I have a polynomial least squares problem, and when I (1) regularize and (2) add a constraint (fit 4), the fit would look good if I flipped the sign and shifted it down. This is shown in the plot:

I'm wondering why this is the case. Based on the fit three, the constraint doesn't seem too awful, but it misses the curvature on the first part of the plot but gets it on the second. Why does regularizing this constrained problem (now the purple fit) make the fit lose the second curve too?

I've included my code below:

```
import matplotlib.pyplot as plt
import numpy as np
import numpy.linalg as la
import cvxpy as cp
# data
x = np.array([0.98775, 0.9942, 0.99438333, 0.99145417, 0.99070833,
0.991325, 0.99117917, 0.97414583, 0.9754625, 0.9850875])
y = np.array([0.729069, 0.66085, 0.658708, 0.693509, 0.723134,
0.716455, 0.715611, 0.86655, 0.854071, 0.757493])
N = len(x)
X = np.zeros((N, 3))
# model
def model(x, beta):
return beta[0] + beta[1]*x + beta[2]*x**2.0
# build features
for i in range(N):
X[i, 0] = 1.
X[i, 1] = x[i]
X[i, 2] = x[i]**2.0
# unconstrained ----------------------------------------------------------
# min_x ||Xbeta - y||_2^2
sol = np.linalg.lstsq(X, y, rcond=None)
beta1 = sol[0]
print "Unconstrained solution: " + str(beta1)
print "Error: ", la.norm(X.dot(beta1) - y)
print "Sum of coeffs: ", sum(beta1)
print
# regularize and solve min_x ||Xbeta - y||_2^2 + mu||beta||_2^2
mu = 1e-6
X_dagger = np.dot(np.linalg.inv(np.dot(X.T, X) + mu*np.eye(3)), X.T)
beta2 = np.dot(X_dagger, y)
print "Unconstrained solution + regularization: " + str(beta2)
print "Error: ", la.norm(X.dot(beta2) - y)
print "Sum of coeffs: ", sum(beta2)
print
# constrained ------------------------------------------------------------
mu = 1e-6
## min_x ||Xbeta - y||_2^2 s.t. 1^T x = 1
e = np.ones(3).reshape(1,3)
K = np.block([[2.0*X.T.dot(X), e.T], [e, 0.0]])
rhs = np.block([2.0*X.T.dot(y), 1.0])
beta3 = la.inv(K).dot(rhs)[0:3]
print "Constrained solution: " + str(beta3)
print "Error: ", la.norm(X.dot(beta3) - y)
print "Sum of coeffs: ", sum(beta3)
print
## min_x ||(A + muI)x - P||_2^2 s.t. 1^T x = 1
e = np.ones(3).reshape(1,3)
K = np.block([[2.0*(X.T.dot(X) + mu*np.eye(3)), e.T], [e, 0.0]])
rhs = np.block([2.0*X.T.dot(y), 1.0])
beta4 = la.inv(K).dot(rhs)[0:3]
print "Constrained solution + regularization: " + str(beta4)
print "Error: ", la.norm(X.dot(beta4) - y)
print "Sum of coeffs: ", sum(beta4)
print
# predict and plot ------------------------------------------------------
# predict
yhat1 = np.zeros(N)
for i in range(N): yhat1[i] = model(x[i], beta1)
yhat2 = np.zeros(N)
for i in range(N): yhat2[i] = model(x[i], beta2)
yhat3 = np.zeros(N)
for i in range(N): yhat3[i] = model(x[i], beta3)
yhat4 = np.zeros(N)
for i in range(N): yhat4[i] = model(x[i], beta4)
# plot
plt.figure(figsize=(17, 5))
plt.plot(y, label="y")
plt.plot(yhat1, label="fit1: unconstr {:0.3e}".format(la.norm(yhat1 - y)))
plt.plot(yhat2, label="fit2: unconstr + reg {:0.3e}".format(la.norm(yhat2 - y)))
plt.plot(yhat3, label="fit3: constr {:0.3e}".format(la.norm(yhat3 - y)))
plt.plot(yhat4, label="fit4: constr + reg {:0.3e}".format(la.norm(yhat4 - y)))
plt.legend()
plt.show()
```