| #!/usr/bin/python |
| |
| """ |
| Control loop pole placement library. |
| |
| This library will grow to support many different pole placement methods. |
| Currently it only supports direct pole placement. |
| """ |
| |
| __author__ = 'Austin Schuh (austin.linux@gmail.com)' |
| |
| import numpy |
| import slycot |
| |
| class Error (Exception): |
| """Base class for all control loop exceptions.""" |
| |
| |
| class PolePlacementError(Error): |
| """Exception raised when pole placement fails.""" |
| |
| |
| # TODO(aschuh): dplace should take a control system object. |
| # There should also exist a function to manipulate laplace expressions, and |
| # something to plot bode plots and all that. |
| def dplace(A, B, poles, alpha=1e-6): |
| """Set the poles of (A - BF) to poles. |
| |
| Args: |
| A: numpy.matrix(n x n), The A matrix. |
| B: numpy.matrix(n x m), The B matrix. |
| poles: array(imaginary numbers), The poles to use. Complex conjugates poles |
| must be in pairs. |
| |
| Raises: |
| ValueError: Arguments were the wrong shape or there were too many poles. |
| PolePlacementError: Pole placement failed. |
| |
| Returns: |
| numpy.matrix(m x n), K |
| """ |
| # See http://www.icm.tu-bs.de/NICONET/doc/SB01BD.html for a description of the |
| # fortran code that this is cleaning up the interface to. |
| n = A.shape[0] |
| if A.shape[1] != n: |
| raise ValueError("A must be square") |
| if B.shape[0] != n: |
| raise ValueError("B must have the same number of states as A.") |
| m = B.shape[1] |
| |
| num_poles = len(poles) |
| if num_poles > n: |
| raise ValueError("Trying to place more poles than states.") |
| |
| out = slycot.sb01bd(n=n, |
| m=m, |
| np=num_poles, |
| alpha=alpha, |
| A=A, |
| B=B, |
| w=numpy.array(poles), |
| dico='D') |
| |
| A_z = numpy.matrix(out[0]) |
| num_too_small_eigenvalues = out[2] |
| num_assigned_eigenvalues = out[3] |
| num_uncontrollable_eigenvalues = out[4] |
| K = numpy.matrix(-out[5]) |
| Z = numpy.matrix(out[6]) |
| |
| if num_too_small_eigenvalues != 0: |
| raise PolePlacementError("Number of eigenvalues that are too small " |
| "and are therefore unmodified is %d." % |
| num_too_small_eigenvalues) |
| if num_assigned_eigenvalues != num_poles: |
| raise PolePlacementError("Did not place all the eigenvalues that were " |
| "requested. Only placed %d eigenvalues." % |
| num_assigned_eigenvalues) |
| if num_uncontrollable_eigenvalues != 0: |
| raise PolePlacementError("Found %d uncontrollable eigenvlaues." % |
| num_uncontrollable_eigenvalues) |
| |
| return K |
| |
| |
| def c2d(A, B, dt): |
| """Converts from continuous time state space representation to discrete time. |
| Evaluates e^(A dt) for the discrete time version of A, and |
| integral(e^(A t) * B, 0, dt). |
| Returns (A, B). C and D are unchanged.""" |
| e, P = numpy.linalg.eig(A) |
| diag = numpy.matrix(numpy.eye(A.shape[0])) |
| diage = numpy.matrix(numpy.eye(A.shape[0])) |
| for eig, count in zip(e, range(0, A.shape[0])): |
| diag[count, count] = numpy.exp(eig * dt) |
| if abs(eig) < 1.0e-16: |
| diage[count, count] = dt |
| else: |
| diage[count, count] = (numpy.exp(eig * dt) - 1.0) / eig |
| |
| return (P * diag * numpy.linalg.inv(P), P * diage * numpy.linalg.inv(P) * B) |
| |
| def ctrb(A, B): |
| """Returns the controlability matrix. |
| |
| This matrix must have full rank for all the states to be controlable. |
| """ |
| n = A.shape[0] |
| output = B |
| intermediate = B |
| for i in xrange(0, n): |
| intermediate = A * intermediate |
| output = numpy.concatenate((output, intermediate), axis=1) |
| |
| return output |
| |
| def dlqr(A, B, Q, R): |
| """Solves for the optimal lqr controller. |
| |
| x(n+1) = A * x(n) + B * u(n) |
| J = sum(0, inf, x.T * Q * x + u.T * R * u) |
| """ |
| |
| # P = (A.T * P * A) - (A.T * P * B * numpy.linalg.inv(R + B.T * P *B) * (A.T * P.T * B).T + Q |
| |
| P, rcond, w, S, T = slycot.sb02od(A.shape[0], B.shape[1], A, B, Q, R, 'D') |
| |
| F = numpy.linalg.inv(R + B.T * P *B) * B.T * P * A |
| return F |