`abs_energy` (x) |
Returns the absolute energy of the time series which is the sum over the squared values |

`absolute_sum_of_changes` (x) |
Returns the sum over the absolute value of consecutive changes in the series x |

`agg_autocorrelation` (x, param) |
Calculates the value of an aggregation function (e.g. |

`agg_linear_trend` (x, param) |
Calculates a linear least-squares regression for values of the time series that were aggregated over chunks versus the sequence from 0 up to the number of chunks minus one. |

`approximate_entropy` (x, m, r) |
Implements a vectorized Approximate entropy algorithm. |

`ar_coefficient` (x, param) |
This feature calculator fits the unconditional maximum likelihood of an autoregressive AR(k) process. |

`augmented_dickey_fuller` (x, param) |
The Augmented Dickey-Fuller test is a hypothesis test which checks whether a unit root is present in a time series sample. |

`autocorrelation` (x, lag) |
Calculates the autocorrelation of the specified lag, according to the formula [1] |

`benford_correlation` (x) |
Useful for anomaly detection applications [1][2]. |

`binned_entropy` (x, max_bins) |
First bins the values of x into max_bins equidistant bins. |

`c3` (x, lag) |
This function calculates the value of |

`change_quantiles` (x, ql, qh, isabs, f_agg) |
First fixes a corridor given by the quantiles ql and qh of the distribution of x. |

`cid_ce` (x, normalize) |
This function calculator is an estimate for a time series complexity [1] (A more complex time series has more peaks, valleys etc.). |

`count_above` (x, t) |
Returns the percentage of values in x that are higher than t |

`count_above_mean` (x) |
Returns the number of values in x that are higher than the mean of x |

`count_below` (x, t) |
Returns the percentage of values in x that are lower than t |

`count_below_mean` (x) |
Returns the number of values in x that are lower than the mean of x |

`cwt_coefficients` (x, param) |
Calculates a Continuous wavelet transform for the Ricker wavelet, also known as the “Mexican hat wavelet” which is |

`energy_ratio_by_chunks` (x, param) |
Calculates the sum of squares of chunk i out of N chunks expressed as a ratio with the sum of squares over the whole series. |

`fft_aggregated` (x, param) |
Returns the spectral centroid (mean), variance, skew, and kurtosis of the absolute fourier transform spectrum. |

`fft_coefficient` (x, param) |
Calculates the fourier coefficients of the one-dimensional discrete Fourier Transform for real input by fast |

`first_location_of_maximum` (x) |
Returns the first location of the maximum value of x. |

`first_location_of_minimum` (x) |
Returns the first location of the minimal value of x. |

`fourier_entropy` (x, bins) |
Calculate the binned entropy of the power spectral density of the time series (using the welch method). |

`friedrich_coefficients` (x, param) |
Coefficients of polynomial , which has been fitted to |

`has_duplicate` (x) |
Checks if any value in x occurs more than once |

`has_duplicate_max` (x) |
Checks if the maximum value of x is observed more than once |

`has_duplicate_min` (x) |
Checks if the minimal value of x is observed more than once |

`index_mass_quantile` (x, param) |
Those apply features calculate the relative index i where q% of the mass of the time series x lie left of i. |

`kurtosis` (x) |
Returns the kurtosis of x (calculated with the adjusted Fisher-Pearson standardized moment coefficient G2). |

`large_standard_deviation` (x, r) |
Boolean variable denoting if the standard dev of x is higher than ‘r’ times the range = difference between max and min of x. |

`last_location_of_maximum` (x) |
Returns the relative last location of the maximum value of x. |

`last_location_of_minimum` (x) |
Returns the last location of the minimal value of x. |

`lempel_ziv_complexity` (x, bins) |
Calculate a complexity estimate based on the Lempel-Ziv compression algorithm. |

`length` (x) |
Returns the length of x |

`linear_trend` (x, param) |
Calculate a linear least-squares regression for the values of the time series versus the sequence from 0 to length of the time series minus one. |

`linear_trend_timewise` (x, param) |
Calculate a linear least-squares regression for the values of the time series versus the sequence from 0 to length of the time series minus one. |

`longest_strike_above_mean` (x) |
Returns the length of the longest consecutive subsequence in x that is bigger than the mean of x |

`longest_strike_below_mean` (x) |
Returns the length of the longest consecutive subsequence in x that is smaller than the mean of x |

`max_langevin_fixed_point` (x, r, m) |
Largest fixed point of dynamics :math:argmax_x {h(x)=0}` estimated from polynomial , |

`maximum` (x) |
Calculates the highest value of the time series x. |

`mean` (x) |
Returns the mean of x |

`mean_abs_change` (x) |
Returns the mean over the absolute differences between subsequent time series values which is |

`mean_change` (x) |
Returns the mean over the differences between subsequent time series values which is |

`mean_second_derivative_central` (x) |
Returns the mean value of a central approximation of the second derivative |

`median` (x) |
Returns the median of x |

`minimum` (x) |
Calculates the lowest value of the time series x. |

`number_crossing_m` (x, m) |
Calculates the number of crossings of x on m. |

`number_cwt_peaks` (x, n) |
This feature calculator searches for different peaks in x. |

`number_peaks` (x, n) |
Calculates the number of peaks of at least support n in the time series x. |

`partial_autocorrelation` (x, param) |
Calculates the value of the partial autocorrelation function at the given lag. |

`percentage_of_reoccurring_datapoints_to_all_datapoints` (x) |
Returns the percentage of non-unique data points. |

`percentage_of_reoccurring_values_to_all_values` (x) |
Returns the percentage of values that are present in the time series more than once. |

`permutation_entropy` (x, tau, dimension) |
Calculate the permutation entropy. |

`quantile` (x, q) |
Calculates the q quantile of x. |

`range_count` (x, min, max) |
Count observed values within the interval [min, max). |

`ratio_beyond_r_sigma` (x, r) |
Ratio of values that are more than r*std(x) (so r sigma) away from the mean of x. |

`ratio_value_number_to_time_series_length` (x) |
Returns a factor which is 1 if all values in the time series occur only once, and below one if this is not the case. |

`sample_entropy` (x) |
Calculate and return sample entropy of x. |

`set_property` (key, value) |
This method returns a decorator that sets the property key of the function to value |

`skewness` (x) |
Returns the sample skewness of x (calculated with the adjusted Fisher-Pearson standardized moment coefficient G1). |

`spkt_welch_density` (x, param) |
This feature calculator estimates the cross power spectral density of the time series x at different frequencies. |

`standard_deviation` (x) |
Returns the standard deviation of x |

`sum_of_reoccurring_data_points` (x) |
Returns the sum of all data points, that are present in the time series more than once. |

`sum_of_reoccurring_values` (x) |
Returns the sum of all values, that are present in the time series more than once. |

`sum_values` (x) |
Calculates the sum over the time series values |

`symmetry_looking` (x, param) |
Boolean variable denoting if the distribution of x looks symmetric. |

`time_reversal_asymmetry_statistic` (x, lag) |
This function calculates the value of |

`value_count` (x, value) |
Count occurrences of value in time series x. |

`variance` (x) |
Returns the variance of x |

`variance_larger_than_standard_deviation` (x) |
Boolean variable denoting if the variance of x is greater than its standard deviation. |

`variation_coefficient` (x) |
Returns the variation coefficient (standard error / mean, give relative value of variation around mean) of x. |