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Aircraft neural modeling and parameter estimation using neural partial differentiation

Majeed Mohamed (Flight Mechanics and Control Division, Council of Scientific and Industrial Research-National Aerospace Laboratories, Bangalore, India and Air Traffic Management Research Institute, Nanyang Technological University, Singapore)
Vikalp Dongare (Department of Aeronautical Engineering, M.V. Jayaraman College of Engineering, Bangalore, India and GENPACT, Bangalore, India)

Aircraft Engineering and Aerospace Technology

ISSN: 0002-2667

Article publication date: 13 August 2018

Issue publication date: 12 September 2018

232

Abstract

Purpose

The purpose of this paper is to build a neural model of an aircraft from flight data and online estimation of the aerodynamic derivatives from established neural model.

Design/methodology/approach

A neural model capable of predicting generalized force and moment coefficients of an aircraft using measured motion and control variable is used to extract aerodynamic derivatives. The use of neural partial differentiation (NPD) method to the multi-input-multi-output (MIMO) aircraft system for the online estimation of aerodynamic parameters from flight data is extended.

Findings

The estimation of aerodynamic derivatives of rigid and flexible aircrafts is treated separately. In the case of rigid aircraft, longitudinal and lateral-directional derivatives are estimated from flight data. Whereas simulated data are used for a flexible aircraft in the absence of its flight data. The unknown frequencies of structural modes of flexible aircraft are also identified as part of estimation problem in addition to the stability and control derivatives. The estimated results are compared with the parameter estimates obtained from output error method. The validity of estimates has been checked by the model validation method, wherein the estimated model response is matched with the flight data that are not used for estimating the derivatives.

Research limitations/implications

Compared to the Delta and Zero methods of neural networks for parameter estimation, the NPD method has an additional advantage of providing the direct theoretical insight into the statistical information (standard deviation and relative standard deviation) of estimates from noisy data. The NPD method does not require the initial value of estimates, but it requires a priori information about the model structure of aircraft dynamics to extract the flight stability and control parameters. In the case of aircraft with a high degree of flexibility, aircraft dynamics may contain many parameters that are required to be estimated. Thus, NPD seems to be a more appropriate method for the flexible aircraft parameter estimation, as it has potential to estimate most of the parameters without having the issue of convergence.

Originality/value

This paper highlights the application of NPD for MIMO aircraft system; previously it was used only for multi-input and single-output system for extraction of parameters. The neural modeling and application of NPD approach to the MIMO aircraft system facilitate to the design of neural network-based adaptive flight control system. Some interesting results of parameter estimation of flexible aircraft are also presented from established neural model using simulated data as a novelty. This gives more value addition to analyzing the flight data of flexible aircraft as it is a challenging problem in parameter estimation of flexible aircraft.

Keywords

Citation

Mohamed, M. and Dongare, V. (2018), "Aircraft neural modeling and parameter estimation using neural partial differentiation", Aircraft Engineering and Aerospace Technology, Vol. 90 No. 5, pp. 764-778. https://doi.org/10.1108/AEAT-02-2016-0021

Publisher

:

Emerald Publishing Limited

Copyright © 2018, Emerald Publishing Limited

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