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SALC.py~
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144 lines (120 loc) · 3.96 KB
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from ui import *
import sherpa.astro.ui as ui
from mhtest import *
execfile("funcs.py")
set_stat("cash")
model = "xsphabs.abs1*powlaw1d.p1"
parnames=np.array(['abs1.nh','p1.gamma','p1.ampl'])
#dataspace1d(0.0,1024.0,id=1,dstype=DataPHA)
arf1=unpack_arf("core1.arf")
rmf1=unpack_rmf("core1.rmf")
#set_arf(arf1)
#set_rmf(rmf1)
set_model(1, model)
abs1.nh = 0.1
#abs1.nh = 0.01
p1.gamma = 2.0
# set exposure level
expos=100
counts0=300
fake_pha(1,arf1,rmf1,exposure=expos)
p1.ampl = counts0/calc_data_sum()
fake_pha(1,arf1,rmf1,exposure=expos)
ranges= np.array([[.3,.9],[.9,2.5],[2.5,8.0]])
counts = np.zeros( ranges.shape[0] )
lamb = np.zeros( ranges.shape[0] )
lklhd = np.zeros( ranges.shape[0] )
for i in range(ranges.shape[0]):
notice( ranges[i,0] , ranges[i,1])
counts[i] = calc_data_sum(ranges[i,0] , ranges[i,1] )
lamb[i] = calc_model_sum(ranges[i,0] , ranges[i,1] )
lklhd[i] = np.exp(-.5*calc_stat() )
notice()
def log_sum( counts, ranges):
for i in range(ranges.shape[0]):
notice( ranges[i,0] , ranges[i,1])
lamb[i] = calc_model_sum(ranges[i,0] , ranges[i,1] )
lklhd[i] = counts[i] * np.log(lamb[i]) - lamb[i]
notice()
return np.sum(lklhd)
def z(counts,ranges,outfile='z.txt'):
L = 30
out = np.zeros( (L,L) )
for i in range(1,L,1):
for j in range(1,L,1):
if j==1:
print str(i)
abs1.nh = i*0.0333+0.001
p1.gamma = j*0.1
out[i,j] = log_sum(counts, ranges)
write_draws(out, outfile)
def grid(ranges,outfile='grid.txt'):
n = np.array([0.001,0.01,0.025,0.05,0.075,0.1,0.125,0.25,0.5,1])
g = np.array([0.1,0.25,0.5,0.75,1,1.5,2,3])
out = np.zeros( (g.size*n.size,4) )
lamb = np.zeros( ranges.shape[0] )
for i in range(g.size):
for j in range(n.size):
if j==1:
print str(i)
abs1.nh = n[j]
p1.gamma = g[i]
for k in range(ranges.shape[0]):
lamb[k] = calc_model_sum(ranges[k,0], ranges[k,1])
cS = np.log10(lamb[0]/lamb[1])
cH = np.log10(lamb[1]/lamb[2])
out[(n.size)*i+j] = np.hstack( (g[i],n[j],cS,cH) )
write_draws(out, outfile)
#start = np.array([.1,.1,.1])
k = ranges.shape[0]-1
notice(ranges[0,0],ranges[k,1])
fit()
covar()
#start = np.array([0.1,1.5,0.0001])
start = get_fit_results().parvals
#sigma = np.diag( np.array([.0001,.0001,.0001]) )
sigma = np.diag(get_covar_results().extra_output)
print sigma
def metropolis(counts, ranges, parnames, start, sigma, outfile='out.txt', num_iter=1000 ):
iterations = np.zeros( (num_iter+1, parnames.size) )
statistics = np.zeros( (num_iter+1,1) )
current=np.copy(start)
_set_par_vals(parnames, current)
statistics[0] = log_sum( counts, ranges)
statistics[0] += -0.01*current[1] - np.log(current[2])
iterations[0] = np.copy(current)
zero_vec = np.zeros(parnames.size)
for i in range(1,num_iter+1,1):
if np.mod(i,100)==1:
print "draw "+str(i)
current = np.copy(iterations[i-1])
while True:
try:
#if ((sigma==sigma_m).all()):
proposal = iterations[i-1] + np.random.multivariate_normal(zero_vec, sigma)
_set_par_vals(parnames, proposal)
break
#except Parameter Error:
except Exception:
pass
stat_temp = log_sum( counts, ranges)
stat_temp += -0.01*proposal[1] - np.log(proposal[2])
alpha = np.exp( stat_temp - statistics[i-1])
u = np.random.uniform(0,1,1)
if u <= alpha:
iterations[i]=np.copy(proposal)
statistics[i]=np.copy(stat_temp)
else:
iterations[i]=np.copy(iterations[i-1])
statistics[i]=np.copy(statistics[i-1])
burnin = int(np.round(num_iter*0.2)+1)
result = np.hstack( (statistics[np.arange(burnin,num_iter+1)],iterations[np.arange(burnin,num_iter+1)]) )
analyze_draws( result, parnames, 2, dict=False, verbose=True, means=True)
write_draws( iterations, outfile)
return result
# draws = metropolis( counts, ranges, parnames, start, sigma, outfile="out.txt", num_iter=100 )
draws = metropolis( np.array([1,14,27]), ranges, parnames, start, sigma, outfile="out.txt", num_iter=1250 )
#means ={}
#for i,par in enumerate(parnames):
# means[par] = np.round(np.mean( draws[:,i+1]) , 3)
#means