Ejemplo n.º 1
0
def nucmin_estimator(A, y, eta=None, **kwargs):
    """@todo: Docstring for nucmin_estimator.

    :param A: @todo
    :param y: @todo
    :param **kwargs: @todo
    :returns: @todo

    """
    x_sharp = cvx.Variable(A.shape[1], A.shape[2])
    objective = cvx.Minimize(cvx.normNuc(x_sharp))

    if eta is None:
        constraints = [_expval(A, x_sharp) == y]
    else:
        constraints = [cvx.abs(_expval(A, x_sharp) - y) < eta]

    problem = cvx.Problem(objective, constraints)
    problem.solve(**kwargs)

    if problem.status not in ['optimal']:
        raise ValueError("Optimization did not converge: " + problem.status)
    return np.array(x_sharp.value)
Ejemplo n.º 2
0
 def test_norm_nuc(self) -> None:
     """Test gradient for norm_nuc
     """
     expr = cp.normNuc(self.A)
     self.A.value = [[10, 4], [4, 30]]
     self.assertItemsAlmostEqual(expr.grad[self.A].toarray(), [1, 0, 0, 1])
Ejemplo n.º 3
0
    # Set-up hyperparameters
    options = {'c1': 0.5, 'c2': 0.3, 'w': 0.9}
    # Call instance of PSO
    optimizer = ps.single.GlobalBestPSO(n_particles=100,
                                        dimensions=p,
                                        options=options)
    # Perform optimization
    best_cost, best_pos = optimizer.optimize(nnm,
                                             iters=100,
                                             Y=Y_low,
                                             omega_c=omega_c)

    known_value_indices = tuple(zip(*omega.tolist()))
    known_values = Y_low[omega[:, 0], omega[:, 1]]
    X = cp.Variable((m, n), pos=True)
    objective_fn = cp.normNuc(X)
    constraints = [
        X[known_value_indices] == known_values,
    ]
    problem = cp.Problem(cp.Minimize(objective_fn), constraints)
    problem.solve(gp=False)
    #print("Solver reconstruct loss: ", np.linalg.norm((np.array(X.value) - Y_low), "fro"))
    Y[omega_c[:, 0], omega_c[:, 1]] = best_pos
    print("PSO reconstruct loss:", np.linalg.norm((Y - Y_low), "fro"))

    result.append(
        [t,
         np.linalg.norm((Y - Y_low), "fro") / np.linalg.norm(Y_low, "fro")])
    #result.append([t, "CVXPY", np.linalg.norm((np.array(X.value) - Y_low), "fro")])

df = pd.DataFrame(result, columns=["iter", "MSE"]).iloc[:, 1]