lowess 1.2.0

LOWESS (Locally Weighted Scatterplot Smoothing)
Documentation

LOWESS Project

The fastest, most robust, and most feature-complete language-agnostic LOWESS (Locally Weighted Scatterplot Smoothing) implementation for Rust, Python, R, Julia, JavaScript, C++, and WebAssembly.

[!IMPORTANT]

The lowess-project contains a complete ecosystem for LOWESS smoothing:

Installation

[!NOTE]

Currently available for R, Python, Rust, Julia, Node.js, WebAssembly, and C++. See INSTALLATION.md for detailed installation instructions.

Documentation

[!NOTE]

📚 View the full documentation

LOESS vs. LOWESS

Feature LOESS (This Crate) LOWESS
Polynomial Degree Linear, Quadratic, Cubic, Quartic Linear (Degree 1)
Dimensions Multivariate (n-D support) Univariate (1-D only)
Flexibility High (Distance metrics) Standard
Complexity Higher (Matrix inversion) Lower (Weighted average/slope)

[!TIP] Note: For a LOESS implementation, use loess-project.

Why this package?

Speed

The lowess project beats the competition in terms of speed, whether in single-threaded or multi-threaded parallel execution. It is on average 200-327x faster than Python's statsmodels.lowess and 2-3x faster than R's lowess.

For more details on the performance comparison, see the BENCHMARKS file.

Robustness

This implementation is more robust than R's lowess and Python's statsmodels due to two key design choices:

MAD-Based Scale Estimation:

For robustness weight calculations, this crate uses Median Absolute Deviation (MAD) for scale estimation:

s = median(|r_i - median(r)|)

In contrast, statsmodels and R's lowess uses the median of absolute residuals (MAR):

s = median(|r_i|)
  • MAD is a breakdown-point-optimal estimator—it remains valid even when up to 50% of data are outliers.
  • The median-centering step removes asymmetric bias from residual distributions.
  • MAD provides consistent outlier detection regardless of whether residuals are centered around zero.

Boundary Padding:

This crate applies a range of different boundary policies at dataset edges:

  • Extend: Repeats edge values to maintain local neighborhood size.
  • Reflect: Mirrors data symmetrically around boundaries.
  • Zero: Pads with zeros (useful for signal processing).
  • NoBoundary: Original Cleveland behavior

statsmodels and R's lowess do not apply boundary padding, which can lead to:

  • Biased estimates near boundaries due to asymmetric local neighborhoods.
  • Increased variance at the edges of the smoothed curve.

Features

A variety of features, supporting a range of use cases:

Feature This package statsmodels R (stats)
Kernel 7 options only Tricube only Tricube
Robustness Weighting 3 options only Huber only Huber
Scale Estimation 2 options only MAR only MAR
Boundary Padding 4 options no padding no padding
Zero Weight Fallback 3 options no no
Auto Convergence yes no no
Online Mode yes no no
Streaming Mode yes no no
Confidence Intervals yes no no
Prediction Intervals yes no no
Cross-Validation 2 options no no
Parallel Execution yes no no
GPU Acceleration yes* no no
no-std Support yes no no

* GPU acceleration is currently in beta and may not be available on all platforms.

Validation

All implementations are numerical twins of R's lowess:

Aspect Status Details
Accuracy ✅ EXACT MATCH Max diff < 1e-12 across all scenarios
Consistency ✅ PERFECT Multiple scenarios pass with strict tolerance
Robustness ✅ VERIFIED Robust smoothing matches R exactly

API Reference

R:

Lowess(
    fraction = 0.5,
    iterations = 3L,
    delta = 0.01,
    weight_function = "tricube",
    robustness_method = "bisquare",
    zero_weight_fallback = "use_local_mean",
    boundary_policy = "extend",
    confidence_intervals = 0.95,
    prediction_intervals = 0.95,
    return_diagnostics = TRUE,
    return_residuals = TRUE,
    return_robustness_weights = TRUE,
    cv_fractions = c(0.3, 0.5, 0.7),
    cv_method = "kfold",
    cv_k = 5L,
    auto_converge = 1e-4,
    parallel = TRUE
)$fit(x, y)

# Result structure:
result$x,
result$y,
result$standard_errors,
result$confidence_lower,
result$confidence_upper,
result$prediction_lower,
result$prediction_upper,
result$residuals,
result$robustness_weights,
result$diagnostics,
result$iterations_used,
result$fraction_used,
result$cv_scores

Python:

from fastlowess import Lowess

model = Lowess(
    fraction=0.5,
    iterations=3,
    delta=0.01,
    weight_function="tricube",
    robustness_method="bisquare",
    zero_weight_fallback="use_local_mean",
    boundary_policy="extend",
    confidence_intervals=0.95,
    prediction_intervals=0.95,
    return_diagnostics=True,
    return_residuals=True,
    return_robustness_weights=True,
    cv_fractions=[0.3, 0.5, 0.7],
    cv_method="kfold",
    cv_k=5,
    auto_converge=1e-4,
    parallel=True
)
result = model.fit(x, y)

# Result structure:
result.x,
result.y,
result.standard_errors,
result.confidence_lower,
result.confidence_upper,
result.prediction_lower,
result.prediction_upper,
result.residuals,
result.robustness_weights,
result.diagnostics,
result.iterations_used,
result.fraction_used,
result.cv_scores

Rust:

Lowess::new()
    .fraction(0.5)
    .iterations(3)
    .delta(0.01)
    .weight_function(Tricube)
    .robustness_method(Bisquare)
    .zero_weight_fallback(UseLocalMean)
    .boundary_policy(Extend)
    .confidence_intervals(0.95)
    .prediction_intervals(0.95)
    .return_diagnostics()
    .return_residuals()
    .return_robustness_weights()
    .cross_validate(KFold(5, &[0.3, 0.5, 0.7]).seed(123))
    .auto_converge(1e-4)
    .adapter(Batch)
    .parallel(true)             // fastLowess only
    .backend(CPU)               // fastLowess only: CPU or GPU
    .build()?;

let result = model.fit(x, y);

// Result structure:
pub struct LowessResult<T> {
    pub x: Vec<T>,                           // Sorted x values
    pub y: Vec<T>,                           // Smoothed y values
    pub standard_errors: Option<Vec<T>>,
    pub confidence_lower: Option<Vec<T>>,
    pub confidence_upper: Option<Vec<T>>,
    pub prediction_lower: Option<Vec<T>>,
    pub prediction_upper: Option<Vec<T>>,
    pub residuals: Option<Vec<T>>,
    pub robustness_weights: Option<Vec<T>>,
    pub diagnostics: Option<Diagnostics<T>>,
    pub iterations_used: Option<usize>,
    pub fraction_used: T,
    pub cv_scores: Option<Vec<T>>,
}

Julia:

Lowess(;
    fraction=0.5,
    iterations=3,
    delta=NaN,  # NaN for auto
    weight_function="tricube",
    robustness_method="bisquare",
    zero_weight_fallback="use_local_mean",
    boundary_policy="extend",
    confidence_intervals=NaN,
    prediction_intervals=NaN,
    return_diagnostics=true,
    return_residuals=true,
    return_robustness_weights=true,
    cv_fractions=Float64[], # e.g. [0.3, 0.5]
    cv_method="kfold",
    cv_k=5,
    auto_converge=NaN,
    parallel=true
)

# Result structure:
result.x,
result.y,
result.standard_errors,
result.confidence_lower,
result.confidence_upper,
result.prediction_lower,
result.prediction_upper,
result.residuals,
result.robustness_weights,
result.diagnostics,
result.iterations_used,
result.fraction_used,
result.cv_scores

Node.js:

new Lowess({
    fraction: 0.5,
    iterations: 3,
    delta: 0.01,
    weightFunction: "tricube",
    robustnessMethod: "bisquare",
    zeroWeightFallback: "use_local_mean",
    boundaryPolicy: "extend",
    confidenceIntervals: 0.95,
    predictionIntervals: 0.95,
    returnDiagnostics: true,
    returnResiduals: true,
    returnRobustnessWeights: true,
    cvFractions: [0.3, 0.5, 0.7],
    cvMethod: "kfold",
    cvK: 5,
    autoConverge: 1e-4,
    parallel: true
}).fit(x, y)

// Result structure:
result.x,
result.y,
result.standardErrors,
result.confidenceLower,
result.confidenceUpper,
result.predictionLower,
result.predictionUpper,
result.residuals,
result.robustnessWeights,
result.diagnostics,
result.iterationsUsed,
result.fractionUsed,
result.cvScores

WebAssembly:

smooth(x, y, {
    fraction: 0.5,
    iterations: 3,
    delta: 0.01,
    weightFunction: "tricube",
    robustnessMethod: "bisquare",
    zeroWeightFallback: "use_local_mean",
    boundaryPolicy: "extend",
    confidenceIntervals: 0.95,
    predictionIntervals: 0.95,
    returnDiagnostics: true,
    returnResiduals: true,
    returnRobustnessWeights: true,
    cvFractions: [0.3, 0.5, 0.7],
    cvMethod: "kfold",
    cvK: 5,
    autoConverge: 1e-4,
    parallel: true
})

// Result structure:
result.x,
result.y,
result.standardErrors,
result.confidenceLower,
result.confidenceUpper,
result.predictionLower,
result.predictionUpper,
result.residuals,
result.robustnessWeights,
result.diagnostics,
result.iterationsUsed,
result.fractionUsed,
result.cvScores

C++:

fastlowess::LowessOptions options;
options.fraction = 0.5;
options.iterations = 3;
options.delta = 0.01;
options.weight_function = "tricube";
options.robustness_method = "bisquare";
options.zero_weight_fallback = "use_local_mean";
options.boundary_policy = "extend";
options.confidence_intervals = 0.95;
options.prediction_intervals = 0.95;
options.return_diagnostics = true;
options.return_residuals = true;
options.return_robustness_weights = true;
options.cv_fractions = {0.3, 0.5, 0.7};
options.cv_method = "kfold";
options.cv_k = 5;
options.auto_converge = 1e-4;
options.parallel = true;

fastlowess::Lowess model(options);
auto result = model.fit(x, y);

// Result structure:
result.x_vector(),
result.y_vector(),
result.standard_errors(),
result.confidence_lower(),
result.confidence_upper(),
result.prediction_lower(),
result.prediction_upper(),
result.residuals(),
result.robustness_weights(),
result.diagnostics(),
result.iterations_used(),
result.fraction_used(),
result.cv_scores()

Contributing

Contributions are welcome! Please see the CONTRIBUTING.md file for more information.

License

Licensed under MIT or Apache-2.0.

Citation

If you use this software in your research, please cite it using the CITATION.cff file or the BibTeX entry below:

@software{lowess_project,
  author = {Valizadeh, Amir},
  title = {LOWESS Project: High-Performance Locally Weighted Scatterplot Smoothing},
  year = {2026},
  url = {https://github.com/thisisamirv/lowess-project},
  license = {MIT OR Apache-2.0}
}