Compact quasi-Newton representation

The compact representation for quasi-Newton methods is a matrix decomposition, which is typically used in gradient based optimization algorithms or for solving nonlinear systems. The decomposition uses a low-rank representation for the direct and/or inverse Hessian or the Jacobian of a nonlinear system. Because of this, the compact representation is often used for large problems and constrained optimization.

The compact matrix decomposition of a dense Hessian approximation
The compact representation (right) of a dense Hessian approximation (left) is an initial matrix (typically diagonal) plus low rank decomposition. It has a small memory footprint (shaded areas) and enables efficient matrix computations

Definition

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The compact representation of a quasi-Newton matrix for the inverse Hessian   or direct Hessian   of a nonlinear objective function   expresses a sequence of recursive rank-1 or rank-2 matrix updates as one rank-  or rank-  update of an initial matrix.[1][2] Because it is derived from quasi-Newton updates, it uses differences of iterates and gradients   in its definition  . In particular, for   or   the rectangular   matrices   and the   square symmetric systems   depend on the  's and define the quasi-Newton representations

 

Applications

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Because of the special matrix decomposition the compact representation is implemented in state-of-the-art optimization software.[3][4][5][6] When combined with limited-memory techniques it is a popular technique for constrained optimization with gradients.[7] Linear algebra operations can be done efficiently, like matrix-vector products, solves or eigendecompositions. It can be combined with line-search and trust region techniques, and the representation has been developed for many quasi-Newton updates. For instance, the matrix vector product with the direct quasi-Newton Hessian and an arbitrary vector   is:

 

Background

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In the context of the GMRES method, Walker[8] showed that a product of Householder transformations (an identity plus rank-1) can be expressed as a compact matrix formula. This led to the derivation of an explicit matrix expression for the product of   identity plus rank-1 matrices.[7] Specifically, for         and   when   the product of   rank-1 updates to the identity is   The BFGS update can be expressed in terms of products of the  's, which have a compact matrix formula. Therefore, the BFGS recursion can exploit these block matrix representations

  (1)

Recursive quasi-Newton updates

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A parametric family of quasi-Newton updates includes many of the most known formulas.[9] For arbitrary vectors   and   such that   and   general recursive update formulas for the inverse and direct Hessian estimates are

  (2)
  (3)

By making specific choices for the parameter vectors   and   well known methods are recovered

Table 1: Quasi-Newton updates parametrized by vectors   and  
       
  BFGS   PSB (Powell Symmetric Broyden)
      DFP
  SR1   SR1
 [10] MSS (Multipoint-Symmetric-Secant)


Compact Representations

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Collecting the updating vectors of the recursive formulas into matrices, define

       

upper triangular

 

lower triangular

 

and diagonal

 

With these definitions the compact representations of general rank-2 updates in (2) and (3) (including the well known quasi-Newton updates in Table 1) have been developed in Brust:[11]

 

(4)

 

 

and the formula for the direct Hessian is

 

(5)

 

 

For instance, when   the representation in (4) is the compact formula for the BFGS recursion in (1).

Specific Representations

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Prior to the development of the compact representations of (2) and (3), equivalent representations have been discovered for most known updates (see Table 1).

Along with the SR1 representation, the BFGS (Broyden-Fletcher-Goldfarb-Shanno) compact representation was the first compact formula known.[7] In particular, the inverse representation is given by

  The direct Hessian approximation can be found by applying the Sherman-Morrison-Woodbury identity to the inverse Hessian:

 

The SR1 (Symmetric Rank-1) compact representation was first proposed in.[7] Using the definitions of   and   from above, the inverse Hessian formula is given by

 

The direct Hessian is obtained by the Sherman-Morrison-Woodbury identity and has the form

 

The multipoint symmetric secant (MSS) method is a method that aims to satisfy multiple secant equations. The recursive update formula was originally developed by Burdakov.[12] The compact representation for the direct Hessian was derived in [13]

 

Another equivalent compact representation for the MSS matrix is derived by rewriting   in terms of  .[14] The inverse representation can be obtained by application for the Sherman-Morrison-Woodbury identity.

Since the DFP (Davidon Fletcher Powell) update is the dual of the BFGS formula (i.e., swapping  ,   and   in the BFGS update), the compact representation for DFP can be immediately obtained from the one for BFGS.[15]

The PSB (Powell-Symmetric-Broyden) compact representation was developed for the direct Hessian approximation.[16] It is equivalent to substituting   in (5)

 

Structured BFGS

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For structured optimization problems in which the objective function can be decomposed into two parts  , where the gradients and Hessian of   are known but only the gradient of   is known, structured BFGS formulas exist. The compact representation of these methods has the general form of (5), with specific   and  .[17]

Reduced BFGS

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The reduced compact representation (RCR) of BFGS is for linear equality constrained optimization  , where   is underdetermined. In addition to the matrices   the RCR also stores the projections of the  's onto the nullspace of  

 

For   the compact representation of the BFGS matrix (with a multiple of the identity  ) the (1,1) block of the inverse KKT matrix has the compact representation[18]

 

 

Limited Memory

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Pattern in a limited-memory updating strategy. With a memory parameter of  , the first   iterations fill the matrix (e.g., an upper triangular for the compact representation,  ). For   the limited-memory techniques discards the oldest information and add a new column to the end.


The most common use of the compact representations is for the limited-memory setting where   denotes the memory parameter, with typical values around   (see e.g., [18][7]). Then, instead of storing the history of all vectors one limits this to the   most recent vectors   and possibly   or  . Further, typically the initialization is chosen as an adaptive multiple of the identity  , with   and  . Limited-memory methods are frequently used for large-scale problems with many variables (i.e.,   can be large), in which the limited-memory matrices   and   (and possibly  ) are tall and very skinny:   and  .

Implementations

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Open source implementations include:

  • ACM TOMS algorithm 1030 implements a L-SR1 solver[19] [20]
  • R's optim general-purpose optimizer routine uses the L-BFGS-B method.
  • SciPy's optimization module's minimize method also includes an option to use L-BFGS-B.
  • IPOPT with first order information

Non open source implementations include:

Works cited

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  1. ^ Nocedal, J.; Wright, S.J. (2006). Numerical Optimization. Springer Series in Operations Research and Financial Engineering. Springer New York, NY. doi:10.1007/978-0-387-40065-5. ISBN 978-0-387-30303-1.
  2. ^ Brust, J. J. (2018). Large-Scale Quasi-Newton Trust-Region Methods: High-Accuracy Solvers, Dense Initializations, and Extensions (PhD thesis). University of California, Merced.
  3. ^ a b Byrd, R. H.; Nocedal, J; Waltz, R. A. (2006). "KNITRO: An integrated package for nonlinear optimization". Large-Scale Nonlinear Optimization. Nonconvex Optimization and Its Applications. Vol. 83. In: Di Pillo, G., Roma, M. (eds) Large-Scale Nonlinear Optimization. Nonconvex Optimization and Its Applications, vol 83.: Springer, Boston, MA. p. 35-59. doi:10.1007/0-387-30065-1_4. ISBN 978-0-387-30063-4.{{cite book}}: CS1 maint: location (link)
  4. ^ Zhu, C.; Byrd, R. H.; Lu, P.; Nocedal, J. (1997). "Algorithm 778: L-BFGS-B: Fortran subroutines for large-scale bound-constrained optimization". ACM Transactions on Mathematical Software (TOMS). 23 (4): 550-560. doi:10.1145/279232.279236.
  5. ^ Brust, J.; Burdakov, O.; Erway, J.; Marcia, R. (2022). "Algorithm 1030: SC-SR1: MATLAB software for limited-memory SR1 trust-region methods". ACM Transactions on Mathematical Software (TOMS). 48 (4): 1-33. doi:10.1145/3550269.
  6. ^ Wächter, A.; Biegler, L. T. (2006). "On the implementation of an interior-point filter line-search algorithm for large-scale nonlinear programming". Mathematical Programming. 106: 25-57. doi:10.1007/s10107-004-0559-y.
  7. ^ a b c d e Byrd, R. H.; Nocedal, J.; Schnabel, R. B. (1994). "Representations of Quasi-Newton Matrices and their use in Limited Memory Methods". Mathematical Programming. 63 (4): 129–156. doi:10.1007/BF01582063. S2CID 5581219.
  8. ^ Walker, H. F. (1988). "Implementation of the GMRES Method Using Householder Transformations". SIAM Journal on Scientific and Statistical Computing. 9 (1): 152–163. doi:10.1137/0909010.
  9. ^ Dennis, Jr, J. E.; Moré, J. J. (1977). "Quasi-Newton methods, motivation and theory". SIAM Review. 19 (1): 46-89. doi:10.1137/1019005. hdl:1813/6056.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  10. ^  
  11. ^ Brust, J. J. (2024). "Useful Compact Representations for Data-Fitting". arXiv:2403.12206 [math.OC].
  12. ^ Burdakov, O. P. (1983). "Methods of the secant type for systems of equations with symmetric Jacobian matrix". Numerical Functional Analysis and Optimization. 6 (2): 1–18. doi:10.1080/01630568308816160.
  13. ^ Burdakov, O. P.; Martínez, J. M.; Pilotta, E. A. (2002). "A limited-memory multipoint symmetric secant method for bound constrained optimization". Annals of Operations Research. 117: 51–70. doi:10.1023/A:1021561204463.
  14. ^ Brust, J. J.; Erway, J. B.; Marcia, R. F. (2024). "Shape-changing trust-region methods using multipoint symmetric secant matrices". Optimization Methods and Software: 1–18. arXiv:2209.12057. doi:10.1080/10556788.2023.2296441.
  15. ^ Erway, J. B.; Jain, V.; Marcia, R. F. (2013). Shifted limited-memory DFP systems. In 2013 Asilomar Conference on Signals, Systems and Computers. IEEE. pp. 1033–1037.
  16. ^ Kanzow, C.; Steck, D. (2023). "Regularization of limited memory quasi-Newton methods for large-scale nonconvex minimization". Mathematical Programming Computation. 15 (3): 417–444. doi:10.1007/s12532-023-00238-4.
  17. ^ Brust, J. J; Di, Z.; Leyffer, S.; Petra, C. G. (2021). "Compact representations of structured BFGS matrices". Computational Optimization and Applications. 80 (1): 55–88. doi:10.1007/s10589-021-00297-0.
  18. ^ a b Brust, J. J; Marcia, R.F.; Petra, C.G.; Saunders, M. A. (2022). "Large-scale optimization with linear equality constraints using reduced compact representation". SIAM Journal on Scientific Computing. 44 (1): A103–A127. arXiv:2101.11048. Bibcode:2022SJSC...44A.103B. doi:10.1137/21M1393819.
  19. ^ "Collected Algorithms of the ACM (CALGO)". calgo.acm.org.
  20. ^ "TOMS Alg. 1030". calgo.acm.org/1030.zip.
  21. ^ Zhu, C.; Byrd, Richard H.; Lu, Peihuang; Nocedal, Jorge (1997). "L-BFGS-B: Algorithm 778: L-BFGS-B, FORTRAN routines for large scale bound constrained optimization". ACM Transactions on Mathematical Software. 23 (4): 550–560. doi:10.1145/279232.279236. S2CID 207228122.