Beispiel #1
0
    def __init_jeffreys(self, A, B):
        """Calculate jeffreys prior as defined in Sivia p.125"""
        self.kind = 'jeffreys'
        A = interpret_quantity(A, expect_sequence=False)
        B = interpret_quantity(B, expect_sequence=False)
        assert A.dimensionality == B.dimensionality
        self._state_attrs.extend(['A', 'B'])
        self.units = str(A.units)
        B = B.to(A.units)
        self.A = A
        self.B = B

        def llh(x):
            x = self.__strip(self.__convert(x))
            A = self.__strip(self.A)
            B = self.__strip(self.B)
            return -np.log(x) + np.log(np.log(B) - np.log(A))

        self.llh = llh
        self.max_at = self.A
        self.max_at_str = self.__stringify(self.max_at)
        self.valid_range = (self.A * ureg(self.units),
                            self.B * ureg(self.units))
        self._str = lambda s: "jeffreys' prior, range [%s,%s]" % (self.A, self.
                                                                  B)
Beispiel #2
0
    def __init_gaussian(self, mean, stddev):
        mean = interpret_quantity(mean, expect_sequence=False)
        stddev = interpret_quantity(stddev, expect_sequence=False)
        assert mean.dimensionality == stddev.dimensionality
        self._state_attrs.extend(['mean', 'stddev'])
        self.kind = 'gaussian'
        if isinstance(mean, ureg.Quantity):
            self.units = str(mean.units)
            assert isinstance(stddev, ureg.Quantity), \
                    str(type(stddev))
            stddev = stddev.to(self.units)
        self.mean = mean
        self.stddev = stddev

        def llh(x):
            x = self.__strip(self.__convert(x))
            m = self.__strip(self.mean)
            s = self.__strip(self.stddev)
            return -(x - m)**2 / (2 * s**2)

        self.llh = llh
        self.max_at = self.mean
        self.max_at_str = self.__stringify(self.max_at)
        self.valid_range = (-np.inf * ureg(self.units),
                            np.inf * ureg(self.units))
        self._str = lambda s: 'gaussian prior: stddev=%s%s, maximum at %s%s' \
                %(self.__stringify(self.stddev), self.units_str,
                  self.__stringify(self.mean), self.units_str)
Beispiel #3
0
    def __init_linterp(self, param_vals, llh_vals):
        param_vals = interpret_quantity(param_vals, expect_sequence=True)
        self._state_attrs.extend(['param_vals', 'llh_vals'])
        self.kind = 'linterp'
        if isinstance(param_vals, ureg.Quantity):
            self.units = str(param_vals.units)
        self.interp = interp1d(param_vals.magnitude,
                               llh_vals,
                               kind='linear',
                               copy=True,
                               bounds_error=True,
                               assume_sorted=False)
        self.param_vals = param_vals
        self.llh_vals = llh_vals

        def llh(x):
            x = self.__strip(self.__convert(x))
            return self.interp(x)

        self.llh = llh
        self.max_at = self.param_vals[self.llh_vals == np.max(self.llh_vals)]
        self.max_at_str = ', '.join([self.__stringify(v) for v in self.max_at])
        self.valid_range = (np.min(self.param_vals) * ureg(self.units),
                            np.max(self.param_vals) * ureg(self.units))
        self._str = lambda s: 'linearly-interpolated prior: valid in [%s, %s]%s, maxima at (%s)%s' \
                %(self.__stringify(np.min(self.param_vals)),
                  self.__stringify(np.max(self.param_vals)), self.units_str,
                  self.max_at_str, self.units_str)
Beispiel #4
0
    def __init_spline(self, knots, coeffs, deg, units=None):
        knots = interpret_quantity(knots, expect_sequence=True)
        self._state_attrs.extend(['knots', 'coeffs', 'deg'])
        self.kind = 'spline'
        if isunitless(knots):
            knots = ureg.Quantity(knots, units)
        elif units is not None:
            units = ureg.Unit(units)
            assert knots.dimensionality == units.dimensionality
            knots = knots.to(units)

        self.units = str(knots.units)

        self.knots = knots
        self.coeffs = coeffs
        self.deg = deg
        def llh(x):
            x = self.__strip(self.__convert(x))
            return splev(x, tck=(self.__strip(self.knots), coeffs, deg), ext=2)
        self.llh = llh
        self.max_at = fminbound(
            func=self.__attach_units_to_args(self.chi2),
            x1=np.min(self.__strip(self.knots)),
            x2=np.max(self.__strip(self.knots)),
        )
        if self.units is not None:
            self.max_at = self.max_at * ureg(self.units)
        self.max_at_str = self.__stringify(self.max_at)
        self.valid_range = (np.min(self.knots) * ureg(self.units),
                            np.max(self.knots) * ureg(self.units))
        self._str = lambda s: 'spline prior: deg=%d, valid in [%s, %s]%s; max at %s%s' \
                %(self.deg, self.__stringify(np.min(self.knots)),
                  self.__stringify(np.max(self.knots)), self.units_str,
                  self.max_at_str, self.units_str)