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Deep reinforcement learning for dynamic control of fuel injection timing in multi-pulse compression ignition engines

Marc Henry de Frahan, Nicholas T. Wimer, Shashank Yellapantula, Ray Grout

2021International Journal of Engine Research19 citationsDOIOpen Access PDF

Abstract

Conventional compression-ignition (CI) engines have long offered high thermal efficiencies and torque across a wide range of loads, but often require extensive exhaust gas treatment that decreases efficiency to meet ever-increasing emissions regulations. One strategy to decrease emissions is to split the fuel injection into a series of smaller injections. In this paper, we explore a new way of discovering optimal control strategies for the next generation of CI engines using deep reinforcement learning (DRL). We outline a DRL procedure to maximize the weighted reward of engine work while minimizing end-of-cycle NO x emissions. Through the procedure outlined in this paper, we show that the DRL agent is able to reduce NO x emissions threefold while only decreasing network by 2%. We demonstrate the use of transfer learning (TL) across hierarchies of physical models to accelerate the learning process, making this approach feasible for a range of control problems within this space. This paper presents a framework and demonstration for using DRL to design control systems in technology areas such as multi-pulse engine control where a hierarchy of models combined with multi-objective rewards are used for optimal operation.

Topics & Concepts

Reinforcement learningTorqueRange (aeronautics)Automotive engineeringIgnition systemProcess (computing)Computer scienceEngineeringArtificial intelligenceAerospace engineeringPhysicsThermodynamicsOperating systemAdvanced Combustion Engine TechnologiesElectric and Hybrid Vehicle TechnologiesReal-time simulation and control systems
Deep reinforcement learning for dynamic control of fuel injection timing in multi-pulse compression ignition engines | Litcius