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Please note that the recommended version of Scilab is 2025.0.0. This page might be outdated.
See the recommended documentation of this function
findR
Preprocessor for estimating the matrices of a linear time-invariant dynamical system
Calling Sequence
[R,N [,SVAL,RCND]] = findR(S,Y,U,METH,ALG,JOBD,TOL,PRINTW) [R,N] = findR(S,Y)
Arguments
- S
the number of block rows in the block-Hankel matrices.
- Y
- U
- METH
an option for the method to use:
- 1
MOESP method with past inputs and outputs;
- 2
N4SI15 0 1 1 1000D method.
Default: METH = 1.
- ALG
an option for the algorithm to compute the triangular factor of the concatenated block-Hankel matrices built from the input-output data:
- 1
Cholesky algorithm on the correlation matrix;
- 2
fast QR algorithm;
- 3
standard QR algorithm.
Default: ALG = 1.
- JOBD
an option to specify if the matrices B and D should later be computed using the MOESP approach:
- =
1 : the matrices B and D should later be computed using the MOESP approach;
- =
2 : the matrices B and D should not be computed using the MOESP approach.
Default: JOBD = 2. This parameter is not relevant for METH = 2.
- TOL
a vector of length 2 containing tolerances:
- TOL
(1) is the tolerance for estimating the rank of matrices. If TOL(1) > 0, the given value of TOL(1) is used as a lower bound for the reciprocal condition number.
Default: TOL(1) = prod(size(matrix))*epsilon_machine where epsilon_machine is the relative machine precision.
- TOL
(2) is the tolerance for estimating the system order. If TOL(2) >= 0, the estimate is indicated by the index of the last singular value greater than or equal to TOL(2). (Singular values less than TOL(2) are considered as zero.)
When TOL(2) = 0, then S*epsilon_machine*sval(1) is used instead TOL(2), where sval(1) is the maximal singular value. When TOL(2) < 0, the estimate is indicated by the index of the singular value that has the largest logarithmic gap to its successor. Default: TOL(2) = -1.
- PRINTW
a switch for printing the warning messages.
- =
1: print warning messages;
- =
0: do not print warning messages.
Default: PRINTW = 0.
- R
- N
the order of the discrete-time realization
- SVAL
singular values SVAL, used for estimating the order.
- RCND
vector of length 2 containing the reciprocal condition numbers of the matrices involved in rank decisions or least squares solutions.
Description
findR Preprocesses the input-output data for estimating the matrices of a linear time-invariant dynamical system, using Cholesky or (fast) QR factorization and subspace identification techniques (MOESP or N4SID), and estimates the system order.
[R,N] = findR(S,Y,U,METH,ALG,JOBD,TOL,PRINTW) returns the processed upper triangular factor R of the concatenated block-Hankel matrices built from the input-output data, and the order N of a discrete-time realization. The model structure is:
x(k+1) = Ax(k) + Bu(k) + w(k), k >= 1, y(k) = Cx(k) + Du(k) + e(k).
The vectors y(k) and u(k) are transposes of the k-th rows of Y and U, respectively.
[R,N,SVAL,RCND] = findR(S,Y,U,METH,ALG,JOBD,TOL,PRINTW) also returns the singular values SVAL, used for estimating the order, as well as, if meth = 2, the vector RCND of length 2 containing the reciprocal condition numbers of the matrices involved in rank decisions or least squares solutions.
[R,N] = findR(S,Y) assumes U = [] and default values for the remaining input arguments.
Examples
//generate data from a given linear system A = [ 0.5, 0.1,-0.1, 0.2; 0.1, 0, -0.1,-0.1; -0.4,-0.6,-0.7,-0.1; 0.8, 0, -0.6,-0.6]; B = [0.8;0.1;1;-1]; C = [1 2 -1 0]; SYS=syslin(0.1,A,B,C); U=(ones(1,1000)+rand(1,1000,'normal')); Y=(flts(U,SYS)+0.5*rand(1,1000,'normal')); // Compute R [R,N,SVAL] = findR(15,Y',U'); SVAL N
See Also
- findABCD — discrete-time system subspace identification
- findAC — discrete-time system subspace identification
- findBD — initial state and system matrices B and D of a discrete-time system
- findBDK — Kalman gain and B D system matrices of a discrete-time system
- sorder — computing the order of a discrete-time system
- sident — discrete-time state-space realization and Kalman gain
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