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The confidence interval is the range of values around the mean that contains the true mean. It is expressed as a probability percentage. The interpretation of a 95% confidence interval, for instance, is that the statistician is 95% confident that the true mean falls within the interval. The upper and lower limits of this range are known as confidence limits. The confidence limits for the true mean are estimated from the sample's mean, the standard deviation, and the statistical factor...
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The atomic mass of an element varies due to the relative ratio of its isotopes. A sample's relative proportion of oxygen isotopes influences its average atomic mass. For instance, if we were to measure the atomic mass of oxygen from a sample, the mass would be a weighted average of the isotopic masses of oxygen in that sample. Since a single sample is not likely to perfectly reflect the true atomic mass of oxygen for all the molecules of oxygen on Earth, the mass we obtain from this...
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The interval estimate of any variable is known as the prediction interval. It helps decide if a point estimate is dependable.
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An unbiased point estimate is often insufficient to predict a population estimate, such as population mean or population proportion. In this scenario, a confidence interval is used. A confidence interval is an estimate similar to a  sample proportion. However, unlike the point estimate which is a single value, the confidence interval  contains a range of values. These values have lower and upper limits, known as confidence limits, and can be designated as L1 and L2, respectively.
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Mamba time series forecasting with uncertainty quantification.

Pedro Pessoa1,2, Paul Campitelli1,2, Douglas P Shepherd1,2

  • 1Center for Biological Physics, Tempe, AZ, United States of America.

Machine Learning: Science and Technology
|July 24, 2025
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Summary
This summary is machine-generated.

State space models like Mamba show promise for time series forecasting but lack accurate uncertainty quantification. Our Mamba-ProbTSF method enhances Mamba by modeling predictive uncertainty, improving forecast reliability for electricity and traffic data.

Keywords:
Time Series Forecastingnon-linear dynamicsstate space modelsuncertainty quantification

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Area of Science:

  • Machine Learning
  • Time Series Analysis
  • Probabilistic Forecasting

Background:

  • State space models, including Mamba, are increasingly used for time series forecasting due to their sequence pattern recognition capabilities.
  • Existing Mamba implementations show significant mean errors in electricity consumption (approx. 8%) and traffic occupancy (approx. 18%) benchmarks.
  • There is a need to quantify the uncertainty in Mamba forecasts to distinguish between inaccuracy and inherent data variability.

Purpose of the Study:

  • To develop a method for quantifying the predictive uncertainty of Mamba-based time series forecasts.
  • To introduce a dual-network framework, Mamba-ProbTSF, for probabilistic forecasting using the Mamba architecture.
  • To evaluate the performance and reliability of Mamba-ProbTSF against existing methods.

Main Methods:

  • Proposed a dual-network framework integrating Mamba for probabilistic time series forecasting.
  • One network generates point forecasts; a second network models predictive uncertainty by estimating variance.
  • Implemented the Mamba with probabilistic TSF (Mamba-ProbTSF) tool, with code available on GitHub.

Main Results:

  • Achieved reduced Kullback-Leibler divergence (10^-3 for synthetic, 10^-1 for real-world data), indicating improved probability distribution modeling.
  • Validated that true trajectories fall within the predicted two-sigma uncertainty interval approximately 95% of the time for benchmark datasets.
  • Demonstrated consistently lower forecast errors and more reliable uncertainty quantification compared to DeepAR and ARIMA.

Conclusions:

  • Mamba-ProbTSF effectively quantifies predictive uncertainty in Mamba forecasts, enhancing reliability for time series forecasting tasks.
  • The method shows superior performance over leading probabilistic forecasting models like DeepAR and ARIMA.
  • The framework holds potential for application in stochastic processes, including Brownian motion and molecular dynamics.