Source code for pyFTS.common.flrg

import numpy as np



[docs]class FLRG(object):
    """
    Fuzzy Logical Relationship Group

    Group a set of FLR's with the same LHS. Represents the temporal patterns for time t+1 (the RHS fuzzy sets)
    when the LHS pattern is identified on time t.
    """

    def __init__(self, order, **kwargs):
        self.LHS = None
        """Left Hand Side of the rule"""
        self.RHS = None
        """Right Hand Side of the rule"""
        self.order = order
        """Number of lags on LHS"""
        self.midpoint = None
        self.lower = None
        self.upper = None
        self.key = None


[docs]    def append_rhs(self, set, **kwargs):
        pass



[docs]    def get_key(self):
        """Returns a unique identifier for this FLRG"""
        if self.key is None:
            if isinstance(self.LHS, (list, set)):
                names = [c for c in self.LHS]
            elif isinstance(self.LHS, dict):
                names = [self.LHS[k] for k in self.LHS.keys()]
            else:
                names = [self.LHS]

            self.key = ""

            for n in names:
                if len(self.key) > 0:
                    self.key += ","
                self.key += n
        return self.key



[docs]    def get_membership(self, data, sets):
        """
        Returns the membership value of the FLRG for the input data

        :param data: input data
        :param sets: fuzzy sets
        :return: the membership value
        """
        ret = 0.0
        if isinstance(self.LHS, (list, set)):
            if len(self.LHS) == len(data):
                ret = np.nanmin([sets[self.LHS[ct]].membership(dat) for ct, dat in enumerate(data)])
        else:
            ret = sets[self.LHS].membership(data)
        return ret



[docs]    def get_midpoint(self, sets):
        """
        Returns the midpoint value for the RHS fuzzy sets

        :param sets: fuzzy sets
        :return: the midpoint value
        """
        if self.midpoint is None:
            self.midpoint = np.nanmean(self.get_midpoints(sets))
        return self.midpoint



[docs]    def get_midpoints(self, sets):
        if isinstance(self.RHS, (list, set)):
            return np.array([sets[s].centroid for s in self.RHS])
        elif isinstance(self.RHS, dict):
            return np.array([sets[s].centroid for s in self.RHS.keys()])



[docs]    def get_lower(self, sets):
        """
        Returns the lower bound value for the RHS fuzzy sets

        :param sets: fuzzy sets
        :return: lower bound value
        """
        if self.lower is None:
            if isinstance(self.RHS, list):
                self.lower = min([sets[rhs].lower for rhs in self.RHS])
            elif isinstance(self.RHS, dict):
                self.lower = min([sets[self.RHS[s]].lower for s in self.RHS.keys()])
        return self.lower



[docs]    def get_upper(self, sets):
        """
        Returns the upper bound value for the RHS fuzzy sets

        :param sets: fuzzy sets
        :return: upper bound value
        """
        if self.upper is None:
            if isinstance(self.RHS, list):
                self.upper = max([sets[rhs].upper for rhs in self.RHS])
            elif isinstance(self.RHS, dict):
                self.upper = max([sets[self.RHS[s]].upper for s in self.RHS.keys()])
        return self.upper


    def __len__(self):
        return len(self.RHS)


[docs]    def reset_calculated_values(self):
        self.midpoint = None
        self.upper = None
        self.lower = None