Iso-surface sampler: Bayesian optimization-based sampling framework for controlling multi-fuel compression ignition engines

Abstract

Over the years, engines have been continuously improved to operate across a wide range of operating conditions and meet various requirements. This has led to an increase in actuators and their corresponding control inputs. Traditionally, to control the engine, maps are developed by human calibration. However, as the number of operating conditions and control inputs increases, this can be challenging. To overcome this, data-driven model-based frameworks have been proposed, assuming the existence of a dataset for model development. The accuracy of the developed controller depends on the accuracy of the model, and that in turn depends on the dataset used. However, developing extensive datasets sweeping across the entire range of operating conditions and control inputs can be challenging. In this paper, a sampling framework called the Iso-surface Sampler (ISS) is proposed for developing datasets with outputs within a desirable range, making them suitable for controller development. The proposed sampling framework uses knowledge of the underlying system and Bayesian optimization to build datasets. An experimental study with a computational fluid dynamics (CFD) based engine model was used to demonstrate the effectiveness of the proposed ISS framework. A dataset spanning varying fuel properties and engine speed was generated. Using the generated dataset, feedforward (FF) control maps for combustion phasing were developed and validated using the CFD engine model. The sampled dataset had 73.4% of points within the desired output range. During the validation of FF control maps, an RMSE of 1.78 crank angle degrees (CAD) was obtained, with 63.91% of the locations in FF maps having an error of less than 1 CAD.

Keywords

Bayesian optimization sampling methods data-driven control multi-fuel compression ignition engine combustion phasing control

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References

Fang

Ouyang

Tunestal

, et al. Closed-loop combustion phase control for multiple combustion modes by multiple injections in a compression ignition engine fueled by gasoline-diesel mixture. Appl Energy 2018; 231: 816–825.

Zhu

Prucka

Wang

, et al. Model-based optimal combustion phasing control strategy for spark ignition engines. SAE Int J Engines 2016; 09(2): 1170–1179.

Cassidy

JF.

A computerized on-line approach to calculating optimum engine calibrations. SAE Trans 1977; 86: 293–308.

Reitz

Rutland

Development and testing of diesel engine CFD models. Prog Energy Combust Sci 1995; 21(2): 173–196.

Frazier

. A tutorial on Bayesian optimization. arXiv, arXiv:1807.02811, 2018.

Rasmussen

Williams

CKI

. Gaussian processes for machine learning. Adaptive computation and machine learning. MIT Press, 2006.

Pal

Wang

Zhu

, et al. Multi-objective surrogate-assisted stochastic optimization for engine calibration. J Dyn Syst Meas Control 2021; 143(10): 101004-1–101004-12.

Zhu

Wang

Pal

, et al. Engine calibration using global optimization methods with customization. SAE Paper 2020-01-0270, 2020.

Vlaswinkel

Antunes

Willems

. Automated and risk-aware engine control calibration using constrained Bayesian optimization. arXiv, arXiv:2503.20493, 2025.

10.

Miller

Mak

Sun

, et al. Expected diverse utility (EDU): diverse Bayesian optimization of expensive computer simulators. arXiv, arXiv:2410.01196, 2024.

11.

Zhou

Song

, et al. Machine learning for combustion. Energy and AI 2022; 7(100128): 100128.

12.

Jiang

Yan

Zhang

Data-driven control of automotive diesel engines and after-treatment systems: state of the art and future challenges. Proc Inst Mech Eng Pt D: J Automobile Eng 2023; 237(9): 2083–2098.

13.

Alonso

Alvarruiz

Desantes

, et al. Combining neural networks and genetic algorithms to predict and reduce diesel engine emissions. IEEE Trans Evol Comput 2007; 11(1): 46–55.

14.

Dong

Goertemiller

Pal

, et al. Data driven feedforward control strategy for multi-fuel UAS engine. IFAC Pap Online 2022; 55(37): 627–632.

15.

Pal

Cornelius

Sun

, et al. Data-driven real-time fuel cetane estimation and control design for multifuel UAVs. Appl Energy 2024; 367(123336): 123336.

16.

Garg

Silvas

Willems

Potential of machine learning methods for robust performance and efficient engine control development. IFAC Pap Online 2021; 54(10): 189–195.

17.

Narayanan

Cornelius

Govind Raju

, et al. Simulation-based engine control for an ignition-assisted diesel engine with varying cetane number fuels. In: AIAA SCITECH 2024 forum American Institute of Aeronautics and Astronautics SCITECH 2024, Orlando, FL, USA, 2024, p. 0798.

18.

Narayanan

Govind Raju

Kweon

CBM

, et al. Computational fluid dynamics-based feed-forward control of multi-fuel energy-assisted compression ignition engines for sustainable aviation. Int J Engine Res 2025; 0(0): 14680874251388224.

19.

Prucka

Filipi

, et al. Cam-phasing optimization using artificial neural networks as surrogate models—fuel consumption and NOx emissions. SAE Trans 2006; 115: 742–758.

20.

Iooss

Lemaître

. A review on global sensitivity analysis methods. In: Dellino

Meloni

(eds) Uncertainty management in simulation-optimization of complex systems. Operations research/computer science interfaces series, volume 59. Boston, MA: Springer, 2015.

21.

Liu

Ong

Cai

A survey of adaptive sampling for global metamodeling in support of simulation-based complex engineering design. Struct Multidiscipl Optim 2018; 57(1): 393–416.

22.

Richards

Senecal

Pomraning

Converge (v3. 0). Convergent Science, 2020.

23.

Raju

SAG

Sun

Kim

, et al. Scalable data driven models for control of multi-fuel compression ignition engine. In: 2024 American control conference (ACC), Toronto, CA, USA, 2024, pp. 4248–4253.

24.

Jones

Schonlau

Welch

WJ.

Efficient global optimization of expensive black-box functions. J Glob Optim 1998; 13(4): 455–492.

25.

Ranjan

Bingham

Michailidis

Sequential experiment design for contour estimation from complex computer codes. Technometrics 2008; 50(4): 527–541.

26.

Ravishankar

Llorente

Djurić

. Improvement-based acquisition functions for level set estimation. In: Proceedings of the 33rd European signal processing conference (EUSIPCO), Palermo, Italy, 2025, pp. 1852–1856.

27.

Ruan

, et al. Investigation on parallel algorithms in efficient global optimization based on multiple points infill criterion and domain decomposition. Struct Multidiscipl Optim 2016; 54(4): 747–773.

28.

Govind Raju

Cornelius

Sun

, et al. Rate-limited and energy-efficient feedforward control for multi-fuel unmanned aircraft systems engine. ASME LDSC 2023; 3(2): 021003.

29.

Liu

Ong

Shen

, et al. When gaussian process meets big data: a review of scalable GPS. IEEE Trans Neural Netw Learn Syst 2020; 31: 4405–4423.

30.

Titsias

. Variational learning of inducing variables in sparse gaussian processes. In: van Dyk

Welling

(eds.) Proceedings of the 12th international conference on artificial intelligence and statistics, 2009, vol. 5, pp. 567–574. Florida: PMLR.

31.

Heywood

JB.

Internal combustion engine fundamentals. 2nd ed. McGraw-Hill Education, 2018.

32.

Ren

Kok-John

Wang

, et al. A multi-component wide distillation fuel (covering gasoline, jet fuel and diesel fuel) mechanism for combustion and PAH prediction. Fuel 2017; 208: 447–468.

33.

Narayanan

Sapra

, et al. A misfire-integrated gaussian process (MINT-GP) emulator for energy-assisted compression ignition (EACI) engines with varying cetane number jet fuels. Int J Engine Res 2024; 25: 1349–1380.

34.

Sapra

Hessel

Amezcua

, et al. Numerical modeling and analysis of energy-assisted compression ignition of varying cetane number jet fuels for high-altitude operation. J Eng Gas Turbine Power 2023; 145: 1–27.