def plotMSEvsNoise(x,y,deg,sigmas,lamb,folds, Franke = False):
MSE_test = np.zeros((3,len(sigmas)))
variance = np.zeros((3,len(sigmas)))
bias = np.zeros((3,len(sigmas)))
MSE_train = np.zeros((3,len(sigmas)))
i = 0
for sigma in sigmas:
z = FrankeFunc(x,y)
error = np.random.normal(0,sigma,size=z.shape)
z = z+error
MSE_test[0,i], MSE_train[0,i], bias[0,i], variance[0,i], R2[0, i] = k_fold1(x, y, z, deg, folds,'OLS', shuffle=True, Franke=Franke)
MSE_test[1, i], MSE_train[1, i], bias[1, i], variance[1, i], R2[1, i] = k_fold1(x, y, z, deg, folds, 'Ridge', lamb=lamb, shuffle=True, Franke=Franke)
MSE_test[2, i], MSE_train[2, i], bias[2, i], variance[2, i], R2[2, i] = k_fold1(x, y, z, deg, folds, 'Lasso', lamb=100, shuffle=True, Franke=Franke)
i = i+1
fig = plt.figure()
lines = np.zeros(3)
linenames = [None]*3
linenames[0] = 'OLS'
linenames[1] = 'Ridge'
linenames[2] = 'Lasso'
for j in range(3):
lines = plt.plot(sigmas, MSE_test[j,:], label=linenames[j])
#plt.axhline()
plt.xlabel('Noise')
plt.ylabel('MSE')
plt.legend(linenames)
plt.show()
def fitTerrainData(x,y,terrain,deg=4,lamb = 0.001,folds = 5,method = 'OLS', Franke = False):
p = int(0.5 * (deg + 2) * (deg + 1))
beta = np.zeros(p)
z = terrain.ravel()
x_ = x.ravel()
y_ = y.ravel()
beta = k_fold1(x_, y_, z, deg, folds,method,lamb=lamb,shuffle=True,beta_out=True, Franke=Franke)
x_deg = np.c_[x_, y_]
beta = np.transpose(beta)
poly = PolynomialFeatures(degree=deg)
X = poly.fit_transform(x_deg)
#z_est = np.zeros(z.shape)
z_est = X @ beta
fig = plt.figure()
ax = fig.gca(projection='3d')
surf = ax.plot_surface(x, y, terrain, cmap=cm.coolwarm, linewidth=0, antialiased=False)
ax.scatter(x,y,z_est,marker='.',c='k')
# Customize the z axis.
#ax.set_zlim(-0.10, 1.40)
ax.zaxis.set_major_locator(LinearLocator(10))
ax.zaxis.set_major_formatter(FormatStrFormatter('%.02f'))
# Add a color bar which maps values to colors.
fig.colorbar(surf, shrink=0.5, aspect=5)
titlestring = 'Terrain data fitted with data from a ' + str(deg) +'th degree polynomial, \n created using ' + method + ' regression with lambda = ' + str(lamb)
plt.title(titlestring)
plt.show()
def compareRegressionMethodsAtOptimalConditions(x,y,z,degOLS,degRidge,degLasso,lambRidge,lambLasso,folds,Franke = False):
MSE_test = np.zeros(3)
variance= np.zeros(3)
bias= np.zeros(3)
MSE_train = np.zeros(3)
R2 = np.zeros(3)
i = 0
MSE_test[0], MSE_train[0], bias[0], variance[0], R2[0] = k_fold1(x, y, z, degOLS, folds,'OLS', shuffle=True, Franke=Franke)
MSE_test[1], MSE_train[1], bias[1], variance[1], R2[1] = k_fold1(x, y, z, degRidge, folds, 'Ridge', lamb=lambRidge, shuffle=True, Franke=Franke)
MSE_test[2], MSE_train[2], bias[2], variance[2], R2[2] = k_fold1(x, y, z, degLasso, folds, 'Lasso', lamb=lambLasso, shuffle=True, Franke=Franke)
print('-----------------')
print('MSE OLS: ' + str(MSE_test[0]))
print('R2 OLS: ' + str(R2[0]))
print('MSE Ridge: ' + str(MSE_test[1]))
print('R2 Ridge: ' + str(R2[1]))
print('MSE Lasso: ' + str(MSE_test[2]))
print('R2 Lasso: ' + str(R2[2]))
def plotRidgeLambdaAnalysis(x,y,z,degrees,lambdas,folds, Franke = False):
MSE_test = np.zeros((len(lambdas),len(degrees)))
variance= np.zeros((len(lambdas),len(degrees)))
bias= np.zeros((len(lambdas),len(degrees)))
MSE_train = np.zeros((len(lambdas),len(degrees)))
R2 = np.zeros((len(lambdas),len(degrees)))
i = 0
for lamb in lambdas:
j = 0
for deg in degrees:
MSE_test[i,j], MSE_train[i,j], bias[i,j], variance[i,j], R2[i,j] = k_fold1(x, y, z, deg, folds,'Ridge',lamb=lamb,shuffle=True, Franke= Franke)
j = j+1
i = i+1
#optDeg = degrees[minInd]
fig = plt.figure()
i = 0
lines = np.zeros(len(lambdas))
linenames = [None]*len(lambdas)
print(MSE_test[0,:])
for i in range(len(lambdas)):
linenames[i] = 'Lambda = ' + str(lambdas[i])
lines = plt.plot(degrees, MSE_test[i,:],label=linenames[i])
plt.title('Ridge')
plt.xlabel('Polynomial degree')
plt.ylabel('MSE')
plt.legend(linenames)
plt.show()
linenames = [None]*len(degrees)
fig2 = plt.figure()
for i in range(len(degrees)):
linenames[i] = 'Degree = ' + str(degrees[i])
lines = plt.plot(lambdas, MSE_test[:,i],label=linenames[i])
#plt.plot(lambdas,MSE_test[:,7])
plt.title('Ridge')
plt.xlabel('Lambda')
plt.ylabel('MSE')
plt.legend(linenames)
plt.xscale('log')
plt.show()
def plotLassoBetaVsLambda(x,y,z,deg,lambdas,folds, Franke=False):
p = int(0.5 * (deg + 2) * (deg + 1))
beta = np.zeros((len(lambdas),p))
i = 0
for lamb in lambdas:
beta[i,:] = k_fold1(x, y, z, deg, folds,'Lasso',lamb=lamb,shuffle=True,beta_out=True, Franke = Franke)
i = i+1
fig = plt.figure()
lines = np.zeros(p)
linenames = [None]*len(lines)
for j in range(p):
linenames[j] = 'Beta'
lines = plt.plot(lambdas, beta[:,j],label=linenames[j])
plt.xscale('log')
plt.title('Lasso')
plt.xlabel('Lambda')
plt.ylabel('Beta')
plt.axhline(color='k')
#plt.legend(linenames)
plt.show()
def plotOlsMSEVsComplexity(x,y,z,degrees,folds, Franke = False):
MSE_test = np.zeros(len(degrees))
variance = np.zeros(len(degrees))
bias = np.zeros(len(degrees))
MSE_train = np.zeros(len(degrees))
R2 = np.zeros(len(degrees))
i = 0
for deg in degrees:
MSE_test[i], MSE_train[i], bias[i], variance[i],R2[i] = k_fold1(x, y, z, deg, folds,'OLS',shuffle=True, Franke=Franke)
i = i+1
minInd = np.where(MSE_test == np.amin(MSE_test))
optDeg = degrees[minInd]
lab = 'Optimal degreen = ' + str(optDeg)
plt.figure()
line_test, = plt.plot(degrees,MSE_test,label='TEST')
#line_train, = plt.plot(degrees,MSE_train,label='TRAINING')
dot, = plt.plot(optDeg,MSE_test[minInd],'bo',label = lab)
plt.legend(handles=[dot])
plt.title('OLS')
plt.xlabel('Polynomial degree')
plt.ylabel('MSE')
plt.show()
bias = np.zeros((len(lambdas), len(degrees)))
MSE_train = np.zeros((len(lambdas), len(degrees)))
beta = np.zeros((len(lambdas), len(degrees)))
i = 0
for lamb in lambdas:
j = 0
for deg in degrees:
MSE_test[i,
j], MSE_train[i,
j], bias[i,
j], variance[i,
j] = k_fold1(x,
y,
z,
deg,
folds,
'Lasso',
lamb=lamb,
shuffle=True)
j = j + 1
i = i + 1
'''
fig = plt.figure()
i = 0
lines = np.zeros(len(lambdas))
linenames = [None]*len(lambdas)
print(MSE_test[0,:])
for i in range(len(lambdas)):
linenames[i] = 'Lambda = ' + str(lambdas[i])
lines = plt.plot(degrees, MSE_test[i,:],label=linenames[i])
variance= np.zeros(len(degrees))
bias= np.zeros(len(degrees))
MSE_train = np.zeros(len(degrees))
beta = np.zeros(len(degrees))
for deg in degrees:
MSE_test[i], MSE_train[i], bias[i], variance[i] = k_fold2(x, y, z, deg, folds,'OLS')
i = i+1
fig = plt.figure()
line_test, = plt.plot(degrees,MSE_test,label='TEST')
line_train, = plt.plot(degrees,MSE_train,label='TRAINING')
plt.legend(handles=[line_test,line_train])
plt.show()
MSE_tst, MSE_tra, bi, va = k_fold1(x,y,z,5,folds,'OLS',shuffle=True)
print('MSE for test with OLS:')
print(MSE_tst)
'''
MSE_test[1], MSE_train[1], bias[1], variance[1] = k_fold1(x,y,z,deg,folds,'OLS',shuffle=True)
#Ridge
MSE_test[2], MSE_train[2], bias[2], variance[2] = k_fold1(x,y,z,deg,folds,'OLS',shuffle=True)
#Lasso
MSE_test[3], MSE_train[3], bias[3], variance[3] = k_fold1(x,y,z,deg,folds,'OLS',shuffle=True)
'''
#Compare
