequency": (0.05, 1.0),
        "phase": (0.0, 2.0 * np.pi),
        "position": (5.0, 15.0),
        "width": (0.1, 3.0),
    },
    independent_vars_sampling={"x": x_data},
    snapshot_path="model_dg_plain.pth",  # saves and loads model automatically
)

if not estimator.is_trained:
    estimator.train()

# Get parameter estimates for experimental data
initial_params = estimator.predict(x_data, y_data)

# Use in standard curve fitting
optimal_params, pcov = optimize.curve_fit(wavelet, x_data, y_data, p0=list(initial_params.values()))
```

## Background

### Why should this work?
Providing good initial parameter estimates for an arbitrary fit function is an ambitious task. ZeroGuess is motivated by the experience of a person doing many fits over an extended period of time: At some point you look at your data and can roughly predict what the parameters should be.

This intuition is implemented by ZeroGuess, where a neural network looks at many instances of synthetic data and then is trained to predict the parameters that generated this data. This approach is restricted to several limitations (see below).

### Limitations

**Conceptual Limitations:**
- Users must define appropriate parameter ranges for their specific use case. This is typically feasible as parameters in physical systems are usually bounded
- Parameter ambiguity can affect learning effectiveness (see "Canonical Representations" section)

**Technical Limitations:**
- Only one-dimensional independent variables are currently supported
- Requires currently a consistent sampling of the independent variable across datasets

These technical limitations can be addressed in future versions. If you need these features, please raise an issue on GitHub.

### Canonical Representations

Many fitting functions produce identical outputs with different parameter combinations. For example, in a double Gaussian function, swapping the parameters of the two peaks produces the same curve:

```python
# These two parameter sets produce identical curves
params1 = {"amplitude1": 2, "center1": -2, "width1": 1, 
           "amplitude2": 3, "center2": 2, "width2": 0.5}
params2 = {"amplitude1": 3, "center2": 2, "width2": 0.5,
           "amplitude2": 2, "center1": -2, "width1": 1}
```

You can provide ZeroGuess a function for `make_canonical` to transform parameters into a standardized form (e.g., ordering peaks from left to right), enabling the model to learn a consistent mapping and provide more reliable parameter estimates.

### Performance and Advanced Fitting Methods

Accurate starting parameters are essential for local optimization methods like `least_squares`. Global optimization methods like `dual_annealing` find better solutions but require substantially more computation.  
[![Benchmark Results](https://img.shields.io/badge/benchmarks-view%20results-blue)](https://deniz195.github.io/zeroguess/latest/lmfit_comparison/double_gaussian/report.html )

Benchmarks indicate that ZeroGuess improves the performance of `least_squares` fits to comparable levels with `dual_annealing` (~70% success rate) while reducing computation time by a factor of 100 (from 1150ms to 12ms).

This makes ZeroGuess useful for complex fitting functions with multiple parameters and for large datasets where computation efficiency is important.


## Features

- Automatic estimation of starting parameters for curve fitting
- Support for both SciPy and lmfit curve fitting libraries
- Neural network-based parameter estimation
- Model persistence for reuse without retraining
- Detailed diagnostics and visualization tools

## Requirements

- Python 3.10+
- Dependencies: numpy, scipy, torch, lmfit (optional)

## License

MIT

## Performance Benchmarks

ZeroGuess is benchmarked regularly to ensure optimal performance. View the latest [benchmark results](https://deniz195.github.io/zeroguess/).
