Metadata-Version: 2.1
Name: tsmoothie
Version: 1.0.4
Summary: A python library for timeseries smoothing and outlier detection in a vectorized way.
Home-page: https://github.com/cerlymarco/tsmoothie
Author: Marco Cerliani
Author-email: cerlymarco@gmail.com
License: MIT
Description: # tsmoothie
        
        A python library for time-series smoothing and outlier detection in a vectorized way.
        
        ## Overview
        
        tsmoothie computes, in a fast and efficient way, the smoothing of single or multiple time-series. 
        
        The smoothing techniques available are:
        
        - Exponential Smoothing
        - Convolutional Smoothing with various window types (constant, hanning, hamming, bartlett, blackman)
        - Spectral Smoothing with Fourier Transform
        - Polynomial Smoothing 
        - Spline Smoothing of various kind (linear, cubic, natural cubic) 
        - Gaussian Smoothing 
        - Binner Smoothing 
        - LOWESS 
        - Seasonal Decompose Smoothing of various kind (convolution, lowess, natural cubic spline)
        - Kalman Smoothing with customizable components (level, trend, seasonality, long seasonality) 
        
        tsmoothie provides the calculation of intervals as result of the smoothing process. This can be useful to identify outliers and anomalies in time-series.
        
        In relation to the smoothing method used, the interval types available are:
        
        - sigma intervals
        - confidence intervals
        - predictions intervals
        - kalman intervals
        
        tsmoothie can carry out a sliding smoothing approach to simulate an online usage. This is possible splitting the time-series into equal sized pieces and smoothing them independently. As always, this functionality is implemented in a vectorized way through the **WindowWrapper** class.
        
        tsmoothie can operate time-series bootstrap through the **BootstrappingWrapper** class.
        
        The supported bootstrap algorithms are:
        
        - none overlapping block bootstrap
        - moving block bootstrap
        - circular block bootstrap
        - stationary bootstrap
        
        ## Media
        
        Blog Posts:
        
        - [Time Series Smoothing for better Clustering](https://towardsdatascience.com/time-series-smoothing-for-better-clustering-121b98f308e8)
        - [Time Series Smoothing for better Forecasting](https://towardsdatascience.com/time-series-smoothing-for-better-forecasting-7fbf10428b2)
        - [Real-Time Time Series Anomaly Detection](https://towardsdatascience.com/real-time-time-series-anomaly-detection-981cf1e1ca13)
        - [Extreme Event Time Series Preprocessing](https://towardsdatascience.com/extreme-event-time-series-preprocessing-90aa59d5630c)
        - [Time Series Bootstrap in the age of Deep Learning](https://towardsdatascience.com/time-series-bootstrap-in-the-age-of-deep-learning-b98aa2aa32c4)
        
        ## Installation
        
        ```shell
        pip install tsmoothie
        ```
        
        The module depends only on NumPy, SciPy and simdkalman. Python 3.6 or above is supported.
        
        ## Usage: _smoothing_
        
        Below a couple of examples of how tsmoothie works. Full examples are available in the [notebooks folder](https://github.com/cerlymarco/tsmoothie/tree/master/notebooks).
        
        ```python
        # import libraries
        import numpy as np
        import matplotlib.pyplot as plt
        from tsmoothie.utils_func import sim_randomwalk
        from tsmoothie.smoother import LowessSmoother
        
        # generate 3 randomwalks of lenght 200
        np.random.seed(123)
        data = sim_randomwalk(n_series=3, timesteps=200, 
                              process_noise=10, measure_noise=30)
        
        # operate smoothing
        smoother = LowessSmoother(smooth_fraction=0.1, iterations=1)
        smoother.smooth(data)
        
        # generate intervals
        low, up = smoother.get_intervals('prediction_interval')
        
        # plot the smoothed timeseries with intervals
        plt.figure(figsize=(18,5))
        
        for i in range(3):
            
            plt.subplot(1,3,i+1)
            plt.plot(smoother.smooth_data[i], linewidth=3, color='blue')
            plt.plot(smoother.data[i], '.k')
            plt.title(f"timeseries {i+1}"); plt.xlabel('time')
        
            plt.fill_between(range(len(smoother.data[i])), low[i], up[i], alpha=0.3)
        ```
        
        ![Randomwalk Smoothing](https://raw.githubusercontent.com/cerlymarco/tsmoothie/master/imgs/randomwalk_smoothing.png)
        
        ```python
        # import libraries
        import numpy as np
        import matplotlib.pyplot as plt
        from tsmoothie.utils_func import sim_seasonal_data
        from tsmoothie.smoother import DecomposeSmoother
        
        # generate 3 periodic timeseries of lenght 300
        np.random.seed(123)
        data = sim_seasonal_data(n_series=3, timesteps=300, 
                                 freq=24, measure_noise=30)
        
        # operate smoothing
        smoother = DecomposeSmoother(smooth_type='lowess', periods=24,
                                     smooth_fraction=0.3)
        smoother.smooth(data)
        
        # generate intervals
        low, up = smoother.get_intervals('sigma_interval')
        
        # plot the smoothed timeseries with intervals
        plt.figure(figsize=(18,5))
        
        for i in range(3):
            
            plt.subplot(1,3,i+1)
            plt.plot(smoother.smooth_data[i], linewidth=3, color='blue')
            plt.plot(smoother.data[i], '.k')
            plt.title(f"timeseries {i+1}"); plt.xlabel('time')
        
            plt.fill_between(range(len(smoother.data[i])), low[i], up[i], alpha=0.3)
        ```
        
        ![Sinusoidal Smoothing](https://raw.githubusercontent.com/cerlymarco/tsmoothie/master/imgs/sinusoidal_smoothing.png)
        
        ## Usage: _bootstrap_
        
        ```python
        # import libraries
        import numpy as np
        import matplotlib.pyplot as plt
        from tsmoothie.utils_func import sim_seasonal_data
        from tsmoothie.smoother import ConvolutionSmoother
        from tsmoothie.bootstrap import BootstrappingWrapper
        
        # generate a periodic timeseries of lenght 300
        np.random.seed(123)
        data = sim_seasonal_data(n_series=1, timesteps=300, 
                                 freq=24, measure_noise=15)
        
        # operate bootstrap
        bts = BootstrappingWrapper(ConvolutionSmoother(window_len=8, window_type='ones'), 
                                   bootstrap_type='mbb', block_length=24)
        bts_samples = bts.sample(data, n_samples=100)
        
        # plot the bootstrapped timeseries
        plt.figure(figsize=(13,5))
        plt.plot(bts_samples.T, alpha=0.3, c='orange')
        plt.plot(data[0], c='blue', linewidth=2)
        ```
        
        ![Sinusoidal Bootstrap](https://raw.githubusercontent.com/cerlymarco/tsmoothie/master/imgs/sinusoidal_bootstrap.png)
        
        ## References
        
        - Polynomial, Spline, Gaussian and Binner smoothing are carried out building a regression on custom basis expansions. These implementations are based on the amazing intuitions of Matthew Drury available [here](https://github.com/madrury/basis-expansions/blob/master/examples/comparison-of-smoothing-methods.ipynb)
        - Time Series Modelling with Unobserved Components, Matteo M. Pelagatti
        - Bootstrap Methods in Time Series Analysis, Fanny BergstrÃ¶m, Stockholms universitet
        
Platform: UNKNOWN
Requires-Python: >=3
Description-Content-Type: text/markdown
