Modeling Virtual Sensor for Engine Nitrogen Oxides Using Variants of
Artificial Neural Networks 2023-01-5042
Virtual sensing or estimation of emission species such as NOx at the engine
exhaust using the appropriate engine measurables and leveraging it for
control/diagnosis is a challenging task given the highly nonlinear and dynamic
nature of the combustion process. This article presents development of virtual
engine-out NOx (EONOx) sensor using two different supervised dynamic artificial
neural network (ANN) topologies, namely, trained recurrent neural network (RNN)
and wavelet neural network (WNN). The proposed RNN architecture is a single
hidden layer neural network with permutations of feedback connections between
the inter- and intra-layer nodes. The RNN resembles a nonlinear state-space
model mapping select engine measurables and the engine-out NOx and is trained
using a variant of real-time recurrent learning (RTRL) algorithm. The WNN
architecture is a single hidden layer neural network comprising hidden layer
nodes with wavelets as activation functions. The activation functions of the WNN
nodes are adapted for their form and time shift along with their synaptic
weights in the supervised learning method. The topologies are validated in
virtual environment using modeled data as well as experimental data. Approaches
toward leveraging these virtual sensors for better NOx control, both at the
engine-out and system-out level are discussed along with their benefits. The
limitations of such data-based virtual sensors are stated. The outcome of this
work is methodology to select appropriate ANN topology and training it for
efficient EONOx virtual sensor and leveraging it for control at engine and
tailpipe level.