Litcius/Paper detail

Modeling and implementation of nonlinear boost converter using local feedback deep recurrent neural network for voltage balancing in energy harvesting applications

Mostafa Noohi, Ali Mirvakili, Sayed Alireza Sadrossadat

2021International Journal of Circuit Theory and Applications24 citationsDOI

Abstract

Abstract Balancing the voltage of series connected supercapacitors is a necessity. Various passive and active balancing techniques are reported for alleviating the problems of leakage and overvoltage. In this paper, a novel active balancing approach based on boost converter is presented leading to the implementation of a piezoelectric energy harvesting (EH) system. Besides, this nonlinear boost converter is designed, implemented, and modeled using a new macromodeling approach. In this regard, data measured by the implemented boost converter passed through local feedback deep recurrent neural networks (LFDRNNs), in order to model the nonlinear behavior of this converter, and this model can be used to design the EH system. LFDRNN can be trained directly using the input–output waveform samples of the main circuit without knowing its internal details, and the obtained model has similar accuracy compared to the original circuit. The main focus of this paper is the new LFDRNN macromodeling method which is associated with the boost converter‐based active balancing technique. Our experimental results show that LFDRNN extends the ability of conventional neural network‐based models to express the dynamic behavior of nonlinear circuits while increasing the accuracy. Additionally, LFDRNN‐based models are much faster than existing models in simulation tools.

Topics & Concepts

Nonlinear systemWaveformElectronic engineeringBoost converterArtificial neural networkComputer scienceVoltageControl theory (sociology)Electronic circuitCapacitorEngineeringControl engineeringElectrical engineeringArtificial intelligenceQuantum mechanicsPhysicsControl (management)Innovative Energy Harvesting TechnologiesAdvanced Sensor and Energy Harvesting MaterialsAdvanced Memory and Neural Computing