Ejemplo n.º 1
0
	def train(self, X, y,
		      intercept=False
		      **kwarg):
	if intercept == False:
		self.X = prepend_ones_col(X)
		self.y = y

	self.find_theta()
Ejemplo n.º 2
0
def normalEquationRegression(X, y):
    '''Assuming rows correspond to samples'''
    X_new = prepend_ones_col(X)
    temp = np.dot(X_new.T, X_new)
    temp = np.linalg.inv(temp)
    temp = np.dot(temp, X_new.T)
    theta = np.dot(temp, y)
    return theta
Ejemplo n.º 3
0
def normalEquationRidgeRegression(X, y, lmbd=0.1):
    '''Assuming rows correspond to samples'''
    X_new = prepend_ones_col(X)
    _, dim = X_new.shape
    temp = np.dot(X_new.T, X_new) + np.eye(dim) * (lmbd**2)
    temp = np.linalg.inv(temp)
    temp = np.dot(temp, X_new.T)
    theta = np.dot(temp, y)
    return theta
Ejemplo n.º 4
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def gradientDescentAutogradLasso(X, y, alpha=0.01, lmbd=0.1, it=300):
    X_new = prepend_ones_col(X)
    X_new = anp.array(X_new)
    y = anp.array(y)
    th = anp.random.rand(X_new.shape[1])
    for i in range(it):
        dw = lasso_grad(th, X_new, y, lmbd)
        th = th - alpha * (dw)
    return th
Ejemplo n.º 5
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def gradientDescentAutogradRegression(X, y, alpha=0.001, it=1000):
    X_new = prepend_ones_col(X)
    X_new = anp.array(X_new)
    n, m = X_new.shape
    th = anp.array([0.] * m)
    for i in range(it):
        dw = rms_grad(th, X_new, y)
        th = th - alpha * (dw)
    return th
Ejemplo n.º 6
0
def gradientDescentPytorchRegression(X, y, alpha=0.001, it=1000):
    X_new = torch.from_numpy(prepend_ones_col(X))
    y = torch.from_numpy(y[:, None])
    n, m = X_new.shape
    th = Variable(torch.rand(m, 1), requires_grad=True)
    for i in range(it):
        error = cost(th, X_new, y)
        error.backward()
        th = Variable(th - alpha * th.grad, requires_grad=True)
    nump = th.detach().numpy()
    return nump.squeeze()
Ejemplo n.º 7
0
def gradientDescentRegression(X, y, alpha=0.001, it=1000):
    X_new = prepend_ones_col(X)
    n, m = X_new.shape
    th = np.array([0.] * m)
    for i in range(it):
        yhat = np.matmul(X_new, th[:, None])
        e = y[:, None] - yhat
        weighted_e = X_new * e
        sumz = weighted_e.sum(axis=0)
        th = th + (2 * alpha * (sumz))
    return th
Ejemplo n.º 8
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def sgdRegression(X, y, alpha=0.001, it=100):
    X_new = prepend_ones_col(X)
    n, m = X_new.shape
    th = np.zeros(m)
    ths = []
    for i in range(it):
        for j in range(n):
            yhat = (X_new[j, :] * th).sum()
            e = y[j] - yhat
            weighted_e = X_new[j, :] * e
            th = th + (2 * alpha * (weighted_e))
            ths.append(np.copy(th))
    return th, ths
Ejemplo n.º 9
0
def coodrdinateDescentRegression(X, y, it=100):
    X_new = prepend_ones_col(X)
    n, m = X_new.shape
    th = np.array([0.] * m)
    ths = []

    for iteration in range(it):  # for a num of iterations
        for i in range(m):  # for num of thetas
            # calculate y_hat without th_i*X_i
            y_hat_red = np.dot(np.delete(X_new, i, axis=1),
                               np.delete(th, i, axis=0))
            temp = np.dot(X_new[:, i].T, (y - y_hat_red))
            th[i] = temp / np.matmul(X_new[:, i].T, X_new[:, i])
            ths.append(np.copy(th))
    return th, ths
Ejemplo n.º 10
0
def coodrdinateDescentLasso(X, y, lmbd=0.2, it=100):
    X_new = prepend_ones_col(X)
    n, m = X_new.shape
    th = np.array([0.] * m)

    for iteration in range(it):  # for a num of iterations
        for i in range(m):  # for num of thetas
            # calculate y_hat without th_i*X_i
            y_hat_red = np.dot(np.delete(X_new, i, axis=1),
                               np.delete(th, i, axis=0))
            p_i = np.dot(X_new[:, i].T, (y - y_hat_red))
            z_i = np.matmul(X_new[:, i].T, X_new[:, i])
            const = (lmbd) / 2
            if p_i < -const:
                th[i] = (p_i + const) / z_i
            elif p_i >= -const and p_i <= const:
                th[i] = 0
            else:  # p_i > const
                th[i] = (p_i - const) / z_i
    return th