TY - JOUR
T1 - Reconstructing soot fields in acoustically forced laminar sooting flames using physics-informed machine learning models
AU - Liu, Shiyu
AU - Wang, Haiou
AU - Sun, Zhiwei
AU - Foo, Kae Ken
AU - Nathan, Graham J.
AU - Dong, Xue
AU - Evans, Michael J.
AU - Dally, Bassam B.
AU - Luo, Kun
AU - Fan, Jianren
N1 - Publisher Copyright:
© 2024 The Combustion Institute
PY - 2024/1
Y1 - 2024/1
N2 - This work reports an application of physics-informed machine learning models on reconstructing key parameters of acoustically forced, time-varying laminar sooting flames, highlighting the potential of the machine learning methods as a complementary tool to conventional laser diagnostics. First, a physics-informed neural networks (PINNs) model was developed to reconstruct the fields of velocity and temperature in the region where is inaccessible with laser-based diagnosing methods due to soot scattering. The PINNs model was trained using experimental data from planar laser diagnostics and constrained with the momentum and energy conservations. The model shows effective capability of fulfilling the velocity and temperature fields. Second, an Autoencoder (AE)-based Deep Operator Network (DeepONet), also as a physics-informed model, was developed to predict the planar distribution of soot volume fraction in the flames. The AE-DeepONet framework was trained using planar images of temperature and hydroxyl radical (OH) with a hybrid way by combining physics-informed and data-driven approaches. The AE-DeepONet model outperforms the conventional data-driven-only machine learning models. The results show that, constrained by physical laws, machine learning based models can properly predict soot distribution, velocity and temperature in unsteady laminar flames, shedding light on the physics-informed machine learning methods as a complement to laser diagnostics.
AB - This work reports an application of physics-informed machine learning models on reconstructing key parameters of acoustically forced, time-varying laminar sooting flames, highlighting the potential of the machine learning methods as a complementary tool to conventional laser diagnostics. First, a physics-informed neural networks (PINNs) model was developed to reconstruct the fields of velocity and temperature in the region where is inaccessible with laser-based diagnosing methods due to soot scattering. The PINNs model was trained using experimental data from planar laser diagnostics and constrained with the momentum and energy conservations. The model shows effective capability of fulfilling the velocity and temperature fields. Second, an Autoencoder (AE)-based Deep Operator Network (DeepONet), also as a physics-informed model, was developed to predict the planar distribution of soot volume fraction in the flames. The AE-DeepONet framework was trained using planar images of temperature and hydroxyl radical (OH) with a hybrid way by combining physics-informed and data-driven approaches. The AE-DeepONet model outperforms the conventional data-driven-only machine learning models. The results show that, constrained by physical laws, machine learning based models can properly predict soot distribution, velocity and temperature in unsteady laminar flames, shedding light on the physics-informed machine learning methods as a complement to laser diagnostics.
KW - Field reconstruction
KW - Limited experimental data
KW - Physics-informed machine learning
KW - Soot prediction
UR - http://www.scopus.com/inward/record.url?scp=85196648860&partnerID=8YFLogxK
U2 - 10.1016/j.proci.2024.105314
DO - 10.1016/j.proci.2024.105314
M3 - Article
AN - SCOPUS:85196648860
SN - 1540-7489
VL - 40
JO - Proceedings of the Combustion Institute
JF - Proceedings of the Combustion Institute
IS - 1-4
M1 - 105314
ER -