pyFTS.models.nonstationary package

Submodules

pyFTS.models.nonstationary.common module

Non Stationary Fuzzy Sets

GARIBALDI, Jonathan M.; JAROSZEWSKI, Marcin; MUSIKASUWAN, Salang. Nonstationary fuzzy sets. IEEE Transactions on Fuzzy Systems, v. 16, n. 4, p. 1072-1086, 2008.

class pyFTS.models.nonstationary.common.FuzzySet(name, mf, parameters, **kwargs)[source]

Bases: pyFTS.common.FuzzySet.FuzzySet

Non Stationary Fuzzy Sets

get_lower(t)[source]
get_midpoint(t)[source]
get_upper(t)[source]
location = None

Pertubation function that affects the location of the membership function

location_params = None

Parameters for location pertubation function

membership(x, t)[source]

Calculate the membership value of a given input

Parameters:
  • x – input value
  • t – time displacement or perturbation parameters
Returns:

membership value of x at this fuzzy set

noise = None

Pertubation function that adds noise on the membership function

noise_params = None

Parameters for noise pertubation function

perform_location(t, param)[source]
perform_width(t, param)[source]
perturbate_parameters(t)[source]
width = None

Pertubation function that affects the width of the membership function

width_params = None

Parameters for width pertubation function

pyFTS.models.nonstationary.common.check_bounds(data, partitioner, t)[source]
pyFTS.models.nonstationary.common.check_bounds_index(data, partitioner, t)[source]
pyFTS.models.nonstationary.common.fuzzify(inst, t, fuzzySets)[source]

Calculate the membership values for a data point given nonstationary fuzzy sets

Parameters:
  • inst – data points
  • t – time displacement of the instance
  • fuzzySets – list of fuzzy sets
Returns:

array of membership values

pyFTS.models.nonstationary.common.fuzzySeries(data, fuzzySets, ordered_sets, window_size=1, method='fuzzy', const_t=None)[source]
pyFTS.models.nonstationary.common.window_index(t, window_size)[source]

pyFTS.models.nonstationary.cvfts module

class pyFTS.models.nonstationary.cvfts.ConditionalVarianceFTS(**kwargs)[source]

Bases: pyFTS.models.hofts.HighOrderFTS

forecast(ndata, **kwargs)[source]

Point forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted values

forecast_interval(ndata, **kwargs)[source]

Interval forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted intervals

generate_flrg(flrs, **kwargs)[source]
perturbation_factors(data, **kwargs)[source]
perturbation_factors__old(data)[source]
train(ndata, **kwargs)[source]

Method specific parameter fitting

Parameters:
  • data – training time series data
  • kwargs – Method specific parameters
class pyFTS.models.nonstationary.cvfts.HighOrderNonstationaryFLRG(order, **kwargs)[source]

Bases: pyFTS.models.hofts.HighOrderFTS

Conventional High Order Fuzzy Logical Relationship Group

append_lhs(c)[source]
append_rhs(c, **kwargs)[source]

pyFTS.models.nonstationary.flrg module

class pyFTS.models.nonstationary.flrg.NonStationaryFLRG(LHS, **kwargs)[source]

Bases: pyFTS.common.flrg.FLRG

get_key()[source]

Returns a unique identifier for this FLRG

get_lower(*args)[source]

Returns the lower bound value for the RHS fuzzy sets

Parameters:sets – fuzzy sets
Returns:lower bound value
get_membership(data, *args)[source]

Returns the membership value of the FLRG for the input data

Parameters:
  • data – input data
  • sets – fuzzy sets
Returns:

the membership value

get_midpoint(*args)[source]

Returns the midpoint value for the RHS fuzzy sets

Parameters:sets – fuzzy sets
Returns:the midpoint value
get_upper(*args)[source]

Returns the upper bound value for the RHS fuzzy sets

Parameters:sets – fuzzy sets
Returns:upper bound value
unpack_args(*args)[source]

pyFTS.models.nonstationary.honsfts module

class pyFTS.models.nonstationary.honsfts.HighOrderNonStationaryFLRG(order, **kwargs)[source]

Bases: pyFTS.models.nonstationary.flrg.NonStationaryFLRG

First Order NonStationary Fuzzy Logical Relationship Group

append_lhs(c)[source]
append_rhs(c, **kwargs)[source]
class pyFTS.models.nonstationary.honsfts.HighOrderNonStationaryFTS(name, **kwargs)[source]

Bases: pyFTS.models.hofts.HighOrderFTS

NonStationaryFTS Fuzzy Time Series

forecast(ndata, **kwargs)[source]

Point forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted values

forecast_interval(ndata, **kwargs)[source]

Interval forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted intervals

generate_flrg(data, **kwargs)[source]
train(data, **kwargs)[source]

Method specific parameter fitting

Parameters:
  • data – training time series data
  • kwargs – Method specific parameters

pyFTS.models.nonstationary.nsfts module

class pyFTS.models.nonstationary.nsfts.ConventionalNonStationaryFLRG(LHS, **kwargs)[source]

Bases: pyFTS.models.nonstationary.flrg.NonStationaryFLRG

First Order NonStationary Fuzzy Logical Relationship Group

append_rhs(c, **kwargs)[source]
get_key()[source]

Returns a unique identifier for this FLRG

class pyFTS.models.nonstationary.nsfts.NonStationaryFTS(**kwargs)[source]

Bases: pyFTS.common.fts.FTS

NonStationaryFTS Fuzzy Time Series

conditional_perturbation_factors(data, **kwargs)[source]
forecast(ndata, **kwargs)[source]

Point forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted values

forecast_interval(ndata, **kwargs)[source]

Interval forecast one step ahead

Parameters:
  • data – time series data with the minimal length equal to the max_lag of the model
  • kwargs – model specific parameters
Returns:

a list with the forecasted intervals

generate_flrg(flrs, **kwargs)[source]
train(data, **kwargs)[source]

Method specific parameter fitting

Parameters:
  • data – training time series data
  • kwargs – Method specific parameters

pyFTS.models.nonstationary.partitioners module

class pyFTS.models.nonstationary.partitioners.PolynomialNonStationaryPartitioner(data, part, **kwargs)[source]

Bases: pyFTS.partitioners.partitioner.Partitioner

Non Stationary Universe of Discourse Partitioner

build(data)[source]

Perform the partitioning of the Universe of Discourse

Parameters:data – training data
Returns:
get_polynomial_perturbations(data, **kwargs)[source]
poly_width(par1, par2, rng, deg)[source]
scale_down(x, pct)[source]
scale_up(x, pct)[source]
class pyFTS.models.nonstationary.partitioners.SimpleNonStationaryPartitioner(data, part, **kwargs)[source]

Bases: pyFTS.partitioners.partitioner.Partitioner

Non Stationary Universe of Discourse Partitioner

build(data)[source]

Perform the partitioning of the Universe of Discourse

Parameters:data – training data
Returns:
pyFTS.models.nonstationary.partitioners.simplenonstationary_gridpartitioner_builder(data, npart, transformation)[source]

pyFTS.models.nonstationary.perturbation module

Pertubation functions for Non Stationary Fuzzy Sets

pyFTS.models.nonstationary.perturbation.exponential(x, parameters)[source]
pyFTS.models.nonstationary.perturbation.linear(x, parameters)[source]
pyFTS.models.nonstationary.perturbation.periodic(x, parameters)[source]
pyFTS.models.nonstationary.perturbation.polynomial(x, parameters)[source]

pyFTS.models.nonstationary.util module

pyFTS.models.nonstationary.util.plot_sets(partitioner, start=0, end=10, step=1, tam=[5, 5], colors=None, save=False, file=None, axes=None, data=None, window_size=1, only_lines=False)[source]
pyFTS.models.nonstationary.util.plot_sets_conditional(model, data, step=1, size=[5, 5], colors=None, save=False, file=None, axes=None)[source]

Module contents

Fuzzy time series with nonstationary fuzzy sets, for heteroskedastic data