def testSingleSubjectMultipleTimes(signal, times):
print("Testing single subject, multiple {} times...".format(times))
results = []
for t in range(times):
neuro_act = simulateFCD.computeSubjectSimulation(C, N)
bds = simulateFCD.computeSubjectBOLD(neuro_act)
bdsT = bds.T
sim_filt = BOLDFilters.filterBrainArea(bdsT, 0)
sim_filt /= np.std(sim_filt)
error = errorMetrics.l2(signal, sim_filt)
print("Trial: {} ({}) of {}".format(t+1, t, times), "Error:", error)
results.append([error])
avg = np.average(results)
std = np.std(results)
print("Average:", avg, "std:", std)
# the histogram of the data
n, bins, patches = plt.hist(results/avg*10, bins=10, facecolor='g', alpha=0.75)
plt.xlabel('error')
plt.ylabel('Probability')
plt.title('Histogram of errors')
plt.text(60, .025, '$\mu$={}, $\sigma$={}'.format(avg, std))
#plt.xlim(40, 160)
#plt.ylim(0, 0.03)
#plt.grid(True)
plt.show()
def processBrainAreasBOLDForEpsilon(brainAreaSignal, areas):
global neuro_act
simulateActivitySubject(C, N, we)
epsilons = np.arange(0,2.1,0.1)
results = [] #np.zeros([len(epsilons), len(areas)])
minEpsilon=0
minValue=1e99
for epsilon in epsilons:
print("Epsilon:", epsilon, end=' ')
BOLDHemModel_Stephan2008.epsilon = epsilon
bds = simulateFCD.computeSubjectBOLD(neuro_act, N, areasToSimulate=areas)
bdsT = bds.T
#for area, areaID in enumerate(areas):
norm_bdsT = normalizeSignal(brainAreaSignal, bdsT)
#print("sim: ", np.average(norm_bdsT), "+/-", np.sqrt(np.var(norm_bdsT)))
#print("fMRFI:", np.average(signal), "+/-", np.sqrt(np.var(signal)))
error = errorMetrics.l2(brainAreaSignal, norm_bdsT)
if error < minValue:
minEpsilon = epsilon
minValue = error
results.append([error])
print("Error:", error)
print("Minimum:", minValue, "at:", minEpsilon,)
plt.plot(epsilons, results, 'r-')
plt.show()
BOLDHemModel_Stephan2008.epsilon = minEpsilon
bds = simulateFCD.computeSubjectBOLD(neuro_act, N, areasToSimulate=[0])
bdsT = bds.T
norm_bdsT = normalizeSignal(brainAreaSignal, bdsT)
interval=range(len(brainAreaSignal))
plt.plot(interval,brainAreaSignal.flatten(), 'b-', interval,norm_bdsT.flatten(), 'r-')
plt.suptitle('Area:'+str(areas[0]))
plt.show()
def fitBOLDBrainArea(neuronal_act, BOLDSignal, area, lowerBounds = initialLowerBounds):
def errorFunc(neuro_act, epsilon, alpha, tau, gamma, kappa):
if Verbose:
global evalCounter
evalCounter += 1
print("Test:", evalCounter)
BOLDModel.epsilon = epsilon
BOLDModel.alpha = alpha
BOLDModel.tau = tau
BOLDModel.gamma = gamma
BOLDModel.kappa = kappa
bds = simulateFCD.computeSubjectBOLD(neuro_act, areasToSimulate=[area])
bdsT = bds.T
sim_filt = BOLDFilters.filterBrainArea(bdsT, 0)
sim_filt /= np.std(sim_filt)
return sim_filt
# init...
from scipy.optimize import curve_fit
emp_filt = BOLDFilters.filterBrainArea(BOLDSignal, area)
emp_filt /= np.std(emp_filt)
# Now, fit it !!!
# Note: Be careful with max_nfev, evaluations include numerical derivatives, so the actual number will be around 4.6 (or more) * this number before stopping!!!
if numMethod == 'trf':
popt, pcov = curve_fit(errorFunc, neuronal_act, emp_filt, method='trf', bounds=(lowerBounds, 3.0), p0 = initialValues, max_nfev = 100)
else: # use 'lm'
popt, pcov = curve_fit(errorFunc, neuronal_act, emp_filt, method='lm', p0 = initialValues)
final_values = errorFunc(neuronal_act, popt[0], popt[1], popt[2], popt[3], popt[4])
finalError = errorMetrics.l2(emp_filt, final_values)
return popt, pcov, finalError
def pltSimAndEmpiricalBrainAreaForVariousVariableValues(BOLDSignal, area, varKey, subplot=False):
N,T = BOLDSignal.shape
interval=range(T)
plt.rcParams.update({'font.size': 22})
if subplot:
plt.subplot(2, 1, 1)
plt.title("Empirical BOLD for area {}".format(area))
emp_filt = BOLDFilters.filterBrainArea(BOLDSignal, area)
emp_filt /= np.std(emp_filt)
empSignal, = plt.plot(interval, emp_filt, 'r--', label='empirical')
if subplot:
plt.subplot(2, 1, 2)
plt.title("Simulated BOLD for area {}".format(area))
sim_filt00 = simBrainAreaForOptimVars(N, area, {varKey: 0.05}) # Some vars cannot be just 0.0...
simSignal00, = plt.plot(interval, sim_filt00, 'b-', label='simulated('+varKey+'=0.05)')
sim_filt05 = simBrainAreaForOptimVars(N, area, {varKey: 0.5})
simSignal05, = plt.plot(interval, sim_filt05, 'g-', label='simulated('+varKey+'=0.5)')
sim_filt10 = simBrainAreaForOptimVars(N, area, {varKey: 1.0})
simSignal10, = plt.plot(interval, sim_filt10, 'c-', label='simulated('+varKey+'=1.0)')
sim_filt15 = simBrainAreaForOptimVars(N, area, {varKey: 1.5})
simSignal15, = plt.plot(interval, sim_filt15, 'm-', label='simulated('+varKey+'=1.5)')
plt.suptitle('Sim and Empirical BOLD for single area, '+varKey)
if not subplot:
plt.legend(handles=[empSignal, simSignal00, simSignal05, simSignal10, simSignal15])
else:
plt.legend(handles=[simSignal00, simSignal05, simSignal10, simSignal15])
plt.tight_layout()
# plt.legend(handles=[simSignal00, simSignal05, simSignal10, simSignal15])
# plt.legend(handles=[empSignal, simSignal05])
plt.show()
# just some computations to know a little bit better this stuff
print("l^2 Error (0.05):", errorMetrics.l2(emp_filt, sim_filt00))
print("l^2 Error (0.5):", errorMetrics.l2(emp_filt, sim_filt05))
print("l^2 Error (1.0):", errorMetrics.l2(emp_filt, sim_filt10))
print("l^2 Error (1.5):", errorMetrics.l2(emp_filt, sim_filt15))
from scipy.stats.stats import pearsonr
print("Pearson.r (0.05):", pearsonr(emp_filt, sim_filt00))
print("Pearson.r (0.5):", pearsonr(emp_filt, sim_filt05))
print("Pearson.r (1.0):", pearsonr(emp_filt, sim_filt10))
print("Pearson.r (1.5):", pearsonr(emp_filt, sim_filt15))
def distTo3Hz(curr):
import functions.Utils.errorMetrics as error
tmin = 1000 if (tmax > 1000) else int(tmax / 10)
currm = np.mean(
curr[tmin:tmax, :],
0) # takes the mean of all xn values along dimension 1...
# return np.abs(np.average(f)-targetFreq)
return error.l2(currm, targetFreq)
def checkAveragedValuesOverSubjects(tc_aal, area, condition):
print("function checkAveragedValuesOverSubjects ({} Subjects)".format(Subjects))
print("======================================================")
allErrors = np.zeros([Subjects])
avgResult, avgError = averageSingleBrainAreaForAllSubjects(tc_aal, area, condition)
print("Average error (area by area):", avgError)
for subject in range(Subjects):
print("Checking area {} from subject {} !!!".format(area,subject))
BOLDData = tc_aal[subject, condition]
emp_filt = BOLDFilters.filterBrainArea(BOLDData, area)
emp_filt /= np.std(emp_filt)
sim_filtOptim = simBrainAreaForOptimVars(N, area, optimBOLD.pairVarsAndValues(avgResult))
error = errorMetrics.l2(emp_filt, sim_filtOptim)
print("Error computed:", error)
allErrors[subject] = error
finalAvgError = np.mean(allErrors)
print("Final avg error (all areas same parms):", finalAvgError)
def pltErrorForBrainAreaFitOptimVariable(BOLDSignal, area, key, minValue = -0.5, maxValue=2.6, stepValue=0.1):
from scipy.stats.stats import pearsonr
emp_filt = BOLDFilters.filterBrainArea(BOLDSignal, area)
emp_filt /= np.std(emp_filt)
N,T = BOLDSignal.shape
global neuro_act
simulateActivitySubject(C, N, we)
values = np.arange(minValue,maxValue,stepValue)
results = [] #np.zeros([len(epsilons), len(areas)])
resultsPearson = []
minVar=-1
minValue=1e99
for value in values:
print("Var value:", value, end=' ')
sim_filt = simBrainAreaForOptimVars(N, area, {key: value})
# simSignal, = plt.plot(interval, sim_filt, label='simulated(epsilon={}})'.format(epsilon))
error = errorMetrics.l2(emp_filt, sim_filt)
errorPearson = (1-pearsonr(emp_filt, sim_filt)[0])*20
if error < minValue:
minVar = value
minValue = error
results.append([error])
resultsPearson.append([errorPearson])
print("Error:", error, "Pearson.r:", errorPearson)
print("'Manual' minimum:", minValue, "at:", minVar,)
plt.rcParams.update({'font.size': 22})
plt.suptitle('BOLD Error for '+ key +', area ({})'.format(area))
plt.plot(values, results, 'r-')
plt.plot(values, resultsPearson, 'b-')
#popt, pcov, finalError = optimBOLD.fitBOLDBrainAreaCatchingErrors(neuro_act, BOLDSignal, area)
#perr = np.sqrt(np.diag(pcov))
#print("Computed minimum:", popt, "value:", finalError,"Std Dev:", perr)
lineAt = minVar # popt[0] or minVar
plt.axvline(x=lineAt, color='g', linestyle='--')
plt.show()
interval=range(T)
empSignal, = plt.plot(interval, emp_filt, 'r--', label='empirical')
sim_filtOptim = simBrainAreaForOptimVars(N, area, {key: lineAt})
simSignalOptim, = plt.plot(interval, sim_filtOptim, 'b-', label='simulated(epsilon={})'.format(lineAt))
plt.suptitle('Optimal Sim and Empirical ('+key+') BOLD for area {}'.format(area))
plt.legend(handles=[empSignal, simSignalOptim])
plt.show()
def pltSubjectBOLDForEpsilon(signal):
global neuro_act
simulateActivitySubject(C, N, we)
results = []
epsilons = np.arange(0,2.1,0.2)
for epsilon in epsilons:
print("Epsilon:", epsilon, end=' ')
BOLDHemModel_Stephan2008.epsilon = epsilon
bds = simulateFCD.computeSubjectBOLD(neuro_act, N)
bdsT = bds.T
norm_bdsT = normalizeSignal(signal, bdsT)
#print("sim: ", np.average(norm_bdsT), "+/-", np.sqrt(np.var(norm_bdsT)))
#print("fMRFI:", np.average(signal), "+/-", np.sqrt(np.var(signal)))
error = errorMetrics.l2(signal, norm_bdsT)
results = np.append(results, [error])
print("Error:", error)
plt.plot(epsilons, results, 'r-')
plt.show()
def processSubjectForEpsilon(signal):
global neuro_act
if doIndividualSim: # each subject goes with his/her own sim...
simulateActivitySubject(C, N, we)
results = []
epsilons = np.arange(0,1.5,0.1)
for epsilon in epsilons:
print("Epsilon:", epsilon, end=' ')
BOLDHemModel_Stephan2008.epsilon = epsilon
bds = simulateFCD.computeSubjectBOLD(neuro_act)
bdsT = bds.T
norm_bdsT = normalizeSignal(signal, bdsT)
#print("sim: ", np.average(norm_bdsT), "+/-", np.sqrt(np.var(norm_bdsT)))
#print("fMRFI:", np.average(signal), "+/-", np.sqrt(np.var(signal)))
error = errorMetrics.l2(signal, norm_bdsT)
np.append(results, [error])
print("Error:", error)
plt.plot(epsilons, results, 'r-')
plt.show()
def distTo3Hz(f):
import functions.Utils.errorMetrics as error
# return np.abs(np.average(f)-targetFreq)
return error.l2(f, targetFreq)
