Tuning algorithmic parameters to optimize the performance of large, complicated computational codes is an important problem involving finding the optima and identifying regimes defined by non-smooth boundaries in black-box functions. Within the Bayesian optimization framework, the Gaussian process surrogate model produces smooth mean functions, but functions in the tuning problem are often non-smooth, which is exacerbated by the fact that we usually have limited sequential samples from the black-box function. Motivated by these issues encountered in tuning, we propose a novel Gaussian process model called a clustered Gaussian process (cGP), where the components are dynamically updated by clustering. In our studies, the performance of cGP can be better than stationary GPs in nearly 90% of the experiments and better than non-stationary GPs in nearly 70% of the repeated experiments while requiring less computational cost. cGP provides a novel approach for dynamic GP, computes more efficiently than recursive partitioning, and discovers non-smoothness regimes. We provide extensive experiments including high-performance computing (HPC) and industrial simulation functions to show the effectiveness of our methods.
AlonsoPCatalánSIgualFD, et al. (2015) Time and energy modeling of high-performance level-3 BLAS on x86 architectures. Simulation Modelling Practice and Theory55: 77–94.
3.
AnJOwenA (2001) Quasi-regression. Journal of Complexity17(4): 588–607.
4.
BarryDHartiganJA (1993) A bayesian analysis for change point problems. Journal of the American Statistical Association88(421): 309–319.
5.
BassevilleMNikiforovIV (1993) Detection of abrupt changes: theory and application. Prentice Hall Information and System Sciences Series. Englewood Cliffs, NJ: Prentice Hall.
6.
BennerPEzzattiPQuintana-OrtíES, et al. (2016) Tuning the blocksize for dense linear algebra factorization routines with the roofline model. In: CarreteroJ (ed) Algorithms and Architectures for Parallel Processing. ICA3PP 2016. Cham: Springer, 18–29.
7.
BergstraJBengioY (2012) Random search for hyper-parameter optimization. Journal of Machine Learning Research13: 281.
8.
BhatiaN (2010) Survey of nearest neighbor techniques. arXiv:1007.0085.
9.
BilmesJAsanovicKChinCW, et al. (1997) Optimizing matrix multiply using PHiPAC: a portable, high-performance, ANSI C coding methodology. ACM International Conference on Supercomputing 25th Anniversary Volume. New York, NY: Association for Computing Machinery, 253–260.
10.
BlackfordLSPetitetAPozoR, et al. (2002) An updated set of basic linear algebra Subprograms (BLAS). ACM Transactions on Mathematical Software28(2): 135–151.
11.
BookerAJDennis JrJFrankPD, et al. (1999) A rigorous framework for optimization of expensive functions by surrogates. Structural Optimization17(1): 1–13.
12.
BroderickTGramacyRB (2010) Treed Gaussian process models for classification. Classification as a Tool for Research. Berlin: Springer, 101–108.
13.
BullAD (2011) Convergence rates of efficient global optimization algorithms. Journal of Machine Learning Research12(10): 1–30.
14.
CalotoiuAHoeflerTPokeM, et al. (2013) Using automated performance modeling to find scalability bugs in complex codes. Proceedings of the International Conference on High Performance Computing, Networking, Storage and Analysis. New York, NY: Association for Computing Machinery, 1–12.
15.
ChipmanHAGeorgeEIMcCullochRE (1998) Bayesian CART model search. Journal of the American Statistical Association93(443): 935–948.
ChoYDemmelJWDerezińskiM, et al. (2023a) Surrogate-based autotuning for randomized sketching algorithms in regression problems. ArXiv Preprint arXiv:2308.15720.
18.
ChoYDemmelJWKingJ, et al. (2023b) Harnessing the crowd for autotuning high-performance computing applications. 2023 IEEE International Parallel and Distributed Processing Symposium (IPDPS). New York, NY: IEEE, 635–645.
19.
Clint WhaleyRPetitetADongarraJJ (2001) Automated empirical optimizations of software and the ATLAS Project. Parallel Computing27(1-2): 3–35.
20.
CramérHLeadbetterM (2013) Stationary and related stochastic processes: sample function properties and their applications. Dover Books on Mathematics. Mineola, NY: Dover Publications.
21.
DevroyeLGyörfiLLugosiG (2013) A Probabilistic Theory of Pattern Recognition. Berlin: Springer Science & Business Media, Vol. 31.
22.
Fabregat-TraverDIsmailAEBientinesiP (2018). Accelerating molecular dynamics codes by performance and accuracy modeling. Journal of Computational Science27(2018): 77-90.
23.
FalgoutRDJonesJEYangUM (2005) Pursuing scalability for hypre’s conceptual interfaces. ACM Transactions on Mathematical Software31(3): 326–350.
GramacyRB (2020) Surrogates: Gaussian Process Modeling, Design, and Optimization for the Applied Sciences. Boca Raton, FL: Chapman and Hall/CRC.
26.
GramacyRBApleyDW (2015) Local Gaussian process approximation for large computer experiments. Journal of Computational & Graphical Statistics24(2): 561–578.
27.
GramacyRBLeeHKH (2008) Bayesian treed Gaussian process models with an application to computer modeling. Journal of the American Statistical Association103(483): 1119–1130.
28.
GramacyRBLudkovskiM (2015) Sequential design for optimal stopping problems. SIAM Journal on Financial Mathematics6(1): 748–775.
29.
GramacyRBPolsonNG (2011) Particle learning of Gaussian process models for sequential design and optimization. Journal of Computational & Graphical Statistics20(1): 102–118.
30.
HeadTMechCoderGLShcherbatyiI, et al. (2018) scikit-optimize/scikit-optimize: v0. 5.2. Version v0 5.
31.
HerlandsWWilsonANickischH, et al. (2016) Scalable Gaussian processes for characterizing multidimensional change surfaces. In: GrettonARobertCC (eds) Proceedings of the 19th International Conference on Artificial Intelligence and Statistics, Proceedings of Machine Learning Research. Breckenridge, CO: PMLR, Vol. 51, 1013–1021.
32.
Hernández-LobatoJMHoffmanMWGhahramaniZ (2014) Predictive entropy search for efficient global optimization of black-box functions. Advances in Neural Information Processing Systems27: 1–9.
33.
HongJWKungHT (1981) I/O complexity: the red-blue pebble game. Proceedings of the Thirteenth Annual ACM Symposium on Theory of Computing - STOC ’81. Milwaukee, WI: ACM Press.
KeGMengQFinleyT, et al. (2017) Lightgbm: a highly efficient gradient boosting decision tree. Advances in Neural Information Processing Systems30: 1–9.
36.
KenettRSZacksSAmbertiD (2013) Modern Industrial Statistics: With Applications in R, MINITAB and JMP. Hoboken, NJ: John Wiley & Sons.
37.
KlusJGruntPDobrovolnýM (2021) Hyper-optimization with Gaussian process and differential evolution algorithm.
38.
KrauseAGuestrinC (2007) Nonmyopic active learning of Gaussian processes: an exploration-exploitation approach. Proceedings of the 24th International Conference on Machine Learning. New York, NY: Association for Computing Machinery, 449–456.
39.
LamparthMBestehornMMärkischB (2022) Gaussian processes and Bayesian optimization for high precision experiments. ArXiv Preprint arXiv:2205.07625.
40.
LiXSLinPLiuY, et al. (2023) Newly released capabilities in the distributed-memory SuperLU sparse direct solver. ACM Transactions on Mathematical Software49(1): 1–20. DOI: 10.1145/3577197.
41.
LindauerMEggenspergerKFeurerM, et al. (2022) Smac3: a versatile Bayesian optimization package for hyperparameter optimization. Journal of Machine Learning Research23(1): 2475–2483.
42.
LiuZZhouLLeungH, et al. (2015) Kinect posture reconstruction based on a local mixture of Gaussian process models. IEEE Transactions on Visualization and Computer Graphics22(11): 2437–2450.
43.
LiuYSid-LakhdarWMMarquesO, et al. (2021) Gptune: Multitask Learning for Autotuning Exascale Applications. New York, NY: Association for Computing Machinery, 234–246.
44.
LuoHStraitJ (2021) Combining geometric and topological information in image segmentation. 2021 IEEE International Conference on Big Data (Big Data)). New York, NY: IEEE, 3841–3852.
45.
LuoHMacEachernSNPeruggiaM (2020) Asymptotics of lower dimensional zero-density regions. Statistics57.6(2023): 1285-1316.
46.
LuoHNattinoGPratolaMT (2022) Sparse additive Gaussian process regression. Journal of Machine Learning Research23(1): 1–33.
47.
LuoHChoYDemmelJW, et al. (2024) Hybrid parameter search and dynamic model selection for mixed-variable Bayesian optimization. Journal of Computational & Graphical Statistics33: 855–868.
48.
MaddoxWJBalandatMWilsonAG, et al. (2021) Bayesian optimization with high-dimensional outputs. Advances in Neural Information Processing Systems34: 19274–19287.
49.
Martinez-CantinR (2015) Locally-biased Bayesian optimization using nonstationary Gaussian processes. Neural Information Processing Systems (NIPS) workshop on Bayesian Optimization7: 4.
Nguyen-TuongDSeegerMPetersJ (2009) Model learning with local Gaussian process regression. Advanced Robotics23(15): 2015–2034.
52.
NoackMMLuoHRisserMD (2024) A unifying perspective on non-stationary kernels for deeper Gaussian processes. APL Machine Learning2(1).
53.
OwenABDickJChenS (2014) Higher order Sobol’ indices. Information and Inference: A Journal of the IMA3(1): 59–81.
54.
PaciorekCJSchervishMJ (2004) Nonstationary covariance functions for Gaussian process regression. Advances in Neural Information Processing Systems 16. Cambridge, MA: MIT Press, 273–280.
55.
ParkSChoiS (2010) Hierarchical Gaussian process regression. Proceedings of 2nd Asian Conference on Machine Learning, Proceedings of Machine Learning Research. Norfolk, MA: JMLR Workshop and Conference Proceedings, Vol. 13, 95–110.
56.
ParkCHuangJZDingY (2011) Domain decomposition approach for fast Gaussian process regression of large spatial data sets. Journal of Machine Learning Research11: 1697–1728.
57.
PeiseEFabregat-TraverDBientinesiP (2015) On the performance prediction of BLAS-based tensor contractions. In: JarvisSWrightSHammondS (eds) High Performance Computing Systems. Performance Modeling, Benchmarking, and Simulation. PMBS 2014. Cham: Springer, 193–212.
58.
RaponiEWangHBujnyM, et al. (2020) High dimensional Bayesian optimization assisted by principal component analysis.
59.
RasmussenCEWilliamsCKI (2006) Gaussian Processes for Machine Learning. Cambridge, MA: MIT Press.
60.
RiosLMSahinidisNV (2013) Derivative-free optimization. Journal of Global Optimization56(3): 1247–1293.
61.
SaatçiYTurnerRRasmussenCE (2010) Gaussian process change point models. Proceedings of the 27th International Conference on International Conference on Machine Learning, ICML’10. New York, NY: Association for Computing Machinery, 927–934.
62.
SchweidtmannAMBongartzDGrotheD, et al. (2021) Deterministic global optimization with Gaussian processes embedded. Mathematical Programming Computation13(3): 553–581.
63.
ShahriariBSwerskyKWangZ, et al. (2016) Taking the human out of the loop: a review of Bayesian optimization. Proceedings of the IEEE104(1): 148–175.
64.
SlonimNAharoniECrammerK (2013) Hartigan’s K-means vs. Lloyd’s K means–is it time for a change?Proceedings of the 23rd International Joint Conference on Artificial Intelligence (IJCAI).
65.
SmithAFM (1975) A Bayesian approach to inference about a change-point in a sequence of random variables. Biometrika62(2): 407–416.
66.
SnoekJLarochelleHAdamsRP (2012) Practical Bayesian optimization of machine learning algorithms. Advances in Neural Information Processing Systems. New York, NY: Association for Computing Machinery, Vol. 25.
67.
SnoekJSwerskyKZemelR, et al. (2014) Input warping for Bayesian optimization of non-stationary functionsInternational Conference on Machine Learning. Breckenridge, CO: PMLR, 1674–1682.
68.
SolakEMurray-smithRLeitheadW, et al. (2003) Derivative observations in Gaussian process models of dynamic systems. In: BeckerSThrunSObermayerK (eds) Advances in Neural Information Processing Systems. Cambridge, MA: MIT Press, Vol. 15.
69.
StoyanovM (2018) Adaptive sparse grid construction in a context of local anisotropy and multiple hierarchical parents. Sparse Grids and Applications-Miami 2016. Berlin: Springer, 175–199.
70.
StoyanovMSelesonPWebsterC (2017) A Surrogate Modeling Approach for Crack Pattern Prediction in Peridynamics. Reston, VA: American Institute of Aeronautics and Astronautics, Chapter 0, 1–11.
71.
SunDTohKCYuanY (2021) Convex clustering: model, theoretical guarantee and efficient algorithm. Journal of Machine Learning Research22: 1–30.
72.
SungCLHaalandBHwangY, et al. (2019) A clustered Gaussian process model for computer experiments. Statistica Sinica.
73.
TehYW (2010) Dirichlet process.
74.
Van ZeeFGSmithTMMarkerB, et al. (2016) The BLIS framework: experiments in portability. ACM Transactions on Mathematical Software42(2): 1–19.
75.
WynneGBriolFXGirolamiM (2021) Convergence guarantees for Gaussian process means with misspecified likelihoods and smoothness. Journal of Machine Learning Research22(123): 1–40.
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