def diag_likelihood(self, N, p00, p01, p10):
"""
returns the value of the likelihood function, which is given by
a multinomial PDF (results being now parameters and the probabilities
the variables) multiplied by the readout error.
p11 is given by 1-p00-p01-p10.
"""
N = N.astype(int)
perr00, perr01, perr10, perr11 = self._apply_readout_error(
p00, p01, p10, 1. - p00 - p01 - p10)
lk = fac(N.sum(), exact=self.fac_exact) / \
(fac(N[0],exact=self.fac_exact) * \
fac(N[1],exact=self.fac_exact) * \
fac(N[2],exact=self.fac_exact) * \
fac(N[3],exact=self.fac_exact)) * \
perr00**N[0] * perr01**N[1] * perr10**N[2] * \
(1.-perr00-perr01-perr10)**N[3]
if type(p00) == np.ndarray:
lk[p00 + p01 + p10 > 1] = 0.
lk[p00 < 0] = 0
lk[p01 < 0] = 0
lk[p10 < 0] = 0
elif p00 + p01 + p10 > 1. or p00 < 0 or p01 < 0 or p10 < 0:
return 0
return lk
def offdiag_likelihood(self, N, a, b):
"""
the probabilities for the XX measurement have some constraints, and are
in the end described by the parameters a and b (see lab book)
"""
N = N.astype(int)
perr00,perr01,perr10,perr11 = self._apply_readout_error(
.25+a-b,
.25-a-b,
.25-a+b,
.25+a+b)
lk = fac(N.sum(), exact=self.fac_exact) / \
(fac(N[0],exact=self.fac_exact) * \
fac(N[1],exact=self.fac_exact) * \
fac(N[2],exact=self.fac_exact) * \
fac(N[3],exact=self.fac_exact)) * \
perr00**N[0] * perr01**N[1] * perr10**N[2] * \
(1.-perr00-perr01-perr10)**N[3]
if type(a) == np.ndarray:
lk[abs(b) > .25-abs(a)] = 0.
elif abs(b) > .25-abs(a):
return 0
return lk
def P0(l): #Find the integral of P0l
if l % 2 == 0: return 0
Sum = 0
for q in range(ceil(l / 2), l + 1):
Sum += fac(2 * q) * fac2(2 * q - l - 1) / fac(
(l - q) * fac(q) * fac(2 * q - l) * fac2(2 * q - l))
return 1 / (2**l) * Sum
def zer_coeff(n, m):
coeffs, pows = [], []
for s in range((n - m) / 2 + 1):
coeffs.append((-1.0)**s * fac(n-s) / \
(fac(s) * fac((n+m)/2.0 - s) * fac((n-m)/2.0 - s)))
pows.append(n - 2.0 * s)
return coeffs, pows
def radialPoly(rho, n,m):
rp = 0
m=np.abs(m)
if is_odd(n-m):
rp = 0
else:
for k in range(0,(n-m)/2):
rp += (-1.0)**k * fac(n-k) * rho**(n-2.0*k) / (np.math.factorial(k) * fac((n+m)/2.0 - k) * fac((n-m)/2.0 - k))
return rp
def zernike_rad(l, n, r):
res = np.zeros(r.shape)
if (n - l) % 2:
return res
for i in xrange((n - l) / 2 + 1):
res += (
r ** (n - 2.0 * i) * (-1.0) ** i * fac(n - i) / (fac(i) * fac((n + l) / 2.0 - i) * fac((n - l) / 2.0 - i))
)
return res
def R(m, n, rad, orig, Nx):
''' n>=m, n-m even '''
rho = getrho(rad, orig, Nx)
bigr = N.zeros((Nx, Nx), dtype=N.float32)
for s in range(1 + int((n - m) / 2)):
coeff = (-1)**s * fac(n - s) / (fac(s) * fac((n + m) / 2 - s) *
fac((n - m) / 2 - s))
bigr = bigr + coeff * rho**(n - 2 * s)
bigr = bigr * (rho <= 1.0)
return bigr
def zernike_rad(m, n, rho):
"""radial component of zernike (m,n), given radial coordinates rho"""
wf = np.zeros(rho.shape) # grid of radial coords
if (np.mod(n - m, 2) == 1):
return rho * 0.0
for k in range((n - m) / 2 + 1):
wf += rho**(n-(2.0*k)) * ((-1.0)**k) * fac(n-k) / \
( fac(k) * fac( (n+m)/2.0 - k ) * \
fac( (n-m)/2.0 - k ) )
return wf
def zernike_rad(m, n, rho):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
"""
if (n < 0 or m < 0 or abs(m) > n):
raise ValueError
if ((n-m) % 2):
return rho*0.0
pre_fac = lambda k: (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return sum(pre_fac(k) * rho**(n-2.0*k) for k in xrange((n-m)/2+1))
def zernike_rad(self, rho):
n=abs(self.n)
m=abs(self.m)
if (numpy.mod(n-m, 2) == 1):
return rho*0.0
wf = rho*0.0
for k in range((n-m)/2+1):
wf += rho**(n-2.0*k) * (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return wf
def zernike_rad(m, n, rho):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
"""
wf = N.zeros(rho.shape)
if (n-m) % 2:
return wf
for k in xrange((n-m)/2+1):
wf += rho**(n-2.0*k) * (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return wf
def _radzernike(self, m, n, r):
"""
Calculate the radial part of the Zernike polynomials
"""
if (np.mod(n - m, 2) == 1):
return np.zeros_like(r)
wf = np.zeros_like(r)
for k in range((n - m) // 2 + 1):
wf += r**(n - 2.0 * k) * (-1.0)**k * fac(n - k) / (fac(k) * fac(
(n + m) / 2.0 - k) * fac((n - m) / 2.0 - k))
return wf
def zernike_rad(self, m, n, rho):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
"""
if (n < 0 or m < 0 or abs(m) > n):
raise ValueError
if ((n-m) % 2):
return rho*0.0
pre_fac = lambda k: (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return sum(pre_fac(k) * rho**(n-2.0*k) for k in xrange((n-m)/2+1))
def zernike_rad(m, n, rho):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
"""
wf = N.zeros(rho.shape)
if (n - m) % 2:
return wf
for k in xrange((n - m) / 2 + 1):
wf += rho**(n - 2.0 * k) * (-1.0)**k * fac(n - k) / (fac(k) * fac(
(n + m) / 2.0 - k) * fac((n - m) / 2.0 - k))
return wf
def differential(poly, diffvar):
"""
Polynomial differential operator.
Args:
poly (Poly) : Polynomial to be differentiated.
diffvar (Poly) : Polynomial to differentiate by. Must be decomposed. If
polynomial array, the output is the Jacobian matrix.
Examples:
>>> q0, q1 = chaospy.variable(2)
>>> poly = chaospy.Poly([1, q0, q0*q1**2+1])
>>> print(poly)
[1, q0, q0q1^2+1]
>>> print(differential(poly, q0))
[0, 1, q1^2]
>>> print(differential(poly, q1))
[0, 0, 2q0q1]
"""
poly = Poly(poly)
diffvar = Poly(diffvar)
if not chaospy.poly.caller.is_decomposed(diffvar):
sum(differential(poly, chaospy.poly.caller.decompose(diffvar)))
if diffvar.shape:
return Poly([differential(poly, pol) for pol in diffvar])
if diffvar.dim > poly.dim:
poly = chaospy.poly.dimension.setdim(poly, diffvar.dim)
else:
diffvar = chaospy.poly.dimension.setdim(diffvar, poly.dim)
qkey = diffvar.keys[0]
core = {}
for key in poly.keys:
newkey = np.array(key) - np.array(qkey)
if np.any(newkey < 0):
continue
newkey = tuple(newkey)
core[newkey] = poly.A[key] * np.prod([
fac(key[idx], exact=True) / fac(newkey[idx], exact=True)
for idx in range(poly.dim)
])
return Poly(core, poly.dim, poly.shape, poly.dtype)
def differential(poly, diffvar):
"""
Polynomial differential operator.
Args:
poly (Poly) : Polynomial to be differentiated.
diffvar (Poly) : Polynomial to differentiate by. Must be decomposed. If
polynomial array, the output is the Jacobian matrix.
Examples:
>>> q0, q1 = cp.variable(2)
>>> poly = cp.Poly([1, q0, q0*q1**2+1])
>>> print(poly)
[1, q0, q0q1^2+1]
>>> print(differential(poly, q0))
[0, 1, q1^2]
>>> print(differential(poly, q1))
[0, 0, 2q0q1]
"""
poly = Poly(poly)
diffvar = Poly(diffvar)
if not chaospy.poly.caller.is_decomposed(diffvar):
sum(differential(poly, chaospy.poly.caller.decompose(diffvar)))
if diffvar.shape:
return Poly([differential(poly, pol) for pol in diffvar])
if diffvar.dim > poly.dim:
poly = chaospy.poly.dimension.setdim(poly, diffvar.dim)
else:
diffvar = chaospy.poly.dimension.setdim(diffvar, poly.dim)
qkey = diffvar.keys[0]
core = {}
for key in poly.keys:
newkey = np.array(key) - np.array(qkey)
if np.any(newkey < 0):
continue
newkey = tuple(newkey)
core[newkey] = poly.A[key] * np.prod(
[fac(key[idx], exact=True) / fac(newkey[idx], exact=True)
for idx in range(poly.dim)])
return Poly(core, poly.dim, poly.shape, poly.dtype)
def get_mu(mu_t, L_t):
""" Computes mu_{t+1}
"""
coeffs = (1.0 / L_t) * np.array(
[pow(mu_t, i) / (fac(i)) for i in np.arange(d + 1)])
polys = np.array([get_moment(mu_t, i) for i in np.arange(d + 1)])
return kappa * sum(np.multiply(coeffs, polys))
def goodfunform(x, s, c0, c1, c2, c3, c4, c5, n, L, Alow, Aupp, lam):
numpeaks = 10
dx = x[1] - x[0]
cent = [c0, c1, c2, c3, c4, c5] + list(np.arange(1, 2 * numpeaks) + c5)
A1 = 1 - Alow - Aupp
norm = [
hnorm(m=value, A=np.array([A1, Alow, Aupp]), c=cent)
for value in range(1, numpeaks)
]
amp = np.array([
np.exp(-lam) * lam**(value) / fac(value) for value in range(numpeaks)
])
yvalues = [
hfit(x, value, np.array([A1, Alow, Aupp]), cent)
for value in range(1, numpeaks)
]
peakform = np.sum(
[yvalues[value - 1] * amp[value] for value in range(1, numpeaks)],
axis=0)
peakform = np.convolve(gaussian(np.arange(-2, 2, dx), 0, s), peakform,
'same')
peakform = peakform + np.sum([
gaussian(x, cent[value - 1], s) * amp[value] * A1**value /
norm[value - 1] for value in range(1, numpeaks)
],
axis=0)
return L * (peakform + amp[0] * gzero(x, c0, s, n))
def zernike_rad(m, n, rho):
"""
Make radial Zernike polynomial on coordinate grid **rho**.
@param [in] m Radial Zernike index
@param [in] n Azimuthal Zernike index
@param [in] rho Radial coordinate grid
@return Radial polynomial with identical shape as **rho**
"""
if (np.mod(n - m, 2) == 1):
return rho * 0.0
wf = rho * 0.0
for k in range((n - m) / 2 + 1):
wf += rho**(n-2.0*k) * (-1.0)**k * fac(n-k) / \
( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return wf
def zernike_rad(m, n, rho): """ Make radial Zernike polynomial on coordinate grid **rho**. @param [in] m Radial Zernike index @param [in] n Azimuthal Zernike index @param [in] rho Radial coordinate grid @return Radial polynomial with identical shape as **rho** """ if (np.mod(n-m, 2) == 1): return rho*0.0 wf = rho*0.0 for k in range((n-m)/2+1): wf += rho**(n-2.0*k) * (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) ) return wf
def zernike_rad(m, n, rho):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
"""
#Todo: This could be sped up A LOT by caching all this factorial stuff
if (n < 0 or m < 0 or abs(m) > n):
raise ValueError
if ((n - m) % 2):
return rho * 0.0
pre_fac = lambda k: (-1.0)**k * fac(n - k) / (fac(k) * fac(
(n + m) / 2.0 - k) * fac((n - m) / 2.0 - k))
return np.sum(
pre_fac(k) * rho**(n - 2.0 * k) for k in xrange((n - m) / 2 + 1))
def zernike_rad(rho, n,m):
"""
Calculate the radial component of Zernike polynomial (m, n)
given a grid of radial coordinates rho.
>>> zernike_rad(3, 3, 0.333)
0.036926037000000009
>>> zernike_rad(1, 3, 0.333)
-0.55522188900000002
>>> zernike_rad(3, 5, 0.12345)
-0.007382104685237683
"""
if (n < 0 or m < 0 or abs(m) > n):
raise ValueError
if ((n-m) % 2):
return rho*0.0
else:
pre_fac = lambda k: (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) )
return sum(pre_fac(k) * rho**(n-2.0*k) for k in xrange((n-m)/2+1))
def differential(P, Q):
"""Polynomial differential operator
Parameters
----------
P : Poly
Polynomial to be differentiated.
Q : Poly
Polynomial to differentiate by. Must be decomposed. If
polynomial array, the output is the Jacobian matrix.
"""
P, Q = Poly(P), Poly(Q)
if not is_decomposed(Q):
differential(decompose(Q)).sum(0)
if Q.shape:
return Poly([differential(P, q) for q in Q])
if Q.dim > P.dim:
P = setdim(P, Q.dim)
else:
Q = setdim(Q, P.dim)
qkey = Q.keys[0]
A = {}
for key in P.keys:
newkey = np.array(key) - np.array(qkey)
if np.any(newkey < 0):
continue
A[tuple(newkey)] = P.A[key]*np.prod([fac(key[i], \
exact=True)/fac(newkey[i], exact=True) \
for i in xrange(P.dim)])
return Poly(A, P.dim, None)
def differential(P, Q):
"""Polynomial differential operator
Parameters
----------
P : Poly
Polynomial to be differentiated.
Q : Poly
Polynomial to differentiate by. Must be decomposed. If
polynomial array, the output is the Jacobian matrix.
"""
P, Q = Poly(P), Poly(Q)
if not is_decomposed(Q):
differential(decompose(Q)).sum(0)
if Q.shape:
return Poly([differential(P, q) for q in Q])
if Q.dim > P.dim:
P = setdim(P, Q.dim)
else:
Q = setdim(Q, P.dim)
qkey = Q.keys[0]
A = {}
for key in P.keys:
newkey = np.array(key) - np.array(qkey)
if np.any(newkey < 0):
continue
A[tuple(newkey)] = P.A[key] * np.prod(
[fac(key[i], exact=True) / fac(newkey[i], exact=True) for i in xrange(P.dim)]
)
return Poly(A, P.dim, None)
def offdiag_likelihood(self, N, a, b):
"""
the probabilities for the XX measurement have some constraints, and are
in the end described by the parameters a and b (see lab book)
"""
N = N.astype(int)
perr00, perr01, perr10, perr11 = self._apply_readout_error(
.25 + a - b, .25 - a - b, .25 - a + b, .25 + a + b)
lk = fac(N.sum(), exact=self.fac_exact) / \
(fac(N[0],exact=self.fac_exact) * \
fac(N[1],exact=self.fac_exact) * \
fac(N[2],exact=self.fac_exact) * \
fac(N[3],exact=self.fac_exact)) * \
perr00**N[0] * perr01**N[1] * perr10**N[2] * \
(1.-perr00-perr01-perr10)**N[3]
if type(a) == np.ndarray:
lk[abs(b) > .25 - abs(a)] = 0.
elif abs(b) > .25 - abs(a):
return 0
return lk
def zernike_rad(m, n, rho): """ Calculate the radial component of Zernike polynomial (m, n) given a grid of radial coordinates rho. >>> zernike_rad(3, 3, 0.333) 0.036926037000000009 >>> zernike_rad(1, 3, 0.333) -0.55522188900000002 >>> zernike_rad(3, 5, 0.12345) -0.007382104685237683 """ if (n < 0 or m < 0 or abs(m) > n): raise ValueError if ((n-m) % 2): return rho*0.0 pre_fac = lambda k: (-1.0)**k * fac(n-k) / ( fac(k) * fac( (n+m)/2.0 - k ) * fac( (n-m)/2.0 - k ) ) return sum(pre_fac(k) * rho**(n-2.0*k) for k in xrange((n-m)/2+1))
def differential(P, Q):
"""
Polynomial differential operator.
Args:
P (Poly) : Polynomial to be differentiated.
Q (Poly) : Polynomial to differentiate by. Must be decomposed. If
polynomial array, the output is the Jacobian matrix.
"""
P, Q = Poly(P), Poly(Q)
if not chaospy.poly.is_decomposed(Q):
differential(chaospy.poly.decompose(Q)).sum(0)
if Q.shape:
return Poly([differential(P, q) for q in Q])
if Q.dim > P.dim:
P = chaospy.poly.setdim(P, Q.dim)
else:
Q = chaospy.poly.setdim(Q, P.dim)
qkey = Q.keys[0]
A = {}
for key in P.keys:
newkey = numpy.array(key) - numpy.array(qkey)
if numpy.any(newkey < 0):
continue
A[tuple(newkey)] = P.A[key]*numpy.prod([fac(key[i], \
exact=True)/fac(newkey[i], exact=True) \
for i in range(P.dim)])
return Poly(B, P.dim, P.shape, P.dtype)
def diag_likelihood(self, N, p00,p01,p10):
"""
returns the value of the likelihood function, which is given by
a multinomial PDF (results being now parameters and the probabilities
the variables) multiplied by the readout error.
p11 is given by 1-p00-p01-p10.
"""
N = N.astype(int)
perr00,perr01,perr10,perr11 = self._apply_readout_error(
p00,p01,p10,1.-p00-p01-p10)
lk = fac(N.sum(), exact=self.fac_exact) / \
(fac(N[0],exact=self.fac_exact) * \
fac(N[1],exact=self.fac_exact) * \
fac(N[2],exact=self.fac_exact) * \
fac(N[3],exact=self.fac_exact)) * \
perr00**N[0] * perr01**N[1] * perr10**N[2] * \
(1.-perr00-perr01-perr10)**N[3]
if type(p00) == np.ndarray:
lk[p00+p01+p10>1]=0.; lk[p00<0]=0; lk[p01<0]=0; lk[p10<0]=0
elif p00+p01+p10 > 1. or p00<0 or p01<0 or p10<0:
return 0
return lk
def poly(z, l):
""" Computes the sequence of polynomials from the algorithm.
Args:
z: np.array to be evaluated
l: Step Index
Returns:
The l-th Polynomial evaluated pointise on z
"""
if not l:
return np.ones(z.shape)
coeffs = (1.0 / L_list[l]) * np.array(
[pow(mu_list[l], k) / (fac(k)) for k in np.arange(d + 1)])
pows = np.arange(d + 1) * np.ones(z.shape + (d + 1, ))
polys = np.power(np.expand_dims(z, 2), pows)
return np.sum((coeffs * polys).T, 0).T
def get_L(mu_t, d):
""" Returns L_t.
"""
# ai = u_l^k / k!
# sum_{i+j is even}} ai aj (i+j-1)!!
a = np.array([pow(mu_t, k) / fac(k) for k in np.arange(d + 1)])
# compute all the moments up to 2*d
E = np.zeros(2 * d + 1)
for i in np.arange(d + 1):
E[2 * i] = fac2(2 * i - 1)
H = np.zeros((d + 1, d + 1))
for i in np.arange(d + 1):
for j in np.arange(d + 1):
H[i, j] = E[i + j]
L2 = np.dot(a, np.dot(H, a))
return math.sqrt(L2)
def Taylor(x, x0, n):
p = y0[0]
for i in range(1, n+1):
p += ((y0[i]) / (fac(i))) * (x-x0)**i
return p
def factorial(number):
return fac(number,True)
def Amijn(A, m, i, j, n):
A1, Alow, Aupp = A
numerator = (A1**i) * (Alow**j) * Aupp**(m - i - j) * (-1)**(m - i - n) * (
m - i) * fac(m)
denominator = fac(i) * fac(j) * fac(m - i - j) * fac(n) * fac(m - i - n)
return numerator / denominator
def Jb_spline(X,n=0):
"""Jb interpolated from a saved spline. Input is (m/T)^2."""
X = numpy.array(X, copy=False)
x = X.ravel()
y = interpolate.splev(x,_tckb, der=n).ravel()
y[x < _xbmin] = interpolate.splev(_xbmin,_tckb, der=n)
y[x > _xbmax] = 0
return y.reshape(X.shape)
# Now for the low x expansion (require that n <= 50)
a,b,c,d = -pi**4/45, pi*pi/12, -pi/6, -1/32.
logab = 1.5 - 2*euler_gamma + 2*log(4*pi)
l = numpy.arange(50)+1
g = (-2*pi**3.5 * (-1)**l*(1+special.zetac(2*l+1)) *
special.gamma(l+.5)/(fac(l+2)*(2*pi)**(2*l+4)))
lowCoef_b = (a,b,c,d,logab,l,g)
del (a,b,c,d,logab,l,g) # clean up name space
a,b,d = -7*pi**4/360, pi*pi/24, 1/32.
logaf = 1.5 - 2*euler_gamma + 2*log(pi)
l = numpy.arange(50)+1
g = (.25*pi**3.5 * (-1)**l*(1+special.zetac(2*l+1)) *
special.gamma(l+.5)*(1-.5**(2*l+1))/(fac(l+2)*pi**(2*l+4)))
lowCoef_f = (a,b,d,logaf,l,g)
del (a,b,d,logaf,l,g) # clean up name space
def Jb_low(x,n=20):
"""Jb calculated using the low-x (high-T) expansion."""
(a,b,c,d,logab,l,g) = lowCoef_b
def funform(x, s, c0, c1, c2, c3, c4, c5, n, L, Lbulk, Lsurf, Alow, Aupp, lam):
numpeaks = 5
cent = [c0, c1, c2, c3, c4, c5] + list(np.arange(1, 2 * numpeaks) + c5)
dx = x[1] - x[0]
A1 = 1 - Alow - Aupp
L0 = 1 - Lbulk - Lsurf
theta = np.heaviside
adx = np.sum((cent[0] <= x) & (x < cent[1]))
# Amplitudes of the Gaussian
amp = [
np.exp(-lam) * lam**(value) / fac(value) for value in range(numpeaks)
]
L = L / sum(
amp
) # removes artifact of missing counts by redistributing evenly over all other energies
# Events that 'pile-up' with a 0 event:
yvalues = [
hfit(x, value, np.array([A1, Alow, Aupp]), cent)
for value in range(1, numpeaks)
]
peakform = L0 * np.sum(
[yvalues[value - 1] * amp[value] for value in range(1, numpeaks)],
axis=0)
#one = np.sum(peakform, axis = 0)/L0
#print('One', np.sum(peakform, axis = 0), one*L0)
# Events that 'Pile-up' with a surface event:
yvalues = [
hfit(x - cent[0], value, np.array([A1, Alow, Aupp]), cent)
for value in range(1, numpeaks)
]
peakform = peakform + Lsurf * np.sum(
[yvalues[value - 1] * amp[value] for value in range(1, numpeaks)],
axis=0)
#print('Two', np.sum(peakform, axis = 0), one*(L0 + Lsurf))
# Events that 'Pile-up' with a bulk event:
yvalues = np.zeros(x.size)
for value in range(1, numpeaks):
temp = np.zeros(x.size)
temp[(cent[value - 1] <= x) & (x < cent[value])] = 1
yvalues = yvalues + amp[value] * temp / sum(temp)
peakform = peakform + Lbulk * yvalues
#print('Three', np.sum(peakform, axis = 0), one*(L0 + Lsurf + Lbulk))
norm = [
hnorm(m=value, A=np.array([A1, Alow, Aupp]), c=cent)
for value in range(1, numpeaks)
]
peakform = np.convolve(gaussian(np.arange(-2, 2, dx), 0, s), peakform,
'same')
peakform = (peakform + np.sum([
gaussian(x, cent[value - 1], s) * amp[value] * A1**value /
norm[value - 1] * L0 for value in range(1, numpeaks)
],
axis=0) +
np.sum([
gaussian(x - cent[0], cent[value - 1], s) * amp[value] *
A1**value / norm[value - 1] * Lsurf
for value in range(1, numpeaks)
],
axis=0))
#print('Four', np.sum(peakform, axis = 0), (L0 + Lbulk + Lsurf)*sum(amp[1:]))
return L * (peakform + fitfun(x, s, c0, c1, n, amp[0], Lbulk, Lsurf))
def Jb_spline(X, n=0):
"""Jb interpolated from a saved spline. Input is (m/T)^2."""
X = numpy.array(X, copy=False)
x = X.ravel()
y = interpolate.splev(x, _tckb, der=n).ravel()
y[x < _xbmin] = interpolate.splev(_xbmin, _tckb, der=n)
y[x > _xbmax] = 0
return y.reshape(X.shape)
# Now for the low x expansion (require that n <= 50)
a, b, c, d = -pi**4 / 45, pi * pi / 12, -pi / 6, -1 / 32.
logab = 1.5 - 2 * euler_gamma + 2 * log(4 * pi)
l = numpy.arange(50) + 1
g = (-2 * pi**3.5 * (-1)**l * (1 + special.zetac(2 * l + 1)) *
special.gamma(l + .5) / (fac(l + 2) * (2 * pi)**(2 * l + 4)))
lowCoef_b = (a, b, c, d, logab, l, g)
del (a, b, c, d, logab, l, g) # clean up name space
a, b, d = -7 * pi**4 / 360, pi * pi / 24, 1 / 32.
logaf = 1.5 - 2 * euler_gamma + 2 * log(pi)
l = numpy.arange(50) + 1
g = (.25 * pi**3.5 * (-1)**l * (1 + special.zetac(2 * l + 1)) *
special.gamma(l + .5) * (1 - .5**(2 * l + 1)) /
(fac(l + 2) * pi**(2 * l + 4)))
lowCoef_f = (a, b, d, logaf, l, g)
del (a, b, d, logaf, l, g) # clean up name space
def Jb_low(x, n=20):
"""Jb calculated using the low-x (high-T) expansion."""
def redo_traceplots(config,prior,Xt,Yt,TH,LLH):
''' plots a new chisq and a new prior + likelihood plot '''
chisq = []
llh = LLH[:][config.burn+1::config.thin]
prior_list_1 = []
prior_list_2 = []
prior_rlw = []
for th in TH:
J = len(th)
#llh_temp,exp_counts,chisq_temp = code3.llh(th,config,prior,Xt,Yt, 10000., p_thin =1.)
# llh.append(llh_temp)
#chisq.append( chisq_temp)
prior_list_1.append( J*np.log(prior.alpha) - prior.beta*np.sum(th[:,1]) - np.log(fac(J)) - np.log(np.product(th[:,1])) )
prior_temp = 0
prior_rlw_temp = 0
for th_j in th:
mb = code3.eval_prior(th_j, config,prior)
prior_temp += mb
prior_rlw_temp += ( -np.log(2*3.14*prior.sigma_gamma*prior.s_Epeak/prior.scale_alpha)
+ th_j[2]**2/(2*prior.sigma_gamma**2) + th_j[3] + prior.scale_alpha*th_j[4] + (th_j[6] - prior.mu_Epeak)**2/(2*prior.s_Epeak**2)
+ J * np.log(prior.alpha) )
prior_list_2.append(prior_temp)
prior_rlw.append(prior_rlw_temp)
llh = np.array(llh)
prior_list_1 = np.array(prior_list_1)
prior_list_2 = np.array(prior_list_2)
prior_mb = prior_list_1 + prior_list_2 - 50
# prior_list =np.array(prior_list)
llh = llh - np.max(llh)
# prior_list = prior_list - np.max(prior_list)
# posterior = llh[:,0] + prior_list
mb = np.arange(config.burn,config.M,config.thin)
#plt.figure()
#plt.plot(mb,chisq)
#plt.xlabel('MCMC iterations (thinned)')
#plt.ylabel(r'$\chi^2$')
#plt.title(r'$\chi^2$ for All Chains')
#plt.tight_layout()
#plt.show()
#plt.savefig('chisq_new.png')
# print np.shape(mb), np.shape(prior_list), np.shape(llh), np.shape(posterior)
plt.figure()
plt.plot(mb,llh)
plt.plot(mb,prior_mb)
plt.plot(mb,prior_rlw)
plt.legend(['LLH',r'Log-prior MB',r'Log-prior RLW'], loc = 3)
# plt.legend(['LLH',r'Log-prior $\nu_x \times \nu_u$',r'Log-prior $\nu_a$'], loc = 3)
plt.xlabel('MCMC iterations (thinned)')
plt.title('Log-densities')
plt.tight_layout()
plt.ylim([-200,0])
plt.show()
plt.savefig('densities.png')
