CGEDMD computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, CGEDMD computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular


    vectors of X. Optionally, CGEDMD returns the residuals


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L.


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations


    expressed in this material are those of the author and


    do not necessarily reflect the views of the DARPA SBIR


    Program Office

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix.


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'N' :: No data scaling.

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product X(:,1:K)*W, where X


           contains a POD basis (leading left singular vectors


           of the data matrix X) and W contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of K, X, W, Z.


    'N' :: The eigenvectors are not computed.

JOBR

    JOBR (input) CHARACTER*1


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will be


           computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: CGESVD (the QR SVD algorithm)


    2 :: CGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: CGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: CGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M>= 0


    The state space dimension (the row dimension of X, Y).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshot pairs


    (the number of columns of X and Y).

X

    X (input/output) COMPLEX(KIND=WP) M-by-N array


    > On entry, X contains the data snapshot matrix X. It is


    assumed that the column norms of X are in the range of


    the normalized floating point numbers.


    < On exit, the leading K columns of X contain a POD basis,


    i.e. the leading K left singular vectors of the input


    data matrix X, U(:,1:K). All N columns of X contain all


    left singular vectors of the input matrix X.


    See the descriptions of K, Z and W.

LDX

    LDX (input) INTEGER, LDX >= M


    The leading dimension of the array X.

Y

    Y (input/workspace/output) COMPLEX(KIND=WP) M-by-N array


    > On entry, Y contains the data snapshot matrix Y


    < On exit,


    If JOBR == 'R', the leading K columns of Y  contain


    the residual vectors for the computed Ritz pairs.


    See the description of RES.


    If JOBR == 'N', Y contains the original input data,


                    scaled according to the value of JOBS.

LDY

    LDY (input) INTEGER , LDY >= M


    The leading dimension of the array Y.

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.


    The numerical rank can be enforced by using positive


    value of NRNK as follows:


    0 < NRNK <= N :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the descriptions of TOL and  K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.

K

    K (output) INTEGER,  0 <= K <= N


    The dimension of the POD basis for the data snapshot


    matrix X and the number of the computed Ritz pairs.


    The value of K is determined according to the rule set


    by the parameters NRNK and TOL.


    See the descriptions of NRNK and TOL.

EIGS

    EIGS (output) COMPLEX(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of EIGS contain


    the computed eigenvalues (Ritz values).


    See the descriptions of K, and Z.

Z

    Z (workspace/output) COMPLEX(KIND=WP)  M-by-N array


    If JOBZ =='V' then Z contains the  Ritz vectors.  Z(:,i)


    is an eigenvector of the i-th Ritz value; ||Z(:,i)||_2=1.


    If JOBZ == 'F', then the Z(:,i)'s are given implicitly as


    the columns of X(:,1:K)*W(1:K,1:K), i.e. X(:,1:K)*W(:,i)


    is an eigenvector corresponding to EIGS(i). The columns


    of W(1:k,1:K) are the computed eigenvectors of the


    K-by-K Rayleigh quotient.


    See the descriptions of EIGS, X and W.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) N-by-1 array


    RES(1:K) contains the residuals for the K computed


    Ritz pairs,


    RES(i) = || A * Z(:,i) - EIGS(i)*Z(:,i))||_2.


    See the description of EIGS and Z.

B

    B (output) COMPLEX(KIND=WP)  M-by-N array.


    IF JOBF =='R', B(1:M,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further


    details in the provided references.


    If JOBF == 'E', B(1:M,1:K) contains


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.


    If JOBF =='N', then B is not referenced.


    See the descriptions of X, W, K.

LDB

    LDB (input) INTEGER, LDB >= M


    The leading dimension of the array B.

W

    W (workspace/output) COMPLEX(KIND=WP) N-by-N array


    On exit, W(1:K,1:K) contains the K computed


    eigenvectors of the matrix Rayleigh quotient.


    The Ritz vectors (returned in Z) are the


    product of X (containing a POD basis for the input


    matrix X) and W. See the descriptions of K, S, X and Z.


    W is also used as a workspace to temporarily store the


    right singular vectors of X.

LDW

    LDW (input) INTEGER, LDW >= N


    The leading dimension of the array W.

S

    S (workspace/output) COMPLEX(KIND=WP) N-by-N array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by CGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N


    The leading dimension of the array S.

ZWORK

    ZWORK (workspace/output) COMPLEX(KIND=WP) LZWORK-by-1 array


    ZWORK is used as complex workspace in the complex SVD, as


    specified by WHTSVD (1,2, 3 or 4) and for CGEEV for computing


    the eigenvalues of a Rayleigh quotient.


    If the call to CGEDMD is only workspace query, then


    ZWORK(1) contains the minimal complex workspace length and


    ZWORK(2) is the optimal complex workspace length.


    Hence, the length of work is at least 2.


    See the description of LZWORK.

LZWORK

    LZWORK (input) INTEGER


    The minimal length of the workspace vector ZWORK.


    LZWORK is calculated as MAX(LZWORK_SVD, LZWORK_CGEEV),


    where LZWORK_CGEEV = MAX( 1, 2*N )  and the minimal


    LZWORK_SVD is calculated as follows


    If WHTSVD == 1 :: CGESVD ::


       LZWORK_SVD = MAX(1,2*MIN(M,N)+MAX(M,N))


    If WHTSVD == 2 :: CGESDD ::


       LZWORK_SVD = 2*MIN(M,N)*MIN(M,N)+2*MIN(M,N)+MAX(M,N)


    If WHTSVD == 3 :: CGESVDQ ::


       LZWORK_SVD = obtainable by a query


    If WHTSVD == 4 :: CGEJSV ::


       LZWORK_SVD = obtainable by a query


    If on entry LZWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths and returns them in


    LZWORK(1) and LZWORK(2), respectively.

RWORK

    RWORK (workspace/output) REAL(KIND=WP) LRWORK-by-1 array


    On exit, RWORK(1:N) contains the singular values of


    X (for JOBS=='N') or column scaled X (JOBS=='S', 'C').


    If WHTSVD==4, then RWORK(N+1) and RWORK(N+2) contain


    scaling factor RWORK(N+2)/RWORK(N+1) used to scale X


    and Y to avoid overflow in the SVD of X.


    This may be of interest if the scaling option is off


    and as many as possible smallest eigenvalues are


    desired to the highest feasible accuracy.


    If the call to CGEDMD is only workspace query, then


    RWORK(1) contains the minimal workspace length.


    See the description of LRWORK.

LRWORK

    LRWORK (input) INTEGER


    The minimal length of the workspace vector RWORK.


    LRWORK is calculated as follows:


    LRWORK = MAX(1, N+LRWORK_SVD,N+LRWORK_CGEEV), where


    LRWORK_CGEEV = MAX(1,2*N) and RWORK_SVD is the real workspace


    for the SVD subroutine determined by the input parameter


    WHTSVD.


    If WHTSVD == 1 :: CGESVD ::


       LRWORK_SVD = 5*MIN(M,N)


    If WHTSVD == 2 :: CGESDD ::


       LRWORK_SVD =  MAX(5*MIN(M,N)*MIN(M,N)+7*MIN(M,N),


       2*MAX(M,N)*MIN(M,N)+2*MIN(M,N)*MIN(M,N)+MIN(M,N) ) )


    If WHTSVD == 3 :: CGESVDQ ::


       LRWORK_SVD = obtainable by a query


    If WHTSVD == 4 :: CGEJSV ::


       LRWORK_SVD = obtainable by a query


    If on entry LRWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    real workspace length and returns it in RWORK(1).

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M,N))


    If WHTSVD == 3, then LIWORK >= MAX(1,M+N-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M+3*N)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for  ZWORK, RWORK and


    IWORK. See the descriptions of ZWORK, RWORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.

Zlatko Drmac

    CGEDMDQ computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices, using a QR factorization


    based compression of the data. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, CGEDMDQ computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular 


    vectors of X. Optionally, CGEDMDQ returns the residuals 


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].      

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.      


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L. 


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations 


    expressed in this material are those of the author and 


    do not necessarily reflect the views of the DARPA SBIR 


    Program Office.      

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022      

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix. The data snapshots are the columns


    of F. The leading N-1 columns of F are denoted X and the


    trailing N-1 columns are denoted Y. 


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)    


    'N' :: No data scaling.   

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Z*V, where Z


           is orthonormal and V contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of F, V, Z.


    'Q' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Q*Z, where Z


           contains the eigenvectors of the compression of the


           underlying discretised operator onto the span of


           the data snapshots. See the descriptions of F, V, Z.   


           Q is from the inital QR facorization.    


    'N' :: The eigenvectors are not computed.  

JOBR

    JOBR (input) CHARACTER*1 


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will


           be computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBQ

    JOBQ (input) CHARACTER*1 


    Specifies whether to explicitly compute and return the


    unitary matrix from the QR factorization.


    'Q' :: The matrix Q of the QR factorization of the data


           snapshot matrix is computed and stored in the


           array F. See the description of F.       


    'N' :: The matrix Q is not explicitly computed.

JOBT

    JOBT (input) CHARACTER*1 


    Specifies whether to return the upper triangular factor


    from the QR factorization.


    'R' :: The matrix R of the QR factorization of the data 


           snapshot matrix F is returned in the array Y.


           See the description of Y and Further details.       


    'N' :: The matrix R is not returned. 

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are 


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.   


    To be useful on exit, this option needs JOBQ='Q'.    

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: CGESVD (the QR SVD algorithm)


    2 :: CGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: CGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: CGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger 


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M >= 0 


    The state space dimension (the number of rows of F).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshots from a single trajectory,


    taken at equidistant discrete times. This is the 


    number of columns of F.

F

    F (input/output) COMPLEX(KIND=WP) M-by-N array


    > On entry,


    the columns of F are the sequence of data snapshots 


    from a single trajectory, taken at equidistant discrete


    times. It is assumed that the column norms of F are 


    in the range of the normalized floating point numbers. 


    < On exit,


    If JOBQ == 'Q', the array F contains the orthogonal 


    matrix/factor of the QR factorization of the initial 


    data snapshots matrix F. See the description of JOBQ. 


    If JOBQ == 'N', the entries in F strictly below the main


    diagonal contain, column-wise, the information on the 


    Householder vectors, as returned by CGEQRF. The 


    remaining information to restore the orthogonal matrix


    of the initial QR factorization is stored in ZWORK(1:MIN(M,N)). 


    See the description of ZWORK.

LDF

    LDF (input) INTEGER, LDF >= M 


    The leading dimension of the array F.

X

    X (workspace/output) COMPLEX(KIND=WP) MIN(M,N)-by-(N-1) array


    X is used as workspace to hold representations of the


    leading N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, the leading K columns of X contain the leading


    K left singular vectors of the above described content


    of X. To lift them to the space of the left singular


    vectors U(:,1:K) of the input data, pre-multiply with the 


    Q factor from the initial QR factorization. 


    See the descriptions of F, K, V  and Z.

LDX

    LDX (input) INTEGER, LDX >= N  


    The leading dimension of the array X. 

Y

    Y (workspace/output) COMPLEX(KIND=WP) MIN(M,N)-by-(N) array


    Y is used as workspace to hold representations of the


    trailing N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, 


    If JOBT == 'R', Y contains the MIN(M,N)-by-N upper


    triangular factor from the QR factorization of the data


    snapshot matrix F.

LDY

    LDY (input) INTEGER , LDY >= N


    The leading dimension of the array Y.   

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.      


    The numerical rank can be enforced by using positive 


    value of NRNK as follows: 


    0 < NRNK <= N-1 :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the description of K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.  

K

    K (output) INTEGER,  0 <= K <= N 


    The dimension of the SVD/POD basis for the leading N-1


    data snapshots (columns of F) and the number of the 


    computed Ritz pairs. The value of K is determined


    according to the rule set by the parameters NRNK and 


    TOL. See the descriptions of NRNK and TOL. 

EIGS

    EIGS (output) COMPLEX(KIND=WP) (N-1)-by-1 array


    The leading K (K<=N-1) entries of EIGS contain


    the computed eigenvalues (Ritz values).


    See the descriptions of K, and Z.

Z

    Z (workspace/output) COMPLEX(KIND=WP)  M-by-(N-1) array


    If JOBZ =='V' then Z contains the Ritz vectors. Z(:,i)


    is an eigenvector of the i-th Ritz value; ||Z(:,i)||_2=1.


    If JOBZ == 'F', then the Z(:,i)'s are given implicitly as


    Z*V, where Z contains orthonormal matrix (the product of


    Q from the initial QR factorization and the SVD/POD_basis


    returned by CGEDMD in X) and the second factor (the 


    eigenvectors of the Rayleigh quotient) is in the array V, 


    as returned by CGEDMD. That is,  X(:,1:K)*V(:,i)


    is an eigenvector corresponding to EIGS(i). The columns 


    of V(1:K,1:K) are the computed eigenvectors of the 


    K-by-K Rayleigh quotient.  


    See the descriptions of EIGS, X and V.      

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) (N-1)-by-1 array


    RES(1:K) contains the residuals for the K computed 


    Ritz pairs, 


    RES(i) = || A * Z(:,i) - EIGS(i)*Z(:,i))||_2.


    See the description of EIGS and Z.      

B

    B (output) COMPLEX(KIND=WP)  MIN(M,N)-by-(N-1) array.


    IF JOBF =='R', B(1:N,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further 


    details in the provided references. 


    If JOBF == 'E', B(1:N,1;K) contains 


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.   


    In both cases, the content of B can be lifted to the 


    original dimension of the input data by pre-multiplying


    with the Q factor from the initial QR factorization. 


    Here A denotes a compression of the underlying operator.      


    See the descriptions of F and X.


    If JOBF =='N', then B is not referenced.

LDB

    LDB (input) INTEGER, LDB >= MIN(M,N)


    The leading dimension of the array B.

V

    V (workspace/output) COMPLEX(KIND=WP) (N-1)-by-(N-1) array


    On exit, V(1:K,1:K) V contains the K eigenvectors of


    the Rayleigh quotient. The Ritz vectors


    (returned in Z) are the product of Q from the initial QR


    factorization (see the description of F) X (see the 


    description of X) and V.

LDV

    LDV (input) INTEGER, LDV >= N-1


    The leading dimension of the array V.

S

    S (output) COMPLEX(KIND=WP) (N-1)-by-(N-1) array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by CGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N-1        


    The leading dimension of the array S.

LZWORK

    ZWORK (workspace/output) COMPLEX(KIND=WP) LWORK-by-1 array


    On exit, 


    ZWORK(1:MIN(M,N)) contains the scalar factors of the 


    elementary reflectors as returned by CGEQRF of the 


    M-by-N input matrix F.   


    If the call to CGEDMDQ is only workspace query, then


    ZWORK(1) contains the minimal complex workspace length and


    ZWORK(2) is the optimal complex workspace length. 


    Hence, the length of work is at least 2.


    See the description of LZWORK.      

LZWORK

    LZWORK (input) INTEGER


    The minimal length of the  workspace vector ZWORK.


    LZWORK is calculated as follows:


    Let MLWQR  = N (minimal workspace for CGEQRF[M,N])


        MLWDMD = minimal workspace for CGEDMD (see the


                 description of LWORK in CGEDMD)


        MLWMQR = N (minimal workspace for 


                   ZUNMQR['L','N',M,N,N])


        MLWGQR = N (minimal workspace for ZUNGQR[M,N,N])


        MINMN  = MIN(M,N)      


    Then


    LZWORK = MAX(2, MIN(M,N)+MLWQR, MINMN+MLWDMD)


    is further updated as follows:


       if   JOBZ == 'V' or JOBZ == 'F' THEN 


            LZWORK = MAX( LZWORK, MINMN+MLWMQR )


       if   JOBQ == 'Q' THEN


            LZWORK = MAX( ZLWORK, MINMN+MLWGQR)      

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit,


    WORK(1:N-1) contains the singular values of 


    the input submatrix F(1:M,1:N-1).


    If the call to CGEDMDQ is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. hence, the


    length of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the  workspace vector WORK.


    LWORK is the same as in CGEDMD, because in CGEDMDQ


    only CGEDMD requires real workspace for snapshots


    of dimensions MIN(M,N)-by-(N-1).


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.          

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    Let M1=MIN(M,N), N1=N-1. Then      


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M,N))


    If WHTSVD == 3, then LIWORK >= MAX(1,M+N-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M+3*N)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.  

Zlatko Drmac

    DGEDMD computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, DGEDMD computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular


    vectors of X. Optionally, DGEDMD returns the residuals


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L.


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations


    expressed in this material are those of the author and


    do not necessarily reflect the views of the DARPA SBIR


    Program Office

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) is CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix.


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'N' :: No data scaling.

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product X(:,1:K)*W, where X


           contains a POD basis (leading left singular vectors


           of the data matrix X) and W contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of K, X, W, Z.


    'N' :: The eigenvectors are not computed.

JOBR

    JOBR (input) CHARACTER*1


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will be


           computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: DGESVD (the QR SVD algorithm)


    2 :: DGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: DGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: DGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M>= 0


    The state space dimension (the row dimension of X, Y).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshot pairs


    (the number of columns of X and Y).

X

    X (input/output) REAL(KIND=WP) M-by-N array


    > On entry, X contains the data snapshot matrix X. It is


    assumed that the column norms of X are in the range of


    the normalized floating point numbers.


    < On exit, the leading K columns of X contain a POD basis,


    i.e. the leading K left singular vectors of the input


    data matrix X, U(:,1:K). All N columns of X contain all


    left singular vectors of the input matrix X.


    See the descriptions of K, Z and W.

LDX

    LDX (input) INTEGER, LDX >= M


    The leading dimension of the array X.

Y

    Y (input/workspace/output) REAL(KIND=WP) M-by-N array


    > On entry, Y contains the data snapshot matrix Y


    < On exit,


    If JOBR == 'R', the leading K columns of Y  contain


    the residual vectors for the computed Ritz pairs.


    See the description of RES.


    If JOBR == 'N', Y contains the original input data,


                    scaled according to the value of JOBS.

LDY

    LDY (input) INTEGER , LDY >= M


    The leading dimension of the array Y.

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1).


                 This option is recommended.


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.


    The numerical rank can be enforced by using positive


    value of NRNK as follows:


    0 < NRNK <= N :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the descriptions of TOL and  K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.

K

    K (output) INTEGER,  0 <= K <= N


    The dimension of the POD basis for the data snapshot


    matrix X and the number of the computed Ritz pairs.


    The value of K is determined according to the rule set


    by the parameters NRNK and TOL.


    See the descriptions of NRNK and TOL.

REIG

    REIG (output) REAL(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of REIG contain


    the real parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    See the descriptions of K, IMEIG, and Z.

IMEIG

    IMEIG (output) REAL(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of IMEIG contain


    the imaginary parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    The eigenvalues are determined as follows:


    If IMEIG(i) == 0, then the corresponding eigenvalue is


    real, LAMBDA(i) = REIG(i).


    If IMEIG(i)>0, then the corresponding complex


    conjugate pair of eigenvalues reads


    LAMBDA(i)   = REIG(i) + sqrt(-1)*IMAG(i)


    LAMBDA(i+1) = REIG(i) - sqrt(-1)*IMAG(i)


    That is, complex conjugate pairs have consecutive


    indices (i,i+1), with the positive imaginary part


    listed first.


    See the descriptions of K, REIG, and Z.

Z

    Z (workspace/output) REAL(KIND=WP)  M-by-N array


    If JOBZ =='V' then


       Z contains real Ritz vectors as follows:


       If IMEIG(i)=0, then Z(:,i) is an eigenvector of


       the i-th Ritz value; ||Z(:,i)||_2=1.


       If IMEIG(i) > 0 (and IMEIG(i+1) < 0) then


       [Z(:,i) Z(:,i+1)] span an invariant subspace and


       the Ritz values extracted from this subspace are


       REIG(i) + sqrt(-1)*IMEIG(i) and


       REIG(i) - sqrt(-1)*IMEIG(i).


       The corresponding eigenvectors are


       Z(:,i) + sqrt(-1)*Z(:,i+1) and


       Z(:,i) - sqrt(-1)*Z(:,i+1), respectively.


       || Z(:,i:i+1)||_F = 1.


    If JOBZ == 'F', then the above descriptions hold for


    the columns of X(:,1:K)*W(1:K,1:K), where the columns


    of W(1:k,1:K) are the computed eigenvectors of the


    K-by-K Rayleigh quotient. The columns of W(1:K,1:K)


    are similarly structured: If IMEIG(i) == 0 then


    X(:,1:K)*W(:,i) is an eigenvector, and if IMEIG(i)>0


    then X(:,1:K)*W(:,i)+sqrt(-1)*X(:,1:K)*W(:,i+1) and


         X(:,1:K)*W(:,i)-sqrt(-1)*X(:,1:K)*W(:,i+1)


    are the eigenvectors of LAMBDA(i), LAMBDA(i+1).


    See the descriptions of REIG, IMEIG, X and W.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) N-by-1 array


    RES(1:K) contains the residuals for the K computed


    Ritz pairs.


    If LAMBDA(i) is real, then


       RES(i) = || A * Z(:,i) - LAMBDA(i)*Z(:,i))||_2.


    If [LAMBDA(i), LAMBDA(i+1)] is a complex conjugate pair


    then


    RES(i)=RES(i+1) = || A * Z(:,i:i+1) - Z(:,i:i+1) *B||_F


    where B = [ real(LAMBDA(i)) imag(LAMBDA(i)) ]


              [-imag(LAMBDA(i)) real(LAMBDA(i)) ].


    It holds that


    RES(i)   = || A*ZC(:,i)   - LAMBDA(i)  *ZC(:,i)   ||_2


    RES(i+1) = || A*ZC(:,i+1) - LAMBDA(i+1)*ZC(:,i+1) ||_2


    where ZC(:,i)   =  Z(:,i) + sqrt(-1)*Z(:,i+1)


          ZC(:,i+1) =  Z(:,i) - sqrt(-1)*Z(:,i+1)


    See the description of REIG, IMEIG and Z.

B

    B (output) REAL(KIND=WP)  M-by-N array.


    IF JOBF =='R', B(1:M,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further


    details in the provided references.


    If JOBF == 'E', B(1:M,1;K) contains


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.


    If JOBF =='N', then B is not referenced.


    See the descriptions of X, W, K.

LDB

    LDB (input) INTEGER, LDB >= M


    The leading dimension of the array B.

W

    W (workspace/output) REAL(KIND=WP) N-by-N array


    On exit, W(1:K,1:K) contains the K computed


    eigenvectors of the matrix Rayleigh quotient (real and


    imaginary parts for each complex conjugate pair of the


    eigenvalues). The Ritz vectors (returned in Z) are the


    product of X (containing a POD basis for the input


    matrix X) and W. See the descriptions of K, S, X and Z.


    W is also used as a workspace to temporarily store the


    right singular vectors of X.

LDW

    LDW (input) INTEGER, LDW >= N


    The leading dimension of the array W.

S

    S (workspace/output) REAL(KIND=WP) N-by-N array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by DGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N


    The leading dimension of the array S.

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit, WORK(1:N) contains the singular values of


    X (for JOBS=='N') or column scaled X (JOBS=='S', 'C').


    If WHTSVD==4, then WORK(N+1) and WORK(N+2) contain


    scaling factor WORK(N+2)/WORK(N+1) used to scale X


    and Y to avoid overflow in the SVD of X.


    This may be of interest if the scaling option is off


    and as many as possible smallest eigenvalues are


    desired to the highest feasible accuracy.


    If the call to DGEDMD is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. Hence, the


    leng of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the workspace vector WORK.


    LWORK is calculated as follows:


    If WHTSVD == 1 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,4*N)).


       If JOBZ == 'N'  then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,3*N)).


       Here LWORK_SVD = MAX(1,3*N+M,5*N) is the minimal


       workspace length of DGESVD.


    If WHTSVD == 2 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,3*N))


       Here LWORK_SVD = MAX(M, 5*N*N+4*N)+3*N*N is the


       minimal workspace length of DGESDD.


    If WHTSVD == 3 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,3*N))


       Here LWORK_SVD = N+M+MAX(3*N+1,


                       MAX(1,3*N+M,5*N),MAX(1,N))


       is the minimal workspace length of DGESVDQ.


    If WHTSVD == 4 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,3*N))


       Here LWORK_SVD = MAX(7,2*M+N,6*N+2*N*N) is the


       minimal workspace length of DGEJSV.


    The above expressions are not simplified in order to


    make the usage of WORK more transparent, and for


    easier checking. In any case, LWORK >= 2.


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M,N))


    If WHTSVD == 3, then LIWORK >= MAX(1,M+N-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M+3*N)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.

Zlatko Drmac

     DGEDMDQ computes the Dynamic Mode Decomposition (DMD) for


     a pair of data snapshot matrices, using a QR factorization


     based compression of the data. For the input matrices


     X and Y such that Y = A*X with an unaccessible matrix


     A, DGEDMDQ computes a certain number of Ritz pairs of A using


     the standard Rayleigh-Ritz extraction from a subspace of


     range(X) that is determined using the leading left singular 


     vectors of X. Optionally, DGEDMDQ returns the residuals 


     of the computed Ritz pairs, the information needed for


     a refinement of the Ritz vectors, or the eigenvectors of


     the Exact DMD.


     For further details see the references listed


     below. For more details of the implementation see [3].      

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.      


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L. 


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations 


    expressed in this material are those of the author and 


    do not necessarily reflect the views of the DARPA SBIR 


    Program Office.      

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022  

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix. The data snapshots are the columns


    of F. The leading N-1 columns of F are denoted X and the


    trailing N-1 columns are denoted Y. 


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)    


    'N' :: No data scaling.   

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Z*V, where Z


           is orthonormal and V contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of F, V, Z.


    'Q' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Q*Z, where Z


           contains the eigenvectors of the compression of the


           underlying discretized operator onto the span of


           the data snapshots. See the descriptions of F, V, Z.  


           Q is from the initial QR factorization.      


    'N' :: The eigenvectors are not computed.  

JOBR

    JOBR (input) CHARACTER*1 


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will


           be computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBQ

    JOBQ (input) CHARACTER*1 


    Specifies whether to explicitly compute and return the


    orthogonal matrix from the QR factorization.


    'Q' :: The matrix Q of the QR factorization of the data


           snapshot matrix is computed and stored in the


           array F. See the description of F.       


    'N' :: The matrix Q is not explicitly computed.

JOBT

    JOBT (input) CHARACTER*1 


    Specifies whether to return the upper triangular factor


    from the QR factorization.


    'R' :: The matrix R of the QR factorization of the data 


           snapshot matrix F is returned in the array Y.


           See the description of Y and Further details.       


    'N' :: The matrix R is not returned.    

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are 


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.


    To be useful on exit, this option needs JOBQ='Q'.

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: DGESVD (the QR SVD algorithm)


    2 :: DGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: DGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: DGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger 


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M >= 0 


    The state space dimension (the number of rows of F).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshots from a single trajectory,


    taken at equidistant discrete times. This is the 


    number of columns of F.

F

    F (input/output) REAL(KIND=WP) M-by-N array


    > On entry,


    the columns of F are the sequence of data snapshots 


    from a single trajectory, taken at equidistant discrete


    times. It is assumed that the column norms of F are 


    in the range of the normalized floating point numbers. 


    < On exit,


    If JOBQ == 'Q', the array F contains the orthogonal 


    matrix/factor of the QR factorization of the initial 


    data snapshots matrix F. See the description of JOBQ. 


    If JOBQ == 'N', the entries in F strictly below the main


    diagonal contain, column-wise, the information on the 


    Householder vectors, as returned by DGEQRF. The 


    remaining information to restore the orthogonal matrix


    of the initial QR factorization is stored in WORK(1:N). 


    See the description of WORK.

LDF

    LDF (input) INTEGER, LDF >= M 


    The leading dimension of the array F.

X

    X (workspace/output) REAL(KIND=WP) MIN(M,N)-by-(N-1) array


    X is used as workspace to hold representations of the


    leading N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, the leading K columns of X contain the leading


    K left singular vectors of the above described content


    of X. To lift them to the space of the left singular


    vectors U(:,1:K)of the input data, pre-multiply with the 


    Q factor from the initial QR factorization. 


    See the descriptions of F, K, V  and Z.

LDX

    LDX (input) INTEGER, LDX >= N  


    The leading dimension of the array X. 

Y

    Y (workspace/output) REAL(KIND=WP) MIN(M,N)-by-(N-1) array


    Y is used as workspace to hold representations of the


    trailing N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, 


    If JOBT == 'R', Y contains the MIN(M,N)-by-N upper


    triangular factor from the QR factorization of the data


    snapshot matrix F.

LDY

    LDY (input) INTEGER , LDY >= N


    The leading dimension of the array Y.   

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.  


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.       


    The numerical rank can be enforced by using positive 


    value of NRNK as follows: 


    0 < NRNK <= N-1 :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the description of K.

TOL

     TOL (input) REAL(KIND=WP), 0 <= TOL < 1


     The tolerance for truncating small singular values.


     See the description of NRNK.  

K

     K (output) INTEGER,  0 <= K <= N 


     The dimension of the SVD/POD basis for the leading N-1


     data snapshots (columns of F) and the number of the 


     computed Ritz pairs. The value of K is determined


     according to the rule set by the parameters NRNK and 


     TOL. See the descriptions of NRNK and TOL. 

REIG

    REIG (output) REAL(KIND=WP) (N-1)-by-1 array


    The leading K (K<=N) entries of REIG contain


    the real parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    See the descriptions of K, IMEIG, Z.

IMEIG

    IMEIG (output) REAL(KIND=WP) (N-1)-by-1 array


    The leading K (K<N) entries of REIG contain


    the imaginary parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    The eigenvalues are determined as follows:


    If IMEIG(i) == 0, then the corresponding eigenvalue is


    real, LAMBDA(i) = REIG(i).


    If IMEIG(i)>0, then the corresponding complex


    conjugate pair of eigenvalues reads


    LAMBDA(i)   = REIG(i) + sqrt(-1)*IMAG(i)


    LAMBDA(i+1) = REIG(i) - sqrt(-1)*IMAG(i)


    That is, complex conjugate pairs have consequtive


    indices (i,i+1), with the positive imaginary part


    listed first.


    See the descriptions of K, REIG, Z.     

Z

    Z (workspace/output) REAL(KIND=WP)  M-by-(N-1) array


    If JOBZ =='V' then


       Z contains real Ritz vectors as follows:


       If IMEIG(i)=0, then Z(:,i) is an eigenvector of


       the i-th Ritz value.


       If IMEIG(i) > 0 (and IMEIG(i+1) < 0) then


       [Z(:,i) Z(:,i+1)] span an invariant subspace and


       the Ritz values extracted from this subspace are


       REIG(i) + sqrt(-1)*IMEIG(i) and


       REIG(i) - sqrt(-1)*IMEIG(i).


       The corresponding eigenvectors are


       Z(:,i) + sqrt(-1)*Z(:,i+1) and


       Z(:,i) - sqrt(-1)*Z(:,i+1), respectively.


    If JOBZ == 'F', then the above descriptions hold for


    the columns of Z*V, where the columns of V are the


    eigenvectors of the K-by-K Rayleigh quotient, and Z is


    orthonormal. The columns of V are similarly structured:


    If IMEIG(i) == 0 then Z*V(:,i) is an eigenvector, and if 


    IMEIG(i) > 0 then Z*V(:,i)+sqrt(-1)*Z*V(:,i+1) and


                      Z*V(:,i)-sqrt(-1)*Z*V(:,i+1)


    are the eigenvectors of LAMBDA(i), LAMBDA(i+1).


    See the descriptions of REIG, IMEIG, X and V.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) (N-1)-by-1 array


    RES(1:K) contains the residuals for the K computed 


    Ritz pairs.       


    If LAMBDA(i) is real, then


       RES(i) = || A * Z(:,i) - LAMBDA(i)*Z(:,i))||_2.


    If [LAMBDA(i), LAMBDA(i+1)] is a complex conjugate pair


    then


    RES(i)=RES(i+1) = || A * Z(:,i:i+1) - Z(:,i:i+1) *B||_F


    where B = [ real(LAMBDA(i)) imag(LAMBDA(i)) ]


              [-imag(LAMBDA(i)) real(LAMBDA(i)) ].


    It holds that


    RES(i)   = || A*ZC(:,i)   - LAMBDA(i)  *ZC(:,i)   ||_2


    RES(i+1) = || A*ZC(:,i+1) - LAMBDA(i+1)*ZC(:,i+1) ||_2


    where ZC(:,i)   =  Z(:,i) + sqrt(-1)*Z(:,i+1)


          ZC(:,i+1) =  Z(:,i) - sqrt(-1)*Z(:,i+1)


    See the description of Z.

B

    B (output) REAL(KIND=WP)  MIN(M,N)-by-(N-1) array.


    IF JOBF =='R', B(1:N,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further 


    details in the provided references. 


    If JOBF == 'E', B(1:N,1;K) contains 


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.   


    In both cases, the content of B can be lifted to the 


    original dimension of the input data by pre-multiplying


    with the Q factor from the initial QR factorization.


    Here A denotes a compression of the underlying operator.


    See the descriptions of F and X.


    If JOBF =='N', then B is not referenced.

LDB

    LDB (input) INTEGER, LDB >= MIN(M,N)


    The leading dimension of the array B.

V

    V (workspace/output) REAL(KIND=WP) (N-1)-by-(N-1) array


    On exit, V(1:K,1:K) contains the K eigenvectors of


    the Rayleigh quotient. The eigenvectors of a complex


    conjugate pair of eigenvalues are returned in real form


    as explained in the description of Z. The Ritz vectors


    (returned in Z) are the product of X and V; see


    the descriptions of X and Z.

LDV

    LDV (input) INTEGER, LDV >= N-1


    The leading dimension of the array V.

S

    S (output) REAL(KIND=WP) (N-1)-by-(N-1) array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by DGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N-1        


    The leading dimension of the array S.

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit, 


    WORK(1:MIN(M,N)) contains the scalar factors of the 


    elementary reflectors as returned by DGEQRF of the 


    M-by-N input matrix F.


    WORK(MIN(M,N)+1:MIN(M,N)+N-1) contains the singular values of 


    the input submatrix F(1:M,1:N-1).


    If the call to DGEDMDQ is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. Hence, the


    length of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the  workspace vector WORK.


    LWORK is calculated as follows:


    Let MLWQR  = N (minimal workspace for DGEQRF[M,N])


        MLWDMD = minimal workspace for DGEDMD (see the


                 description of LWORK in DGEDMD) for 


                 snapshots of dimensions MIN(M,N)-by-(N-1)


        MLWMQR = N (minimal workspace for 


                   DORMQR['L','N',M,N,N])


        MLWGQR = N (minimal workspace for DORGQR[M,N,N])


    Then


    LWORK = MAX(N+MLWQR, N+MLWDMD)


    is updated as follows:


       if   JOBZ == 'V' or JOBZ == 'F' THEN 


            LWORK = MAX( LWORK, MIN(M,N)+N-1+MLWMQR )


       if   JOBQ == 'Q' THEN


            LWORK = MAX( LWORK, MIN(M,N)+N-1+MLWGQR)


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.          

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    Let M1=MIN(M,N), N1=N-1. Then    


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M1,N1))


    If WHTSVD == 3, then LIWORK >= MAX(1,M1+N1-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M1+3*N1)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.  

Zlatko Drmac

    SGEDMD computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, SGEDMD computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular


    vectors of X. Optionally, SGEDMD returns the residuals


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L.


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations


    expressed in this material are those of the author and


    do not necessarily reflect the views of the DARPA SBIR


    Program Office

    Distribution Statement A:


    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix.


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'N' :: No data scaling.

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product X(:,1:K)*W, where X


           contains a POD basis (leading left singular vectors


           of the data matrix X) and W contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of K, X, W, Z.


    'N' :: The eigenvectors are not computed.

JOBR

    JOBR (input) CHARACTER*1


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will be


           computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: SGESVD (the QR SVD algorithm)


    2 :: SGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: SGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: SGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M>= 0


    The state space dimension (the row dimension of X, Y).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshot pairs


    (the number of columns of X and Y).

X

    X (input/output) REAL(KIND=WP) M-by-N array


    > On entry, X contains the data snapshot matrix X. It is


    assumed that the column norms of X are in the range of


    the normalized floating point numbers.


    < On exit, the leading K columns of X contain a POD basis,


    i.e. the leading K left singular vectors of the input


    data matrix X, U(:,1:K). All N columns of X contain all


    left singular vectors of the input matrix X.


    See the descriptions of K, Z and W.

LDX

    LDX (input) INTEGER, LDX >= M


    The leading dimension of the array X.

Y

    Y (input/workspace/output) REAL(KIND=WP) M-by-N array


    > On entry, Y contains the data snapshot matrix Y


    < On exit,


    If JOBR == 'R', the leading K columns of Y  contain


    the residual vectors for the computed Ritz pairs.


    See the description of RES.


    If JOBR == 'N', Y contains the original input data,


                    scaled according to the value of JOBS.

LDY

    LDY (input) INTEGER , LDY >= M


    The leading dimension of the array Y.

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.


    The numerical rank can be enforced by using positive


    value of NRNK as follows:


    0 < NRNK <= N :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the descriptions of TOL and  K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.

K

    K (output) INTEGER,  0 <= K <= N


    The dimension of the POD basis for the data snapshot


    matrix X and the number of the computed Ritz pairs.


    The value of K is determined according to the rule set


    by the parameters NRNK and TOL.


    See the descriptions of NRNK and TOL.

REIG

    REIG (output) REAL(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of REIG contain


    the real parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    See the descriptions of K, IMEIG, and Z.

IMEIG

    IMEIG (output) REAL(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of IMEIG contain


    the imaginary parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    The eigenvalues are determined as follows:


    If IMEIG(i) == 0, then the corresponding eigenvalue is


    real, LAMBDA(i) = REIG(i).


    If IMEIG(i)>0, then the corresponding complex


    conjugate pair of eigenvalues reads


    LAMBDA(i)   = REIG(i) + sqrt(-1)*IMAG(i)


    LAMBDA(i+1) = REIG(i) - sqrt(-1)*IMAG(i)


    That is, complex conjugate pairs have consecutive


    indices (i,i+1), with the positive imaginary part


    listed first.


    See the descriptions of K, REIG, and Z.

Z

    Z (workspace/output) REAL(KIND=WP)  M-by-N array


    If JOBZ =='V' then


       Z contains real Ritz vectors as follows:


       If IMEIG(i)=0, then Z(:,i) is an eigenvector of


       the i-th Ritz value; ||Z(:,i)||_2=1.


       If IMEIG(i) > 0 (and IMEIG(i+1) < 0) then


       [Z(:,i) Z(:,i+1)] span an invariant subspace and


       the Ritz values extracted from this subspace are


       REIG(i) + sqrt(-1)*IMEIG(i) and


       REIG(i) - sqrt(-1)*IMEIG(i).


       The corresponding eigenvectors are


       Z(:,i) + sqrt(-1)*Z(:,i+1) and


       Z(:,i) - sqrt(-1)*Z(:,i+1), respectively.


       || Z(:,i:i+1)||_F = 1.


    If JOBZ == 'F', then the above descriptions hold for


    the columns of X(:,1:K)*W(1:K,1:K), where the columns


    of W(1:k,1:K) are the computed eigenvectors of the


    K-by-K Rayleigh quotient. The columns of W(1:K,1:K)


    are similarly structured: If IMEIG(i) == 0 then


    X(:,1:K)*W(:,i) is an eigenvector, and if IMEIG(i)>0


    then X(:,1:K)*W(:,i)+sqrt(-1)*X(:,1:K)*W(:,i+1) and


         X(:,1:K)*W(:,i)-sqrt(-1)*X(:,1:K)*W(:,i+1)


    are the eigenvectors of LAMBDA(i), LAMBDA(i+1).


    See the descriptions of REIG, IMEIG, X and W.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) N-by-1 array


    RES(1:K) contains the residuals for the K computed


    Ritz pairs.


    If LAMBDA(i) is real, then


       RES(i) = || A * Z(:,i) - LAMBDA(i)*Z(:,i))||_2.


    If [LAMBDA(i), LAMBDA(i+1)] is a complex conjugate pair


    then


    RES(i)=RES(i+1) = || A * Z(:,i:i+1) - Z(:,i:i+1) *B||_F


    where B = [ real(LAMBDA(i)) imag(LAMBDA(i)) ]


              [-imag(LAMBDA(i)) real(LAMBDA(i)) ].


    It holds that


    RES(i)   = || A*ZC(:,i)   - LAMBDA(i)  *ZC(:,i)   ||_2


    RES(i+1) = || A*ZC(:,i+1) - LAMBDA(i+1)*ZC(:,i+1) ||_2


    where ZC(:,i)   =  Z(:,i) + sqrt(-1)*Z(:,i+1)


          ZC(:,i+1) =  Z(:,i) - sqrt(-1)*Z(:,i+1)


    See the description of REIG, IMEIG and Z.

B

    B (output) REAL(KIND=WP)  M-by-N array.


    IF JOBF =='R', B(1:M,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further


    details in the provided references.


    If JOBF == 'E', B(1:M,1;K) contains


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.


    If JOBF =='N', then B is not referenced.


    See the descriptions of X, W, K.

LDB

    LDB (input) INTEGER, LDB >= M


    The leading dimension of the array B.

W

    W (workspace/output) REAL(KIND=WP) N-by-N array


    On exit, W(1:K,1:K) contains the K computed


    eigenvectors of the matrix Rayleigh quotient (real and


    imaginary parts for each complex conjugate pair of the


    eigenvalues). The Ritz vectors (returned in Z) are the


    product of X (containing a POD basis for the input


    matrix X) and W. See the descriptions of K, S, X and Z.


    W is also used as a workspace to temporarily store the


    left singular vectors of X.

LDW

    LDW (input) INTEGER, LDW >= N


    The leading dimension of the array W.

S

    S (workspace/output) REAL(KIND=WP) N-by-N array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by SGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N


    The leading dimension of the array S.

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit, WORK(1:N) contains the singular values of


    X (for JOBS=='N') or column scaled X (JOBS=='S', 'C').


    If WHTSVD==4, then WORK(N+1) and WORK(N+2) contain


    scaling factor WORK(N+2)/WORK(N+1) used to scale X


    and Y to avoid overflow in the SVD of X.


    This may be of interest if the scaling option is off


    and as many as possible smallest eigenvalues are


    desired to the highest feasible accuracy.


    If the call to SGEDMD is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. Hence, the


    length of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the workspace vector WORK.


    LWORK is calculated as follows:


    If WHTSVD == 1 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,4*N)).


       If JOBZ == 'N'  then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,3*N)).


       Here LWORK_SVD = MAX(1,3*N+M,5*N) is the minimal


       workspace length of SGESVD.


    If WHTSVD == 2 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N + LWORK_SVD, N+MAX(1,3*N))


       Here LWORK_SVD = MAX(M, 5*N*N+4*N)+3*N*N is the


       minimal workspace length of SGESDD.


    If WHTSVD == 3 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,3*N))


       Here LWORK_SVD = N+M+MAX(3*N+1,


                       MAX(1,3*N+M,5*N),MAX(1,N))


       is the minimal workspace length of SGESVDQ.


    If WHTSVD == 4 ::


       If JOBZ == 'V', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,4*N))


       If JOBZ == 'N', then


       LWORK >= MAX(2, N+LWORK_SVD,N+MAX(1,3*N))


       Here LWORK_SVD = MAX(7,2*M+N,6*N+2*N*N) is the


       minimal workspace length of SGEJSV.


    The above expressions are not simplified in order to


    make the usage of WORK more transparent, and for


    easier checking. In any case, LWORK >= 2.


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M,N))


    If WHTSVD == 3, then LIWORK >= MAX(1,M+N-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M+3*N)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.

Zlatko Drmac

    SGEDMDQ computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices, using a QR factorization


    based compression of the data. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, SGEDMDQ computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular 


    vectors of X. Optionally, SGEDMDQ returns the residuals 


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].      

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.      


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L. 


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations 


    expressed in this material are those of the author and 


    do not necessarily reflect the views of the DARPA SBIR 


    Program Office.      

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix. The data snapshots are the columns


    of F. The leading N-1 columns of F are denoted X and the


    trailing N-1 columns are denoted Y. 


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)    


    'N' :: No data scaling.   

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Z*V, where Z


           is orthonormal and V contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of F, V, Z.


    'Q' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Q*Z, where Z


           contains the eigenvectors of the compression of the


           underlying discretized operator onto the span of


           the data snapshots. See the descriptions of F, V, Z. 


           Q is from the initial QR factorization.  


    'N' :: The eigenvectors are not computed.  

JOBR

    JOBR (input) CHARACTER*1 


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will


           be computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBQ

    JOBQ (input) CHARACTER*1 


    Specifies whether to explicitly compute and return the


    orthogonal matrix from the QR factorization.


    'Q' :: The matrix Q of the QR factorization of the data


           snapshot matrix is computed and stored in the


           array F. See the description of F.       


    'N' :: The matrix Q is not explicitly computed.

JOBT

    JOBT (input) CHARACTER*1 


    Specifies whether to return the upper triangular factor


    from the QR factorization.


    'R' :: The matrix R of the QR factorization of the data 


           snapshot matrix F is returned in the array Y.


           See the description of Y and Further details.       


    'N' :: The matrix R is not returned.    

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are 


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.   


    To be useful on exit, this option needs JOBQ='Q'.      

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: SGESVD (the QR SVD algorithm)


    2 :: SGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: SGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: SGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger 


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M >= 0 


    The state space dimension (the number of rows of F)

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshots from a single trajectory,


    taken at equidistant discrete times. This is the 


    number of columns of F.

F

    F (input/output) REAL(KIND=WP) M-by-N array


    > On entry,


    the columns of F are the sequence of data snapshots 


    from a single trajectory, taken at equidistant discrete


    times. It is assumed that the column norms of F are 


    in the range of the normalized floating point numbers. 


    < On exit,


    If JOBQ == 'Q', the array F contains the orthogonal 


    matrix/factor of the QR factorization of the initial 


    data snapshots matrix F. See the description of JOBQ. 


    If JOBQ == 'N', the entries in F strictly below the main


    diagonal contain, column-wise, the information on the 


    Householder vectors, as returned by SGEQRF. The 


    remaining information to restore the orthogonal matrix


    of the initial QR factorization is stored in WORK(1:N). 


    See the description of WORK.

LDF

    LDF (input) INTEGER, LDF >= M 


    The leading dimension of the array F.

X

    X (workspace/output) REAL(KIND=WP) MIN(M,N)-by-(N-1) array


    X is used as workspace to hold representations of the


    leading N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, the leading K columns of X contain the leading


    K left singular vectors of the above described content


    of X. To lift them to the space of the left singular


    vectors U(:,1:K)of the input data, pre-multiply with the 


    Q factor from the initial QR factorization. 


    See the descriptions of F, K, V  and Z.

LDX

    LDX (input) INTEGER, LDX >= N  


    The leading dimension of the array X 

Y

    Y (workspace/output) REAL(KIND=WP) MIN(M,N)-by-(N-1) array


    Y is used as workspace to hold representations of the


    trailing N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, 


    If JOBT == 'R', Y contains the MIN(M,N)-by-N upper


    triangular factor from the QR factorization of the data


    snapshot matrix F.

LDY

    LDY (input) INTEGER , LDY >= N


    The leading dimension of the array Y   

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.   


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.     


    The numerical rank can be enforced by using positive 


    value of NRNK as follows: 


    0 < NRNK <= N-1 :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the description of K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.  

K

    K (output) INTEGER,  0 <= K <= N 


    The dimension of the SVD/POD basis for the leading N-1


    data snapshots (columns of F) and the number of the 


    computed Ritz pairs. The value of K is determined


    according to the rule set by the parameters NRNK and 


    TOL. See the descriptions of NRNK and TOL. 

REIG

    REIG (output) REAL(KIND=WP) (N-1)-by-1 array


    The leading K (K<=N) entries of REIG contain


    the real parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    See the descriptions of K, IMEIG, Z.

IMEIG

    IMEIG (output) REAL(KIND=WP) (N-1)-by-1 array


    The leading K (K<N) entries of REIG contain


    the imaginary parts of the computed eigenvalues


    REIG(1:K) + sqrt(-1)*IMEIG(1:K).


    The eigenvalues are determined as follows:


    If IMEIG(i) == 0, then the corresponding eigenvalue is


    real, LAMBDA(i) = REIG(i).


    If IMEIG(i)>0, then the corresponding complex


    conjugate pair of eigenvalues reads


    LAMBDA(i)   = REIG(i) + sqrt(-1)*IMAG(i)


    LAMBDA(i+1) = REIG(i) - sqrt(-1)*IMAG(i)


    That is, complex conjugate pairs have consecutive


    indices (i,i+1), with the positive imaginary part


    listed first.


    See the descriptions of K, REIG, Z.     

Z

    Z (workspace/output) REAL(KIND=WP)  M-by-(N-1) array


    If JOBZ =='V' then


       Z contains real Ritz vectors as follows:


       If IMEIG(i)=0, then Z(:,i) is an eigenvector of


       the i-th Ritz value.


       If IMEIG(i) > 0 (and IMEIG(i+1) < 0) then


       [Z(:,i) Z(:,i+1)] span an invariant subspace and


       the Ritz values extracted from this subspace are


       REIG(i) + sqrt(-1)*IMEIG(i) and


       REIG(i) - sqrt(-1)*IMEIG(i).


       The corresponding eigenvectors are


       Z(:,i) + sqrt(-1)*Z(:,i+1) and


       Z(:,i) - sqrt(-1)*Z(:,i+1), respectively.


    If JOBZ == 'F', then the above descriptions hold for


    the columns of Z*V, where the columns of V are the


    eigenvectors of the K-by-K Rayleigh quotient, and Z is


    orthonormal. The columns of V are similarly structured:


    If IMEIG(i) == 0 then Z*V(:,i) is an eigenvector, and if 


    IMEIG(i) > 0 then Z*V(:,i)+sqrt(-1)*Z*V(:,i+1) and


                      Z*V(:,i)-sqrt(-1)*Z*V(:,i+1)


    are the eigenvectors of LAMBDA(i), LAMBDA(i+1).


    See the descriptions of REIG, IMEIG, X and V.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) (N-1)-by-1 array


    RES(1:K) contains the residuals for the K computed 


    Ritz pairs.       


    If LAMBDA(i) is real, then


       RES(i) = || A * Z(:,i) - LAMBDA(i)*Z(:,i))||_2.


    If [LAMBDA(i), LAMBDA(i+1)] is a complex conjugate pair


    then


    RES(i)=RES(i+1) = || A * Z(:,i:i+1) - Z(:,i:i+1) *B||_F


    where B = [ real(LAMBDA(i)) imag(LAMBDA(i)) ]


              [-imag(LAMBDA(i)) real(LAMBDA(i)) ].


    It holds that


    RES(i)   = || A*ZC(:,i)   - LAMBDA(i)  *ZC(:,i)   ||_2


    RES(i+1) = || A*ZC(:,i+1) - LAMBDA(i+1)*ZC(:,i+1) ||_2


    where ZC(:,i)   =  Z(:,i) + sqrt(-1)*Z(:,i+1)


          ZC(:,i+1) =  Z(:,i) - sqrt(-1)*Z(:,i+1)


    See the description of Z.

B

    B (output) REAL(KIND=WP)  MIN(M,N)-by-(N-1) array.


    IF JOBF =='R', B(1:N,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further 


    details in the provided references. 


    If JOBF == 'E', B(1:N,1;K) contains 


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.   


    In both cases, the content of B can be lifted to the 


    original dimension of the input data by pre-multiplying


    with the Q factor from the initial QR factorization.     


    Here A denotes a compression of the underlying operator.      


    See the descriptions of F and X.


    If JOBF =='N', then B is not referenced.

LDB

    LDB (input) INTEGER, LDB >= MIN(M,N)


    The leading dimension of the array B.

V

    V (workspace/output) REAL(KIND=WP) (N-1)-by-(N-1) array


    On exit, V(1:K,1:K) contains the K eigenvectors of


    the Rayleigh quotient. The eigenvectors of a complex


    conjugate pair of eigenvalues are returned in real form


    as explained in the description of Z. The Ritz vectors


    (returned in Z) are the product of X and V; see


    the descriptions of X and Z.

LDV

    LDV (input) INTEGER, LDV >= N-1


    The leading dimension of the array V.

S

    S (output) REAL(KIND=WP) (N-1)-by-(N-1) array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by SGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N-1        


    The leading dimension of the array S.

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit, 


    WORK(1:MIN(M,N)) contains the scalar factors of the 


    elementary reflectors as returned by SGEQRF of the 


    M-by-N input matrix F.


    WORK(MIN(M,N)+1:MIN(M,N)+N-1) contains the singular values of 


    the input submatrix F(1:M,1:N-1).


    If the call to SGEDMDQ is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. Hence, the


    length of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the  workspace vector WORK.


    LWORK is calculated as follows:


    Let MLWQR  = N (minimal workspace for SGEQRF[M,N])


        MLWDMD = minimal workspace for SGEDMD (see the


                 description of LWORK in SGEDMD) for 


                 snapshots of dimensions MIN(M,N)-by-(N-1)


        MLWMQR = N (minimal workspace for 


                   SORMQR['L','N',M,N,N])


        MLWGQR = N (minimal workspace for SORGQR[M,N,N])


    Then


    LWORK = MAX(N+MLWQR, N+MLWDMD)


    is updated as follows:


       if   JOBZ == 'V' or JOBZ == 'F' THEN 


            LWORK = MAX( LWORK,MIN(M,N)+N-1 +MLWMQR )


       if   JOBQ == 'Q' THEN


            LWORK = MAX( LWORK,MIN(M,N)+N-1+MLWGQR)


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.          

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    Let M1=MIN(M,N), N1=N-1. Then


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M1,N1))


    If WHTSVD == 3, then LIWORK >= MAX(1,M1+N1-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M1+3*N1)


    If on entry LIWORK = -1, then a worskpace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.  

Zlatko Drmac

    ZGEDMD computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, ZGEDMD computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular


    vectors of X. Optionally, ZGEDMD returns the residuals


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L.


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations


    expressed in this material are those of the author and


    do not necessarily reflect the views of the DARPA SBIR


    Program Office

    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix.


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'N' :: No data scaling.

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product X(:,1:K)*W, where X


           contains a POD basis (leading left singular vectors


           of the data matrix X) and W contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of K, X, W, Z.


    'N' :: The eigenvectors are not computed.

JOBR

    JOBR (input) CHARACTER*1


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will be


           computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.

WHTSVD

    WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 }


    Allows for a selection of the SVD algorithm from the


    LAPACK library.


    1 :: ZGESVD (the QR SVD algorithm)


    2 :: ZGESDD (the Divide and Conquer algorithm; if enough


         workspace available, this is the fastest option)


    3 :: ZGESVDQ (the preconditioned QR SVD  ; this and 4


         are the most accurate options)


    4 :: ZGEJSV (the preconditioned Jacobi SVD; this and 3


         are the most accurate options)


    For the four methods above, a significant difference in


    the accuracy of small singular values is possible if


    the snapshots vary in norm so that X is severely


    ill-conditioned. If small (smaller than EPS*||X||)


    singular values are of interest and JOBS=='N',  then


    the options (3, 4) give the most accurate results, where


    the option 4 is slightly better and with stronger


    theoretical background.


    If JOBS=='S', i.e. the columns of X will be normalized,


    then all methods give nearly equally accurate results.

M

    M (input) INTEGER, M>= 0


    The state space dimension (the row dimension of X, Y).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshot pairs


    (the number of columns of X and Y).

LDX

    X (input/output) COMPLEX(KIND=WP) M-by-N array


    > On entry, X contains the data snapshot matrix X. It is


    assumed that the column norms of X are in the range of


    the normalized floating point numbers.


    < On exit, the leading K columns of X contain a POD basis,


    i.e. the leading K left singular vectors of the input


    data matrix X, U(:,1:K). All N columns of X contain all


    left singular vectors of the input matrix X.


    See the descriptions of K, Z and W.
LDX (input) INTEGER, LDX >= M


    The leading dimension of the array X.

Y

    Y (input/workspace/output) COMPLEX(KIND=WP) M-by-N array


    > On entry, Y contains the data snapshot matrix Y


    < On exit,


    If JOBR == 'R', the leading K columns of Y  contain


    the residual vectors for the computed Ritz pairs.


    See the description of RES.


    If JOBR == 'N', Y contains the original input data,


                    scaled according to the value of JOBS.

LDY

    LDY (input) INTEGER , LDY >= M


    The leading dimension of the array Y.

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.


    The numerical rank can be enforced by using positive


    value of NRNK as follows:


    0 < NRNK <= N :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the descriptions of TOL and  K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.

K

    K (output) INTEGER,  0 <= K <= N


    The dimension of the POD basis for the data snapshot


    matrix X and the number of the computed Ritz pairs.


    The value of K is determined according to the rule set


    by the parameters NRNK and TOL.


    See the descriptions of NRNK and TOL.

EIGS

    EIGS (output) COMPLEX(KIND=WP) N-by-1 array


    The leading K (K<=N) entries of EIGS contain


    the computed eigenvalues (Ritz values).


    See the descriptions of K, and Z.

Z

    Z (workspace/output) COMPLEX(KIND=WP)  M-by-N array


    If JOBZ =='V' then Z contains the  Ritz vectors.  Z(:,i)


    is an eigenvector of the i-th Ritz value; ||Z(:,i)||_2=1.


    If JOBZ == 'F', then the Z(:,i)'s are given implicitly as


    the columns of X(:,1:K)*W(1:K,1:K), i.e. X(:,1:K)*W(:,i)


    is an eigenvector corresponding to EIGS(i). The columns


    of W(1:k,1:K) are the computed eigenvectors of the


    K-by-K Rayleigh quotient.


    See the descriptions of EIGS, X and W.

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) N-by-1 array


    RES(1:K) contains the residuals for the K computed


    Ritz pairs,


    RES(i) = || A * Z(:,i) - EIGS(i)*Z(:,i))||_2.


    See the description of EIGS and Z.

B

    B (output) COMPLEX(KIND=WP)  M-by-N array.


    IF JOBF =='R', B(1:M,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further


    details in the provided references.


    If JOBF == 'E', B(1:M,1:K) contains


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.


    If JOBF =='N', then B is not referenced.


    See the descriptions of X, W, K.

LDB

    LDB (input) INTEGER, LDB >= M


    The leading dimension of the array B.

W

    W (workspace/output) COMPLEX(KIND=WP) N-by-N array


    On exit, W(1:K,1:K) contains the K computed


    eigenvectors of the matrix Rayleigh quotient.


    The Ritz vectors (returned in Z) are the


    product of X (containing a POD basis for the input


    matrix X) and W. See the descriptions of K, S, X and Z.


    W is also used as a workspace to temporarily store the


    right singular vectors of X.

LDW

    LDW (input) INTEGER, LDW >= N


    The leading dimension of the array W.

S

    S (workspace/output) COMPLEX(KIND=WP) N-by-N array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by ZGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N


    The leading dimension of the array S.

ZWORK

    ZWORK (workspace/output) COMPLEX(KIND=WP) LZWORK-by-1 array


    ZWORK is used as complex workspace in the complex SVD, as


    specified by WHTSVD (1,2, 3 or 4) and for ZGEEV for computing


    the eigenvalues of a Rayleigh quotient.


    If the call to ZGEDMD is only workspace query, then


    ZWORK(1) contains the minimal complex workspace length and


    ZWORK(2) is the optimal complex workspace length.


    Hence, the length of work is at least 2.


    See the description of LZWORK.

LZWORK

    LZWORK (input) INTEGER


    The minimal length of the workspace vector ZWORK.


    LZWORK is calculated as MAX(LZWORK_SVD, LZWORK_ZGEEV),


    where LZWORK_ZGEEV = MAX( 1, 2*N )  and the minimal


    LZWORK_SVD is calculated as follows


    If WHTSVD == 1 :: ZGESVD ::


       LZWORK_SVD = MAX(1,2*MIN(M,N)+MAX(M,N))


    If WHTSVD == 2 :: ZGESDD ::


       LZWORK_SVD = 2*MIN(M,N)*MIN(M,N)+2*MIN(M,N)+MAX(M,N)


    If WHTSVD == 3 :: ZGESVDQ ::


       LZWORK_SVD = obtainable by a query


    If WHTSVD == 4 :: ZGEJSV ::


       LZWORK_SVD = obtainable by a query


    If on entry LZWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths and returns them in


    LZWORK(1) and LZWORK(2), respectively.

RWORK

    RWORK (workspace/output) REAL(KIND=WP) LRWORK-by-1 array


    On exit, RWORK(1:N) contains the singular values of


    X (for JOBS=='N') or column scaled X (JOBS=='S', 'C').


    If WHTSVD==4, then RWORK(N+1) and RWORK(N+2) contain


    scaling factor RWORK(N+2)/RWORK(N+1) used to scale X


    and Y to avoid overflow in the SVD of X.


    This may be of interest if the scaling option is off


    and as many as possible smallest eigenvalues are


    desired to the highest feasible accuracy.


    If the call to ZGEDMD is only workspace query, then


    RWORK(1) contains the minimal workspace length.


    See the description of LRWORK.

LRWORK

    LRWORK (input) INTEGER


    The minimal length of the workspace vector RWORK.


    LRWORK is calculated as follows:


    LRWORK = MAX(1, N+LRWORK_SVD,N+LRWORK_ZGEEV), where


    LRWORK_ZGEEV = MAX(1,2*N) and RWORK_SVD is the real workspace


    for the SVD subroutine determined by the input parameter


    WHTSVD.


    If WHTSVD == 1 :: ZGESVD ::


       LRWORK_SVD = 5*MIN(M,N)


    If WHTSVD == 2 :: ZGESDD ::


       LRWORK_SVD =  MAX(5*MIN(M,N)*MIN(M,N)+7*MIN(M,N),


       2*MAX(M,N)*MIN(M,N)+2*MIN(M,N)*MIN(M,N)+MIN(M,N) ) )


    If WHTSVD == 3 :: ZGESVDQ ::


       LRWORK_SVD = obtainable by a query


    If WHTSVD == 4 :: ZGEJSV ::


       LRWORK_SVD = obtainable by a query


    If on entry LRWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    real workspace length and returns it in RWORK(1).

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M,N))


    If WHTSVD == 3, then LIWORK >= MAX(1,M+N-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M+3*N)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for  ZWORK, RWORK and


    IWORK. See the descriptions of ZWORK, RWORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.

Zlatko Drmac

    ZGEDMDQ computes the Dynamic Mode Decomposition (DMD) for


    a pair of data snapshot matrices, using a QR factorization


    based compression of the data. For the input matrices


    X and Y such that Y = A*X with an unaccessible matrix


    A, ZGEDMDQ computes a certain number of Ritz pairs of A using


    the standard Rayleigh-Ritz extraction from a subspace of


    range(X) that is determined using the leading left singular 


    vectors of X. Optionally, ZGEDMDQ returns the residuals 


    of the computed Ritz pairs, the information needed for


    a refinement of the Ritz vectors, or the eigenvectors of


    the Exact DMD.


    For further details see the references listed


    below. For more details of the implementation see [3].      

    [1] P. Schmid: Dynamic mode decomposition of numerical


        and experimental data,


        Journal of Fluid Mechanics 656, 5-28, 2010.


    [2] Z. Drmac, I. Mezic, R. Mohr: Data driven modal


        decompositions: analysis and enhancements,


        SIAM J. on Sci. Comp. 40 (4), A2253-A2285, 2018.


    [3] Z. Drmac: A LAPACK implementation of the Dynamic


        Mode Decomposition I. Technical report. AIMDyn Inc.


        and LAPACK Working Note 298.      


    [4] J. Tu, C. W. Rowley, D. M. Luchtenburg, S. L. 


        Brunton, N. Kutz: On Dynamic Mode Decomposition:


        Theory and Applications, Journal of Computational


        Dynamics 1(2), 391 -421, 2014.

    Developed and coded by Zlatko Drmac, Faculty of Science,


    University of Zagreb;  drmac@math.hr


    In cooperation with


    AIMdyn Inc., Santa Barbara, CA.


    and supported by


    - DARPA SBIR project 'Koopman Operator-Based Forecasting


    for Nonstationary Processes from Near-Term, Limited


    Observational Data' Contract No: W31P4Q-21-C-0007


    - DARPA PAI project 'Physics-Informed Machine Learning


    Methodologies' Contract No: HR0011-18-9-0033


    - DARPA MoDyL project 'A Data-Driven, Operator-Theoretic


    Framework for Space-Time Analysis of Process Dynamics'


    Contract No: HR0011-16-C-0116


    Any opinions, findings and conclusions or recommendations 


    expressed in this material are those of the author and 


    do not necessarily reflect the views of the DARPA SBIR 


    Program Office.      

    Distribution Statement A: 


    Approved for Public Release, Distribution Unlimited.


    Cleared by DARPA on September 29, 2022

JOBS

    JOBS (input) CHARACTER*1


    Determines whether the initial data snapshots are scaled


    by a diagonal matrix. The data snapshots are the columns


    of F. The leading N-1 columns of F are denoted X and the


    trailing N-1 columns are denoted Y. 


    'S' :: The data snapshots matrices X and Y are multiplied


           with a diagonal matrix D so that X*D has unit


           nonzero columns (in the Euclidean 2-norm)


    'C' :: The snapshots are scaled as with the 'S' option.


           If it is found that an i-th column of X is zero


           vector and the corresponding i-th column of Y is


           non-zero, then the i-th column of Y is set to


           zero and a warning flag is raised.


    'Y' :: The data snapshots matrices X and Y are multiplied


           by a diagonal matrix D so that Y*D has unit


           nonzero columns (in the Euclidean 2-norm)    


    'N' :: No data scaling.   

JOBZ

    JOBZ (input) CHARACTER*1


    Determines whether the eigenvectors (Koopman modes) will


    be computed.


    'V' :: The eigenvectors (Koopman modes) will be computed


           and returned in the matrix Z.


           See the description of Z.


    'F' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Z*V, where Z


           is orthonormal and V contains the eigenvectors


           of the corresponding Rayleigh quotient.


           See the descriptions of F, V, Z.


    'Q' :: The eigenvectors (Koopman modes) will be returned


           in factored form as the product Q*Z, where Z


           contains the eigenvectors of the compression of the


           underlying discretized operator onto the span of


           the data snapshots. See the descriptions of F, V, Z.


           Q is from the initial QR factorization.  


    'N' :: The eigenvectors are not computed.  

JOBR

    JOBR (input) CHARACTER*1 


    Determines whether to compute the residuals.


    'R' :: The residuals for the computed eigenpairs will


           be computed and stored in the array RES.


           See the description of RES.


           For this option to be legal, JOBZ must be 'V'.


    'N' :: The residuals are not computed.

JOBQ

    JOBQ (input) CHARACTER*1 


    Specifies whether to explicitly compute and return the


    unitary matrix from the QR factorization.


    'Q' :: The matrix Q of the QR factorization of the data


           snapshot matrix is computed and stored in the


           array F. See the description of F.       


    'N' :: The matrix Q is not explicitly computed.

JOBT

    JOBT (input) CHARACTER*1 


    Specifies whether to return the upper triangular factor


    from the QR factorization.


    'R' :: The matrix R of the QR factorization of the data 


           snapshot matrix F is returned in the array Y.


           See the description of Y and Further details.       


    'N' :: The matrix R is not returned. 

JOBF

    JOBF (input) CHARACTER*1


    Specifies whether to store information needed for post-


    processing (e.g. computing refined Ritz vectors)


    'R' :: The matrix needed for the refinement of the Ritz


           vectors is computed and stored in the array B.


           See the description of B.


    'E' :: The unscaled eigenvectors of the Exact DMD are 


           computed and returned in the array B. See the


           description of B.


    'N' :: No eigenvector refinement data is computed.   


    To be useful on exit, this option needs JOBQ='Q'.    

WHTSVD WHTSVD (input) INTEGER, WHSTVD in { 1, 2, 3, 4 } Allows for a selection of the SVD algorithm from the LAPACK library. 1 :: ZGESVD (the QR SVD algorithm) 2 :: ZGESDD (the Divide and Conquer algorithm; if enough workspace available, this is the fastest option) 3 :: ZGESVDQ (the preconditioned QR SVD ; this and 4 are the most accurate options) 4 :: ZGEJSV (the preconditioned Jacobi SVD; this and 3 are the most accurate options) For the four methods above, a significant difference in the accuracy of small singular values is possible if the snapshots vary in norm so that X is severely ill-conditioned. If small (smaller than EPS*||X||) singular values are of interest and JOBS=='N', then the options (3, 4) give the most accurate results, where the option 4 is slightly better and with stronger theoretical background. If JOBS=='S', i.e. the columns of X will be normalized, then all methods give nearly equally accurate results.
M

    M (input) INTEGER, M >= 0 


    The state space dimension (the number of rows of F).

N

    N (input) INTEGER, 0 <= N <= M


    The number of data snapshots from a single trajectory,


    taken at equidistant discrete times. This is the 


    number of columns of F.

F

    F (input/output) COMPLEX(KIND=WP) M-by-N array


    > On entry,


    the columns of F are the sequence of data snapshots 


    from a single trajectory, taken at equidistant discrete


    times. It is assumed that the column norms of F are 


    in the range of the normalized floating point numbers. 


    < On exit,


    If JOBQ == 'Q', the array F contains the orthogonal 


    matrix/factor of the QR factorization of the initial 


    data snapshots matrix F. See the description of JOBQ. 


    If JOBQ == 'N', the entries in F strictly below the main


    diagonal contain, column-wise, the information on the 


    Householder vectors, as returned by ZGEQRF. The 


    remaining information to restore the orthogonal matrix


    of the initial QR factorization is stored in ZWORK(1:MIN(M,N)). 


    See the description of ZWORK.

LDF

    LDF (input) INTEGER, LDF >= M 


    The leading dimension of the array F.

X

    X (workspace/output) COMPLEX(KIND=WP) MIN(M,N)-by-(N-1) array


    X is used as workspace to hold representations of the


    leading N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, the leading K columns of X contain the leading


    K left singular vectors of the above described content


    of X. To lift them to the space of the left singular


    vectors U(:,1:K) of the input data, pre-multiply with the 


    Q factor from the initial QR factorization. 


    See the descriptions of F, K, V  and Z.

LDX

    LDX (input) INTEGER, LDX >= N  


    The leading dimension of the array X. 

Y

    Y (workspace/output) COMPLEX(KIND=WP) MIN(M,N)-by-(N) array


    Y is used as workspace to hold representations of the


    trailing N-1 snapshots in the orthonormal basis computed


    in the QR factorization of F.


    On exit, 


    If JOBT == 'R', Y contains the MIN(M,N)-by-N upper


    triangular factor from the QR factorization of the data


    snapshot matrix F.

LDY

    LDY (input) INTEGER , LDY >= N


    The leading dimension of the array Y.   

NRNK

    NRNK (input) INTEGER


    Determines the mode how to compute the numerical rank,


    i.e. how to truncate small singular values of the input


    matrix X. On input, if


    NRNK = -1 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(1)


                 This option is recommended.  


    NRNK = -2 :: i-th singular value sigma(i) is truncated


                 if sigma(i) <= TOL*sigma(i-1)


                 This option is included for R&D purposes.


                 It requires highly accurate SVD, which


                 may not be feasible.      


    The numerical rank can be enforced by using positive 


    value of NRNK as follows: 


    0 < NRNK <= N-1 :: at most NRNK largest singular values


    will be used. If the number of the computed nonzero


    singular values is less than NRNK, then only those


    nonzero values will be used and the actually used


    dimension is less than NRNK. The actual number of


    the nonzero singular values is returned in the variable


    K. See the description of K.

TOL

    TOL (input) REAL(KIND=WP), 0 <= TOL < 1


    The tolerance for truncating small singular values.


    See the description of NRNK.  

K

    K (output) INTEGER,  0 <= K <= N 


    The dimension of the SVD/POD basis for the leading N-1


    data snapshots (columns of F) and the number of the 


    computed Ritz pairs. The value of K is determined


    according to the rule set by the parameters NRNK and 


    TOL. See the descriptions of NRNK and TOL. 

EIGS

    EIGS (output) COMPLEX(KIND=WP) (N-1)-by-1 array


    The leading K (K<=N-1) entries of EIGS contain


    the computed eigenvalues (Ritz values).


    See the descriptions of K, and Z.

Z

    Z (workspace/output) COMPLEX(KIND=WP)  M-by-(N-1) array


    If JOBZ =='V' then Z contains the Ritz vectors. Z(:,i)


    is an eigenvector of the i-th Ritz value; ||Z(:,i)||_2=1.


    If JOBZ == 'F', then the Z(:,i)'s are given implicitly as


    Z*V, where Z contains orthonormal matrix (the product of


    Q from the initial QR factorization and the SVD/POD_basis


    returned by ZGEDMD in X) and the second factor (the 


    eigenvectors of the Rayleigh quotient) is in the array V, 


    as returned by ZGEDMD. That is,  X(:,1:K)*V(:,i)


    is an eigenvector corresponding to EIGS(i). The columns 


    of V(1:K,1:K) are the computed eigenvectors of the 


    K-by-K Rayleigh quotient.  


    See the descriptions of EIGS, X and V.      

LDZ

    LDZ (input) INTEGER , LDZ >= M


    The leading dimension of the array Z.

RES

    RES (output) REAL(KIND=WP) (N-1)-by-1 array


    RES(1:K) contains the residuals for the K computed 


    Ritz pairs, 


    RES(i) = || A * Z(:,i) - EIGS(i)*Z(:,i))||_2.


    See the description of EIGS and Z.      

B

    B (output) COMPLEX(KIND=WP)  MIN(M,N)-by-(N-1) array.


    IF JOBF =='R', B(1:N,1:K) contains A*U(:,1:K), and can


    be used for computing the refined vectors; see further 


    details in the provided references. 


    If JOBF == 'E', B(1:N,1;K) contains 


    A*U(:,1:K)*W(1:K,1:K), which are the vectors from the


    Exact DMD, up to scaling by the inverse eigenvalues.   


    In both cases, the content of B can be lifted to the 


    original dimension of the input data by pre-multiplying


    with the Q factor from the initial QR factorization.   


    Here A denotes a compression of the underlying operator.      


    See the descriptions of F and X.


    If JOBF =='N', then B is not referenced.

LDB

    LDB (input) INTEGER, LDB >= MIN(M,N)


    The leading dimension of the array B.

V

    V (workspace/output) COMPLEX(KIND=WP) (N-1)-by-(N-1) array


    On exit, V(1:K,1:K) V contains the K eigenvectors of


    the Rayleigh quotient. The Ritz vectors


    (returned in Z) are the product of Q from the initial QR


    factorization (see the description of F) X (see the 


    description of X) and V.

LDV

    LDV (input) INTEGER, LDV >= N-1


    The leading dimension of the array V.

S

    S (output) COMPLEX(KIND=WP) (N-1)-by-(N-1) array


    The array S(1:K,1:K) is used for the matrix Rayleigh


    quotient. This content is overwritten during


    the eigenvalue decomposition by ZGEEV.


    See the description of K.

LDS

    LDS (input) INTEGER, LDS >= N-1        


    The leading dimension of the array S.

LZWORK

    ZWORK (workspace/output) COMPLEX(KIND=WP) LWORK-by-1 array


    On exit, 


    ZWORK(1:MIN(M,N)) contains the scalar factors of the 


    elementary reflectors as returned by ZGEQRF of the 


    M-by-N input matrix F.   


    If the call to ZGEDMDQ is only workspace query, then


    ZWORK(1) contains the minimal complex workspace length and


    ZWORK(2) is the optimal complex workspace length. 


    Hence, the length of work is at least 2.


    See the description of LZWORK.      

LZWORK

    LZWORK (input) INTEGER


    The minimal length of the  workspace vector ZWORK.


    LZWORK is calculated as follows:


    Let MLWQR  = N (minimal workspace for ZGEQRF[M,N])


        MLWDMD = minimal workspace for ZGEDMD (see the


                 description of LWORK in ZGEDMD)


        MLWMQR = N (minimal workspace for 


                   ZUNMQR['L','N',M,N,N])


        MLWGQR = N (minimal workspace for ZUNGQR[M,N,N])


        MINMN  = MIN(M,N)      


    Then


    LZWORK = MAX(2, MIN(M,N)+MLWQR, MINMN+MLWDMD)


    is further updated as follows:


       if   JOBZ == 'V' or JOBZ == 'F' THEN 


            LZWORK = MAX(LZWORK, MINMN+MLWMQR)


       if   JOBQ == 'Q' THEN


            LZWORK = MAX(ZLWORK, MINMN+MLWGQR)      

WORK

    WORK (workspace/output) REAL(KIND=WP) LWORK-by-1 array


    On exit,


    WORK(1:N-1) contains the singular values of 


    the input submatrix F(1:M,1:N-1).


    If the call to ZGEDMDQ is only workspace query, then


    WORK(1) contains the minimal workspace length and


    WORK(2) is the optimal workspace length. hence, the


    length of work is at least 2.


    See the description of LWORK.

LWORK

    LWORK (input) INTEGER


    The minimal length of the  workspace vector WORK.


    LWORK is the same as in ZGEDMD, because in ZGEDMDQ


    only ZGEDMD requires real workspace for snapshots


    of dimensions MIN(M,N)-by-(N-1). 


    If on entry LWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace length for WORK.          

IWORK

    IWORK (workspace/output) INTEGER LIWORK-by-1 array


    Workspace that is required only if WHTSVD equals


    2 , 3 or 4. (See the description of WHTSVD).


    If on entry LWORK =-1 or LIWORK=-1, then the


    minimal length of IWORK is computed and returned in


    IWORK(1). See the description of LIWORK.

LIWORK

    LIWORK (input) INTEGER


    The minimal length of the workspace vector IWORK.


    If WHTSVD == 1, then only IWORK(1) is used; LIWORK >=1


    Let M1=MIN(M,N), N1=N-1. Then


    If WHTSVD == 2, then LIWORK >= MAX(1,8*MIN(M1,N1))


    If WHTSVD == 3, then LIWORK >= MAX(1,M1+N1-1)


    If WHTSVD == 4, then LIWORK >= MAX(3,M1+3*N1)


    If on entry LIWORK = -1, then a workspace query is


    assumed and the procedure only computes the minimal


    and the optimal workspace lengths for both WORK and


    IWORK. See the descriptions of WORK and IWORK.

INFO

    INFO (output) INTEGER


    -i < 0 :: On entry, the i-th argument had an


              illegal value


       = 0 :: Successful return.


       = 1 :: Void input. Quick exit (M=0 or N=0).


       = 2 :: The SVD computation of X did not converge.


              Suggestion: Check the input data and/or


              repeat with different WHTSVD.


       = 3 :: The computation of the eigenvalues did not


              converge.


       = 4 :: If data scaling was requested on input and


              the procedure found inconsistency in the data


              such that for some column index i,


              X(:,i) = 0 but Y(:,i) /= 0, then Y(:,i) is set


              to zero if JOBS=='C'. The computation proceeds


              with original or modified data and warning


              flag is set with INFO=4.  

Zlatko Drmac