Increasing fast estimation of assessment of navigation parameters for the UAV based on a linear Kalman filter

Navigation of the short-range unmanned aerial vehicles (UAV) requires the evaluation of parameters such as the velocity vector and position in real-time using an onboard computer. The use of the complex algorithms capable of working with nonlinear systems reduces the efficiency of calculations; ther...

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Bibliographic Details
Main Authors: Isaev, M. A., Linets, G. I., Nikulin, V. I., Melnikov, S. V., Isaev, A. M.
Format: Conference Proceeding
Language:English
Subjects:
Accuracy
Airborne/spaceborne computers
Algorithms
Arithmetic
Complexity
Control systems
Controllability
Data processing
Differential equations
Earth models
Iterative methods
Kalman filters
Multiplication
Navigation
Nonlinear systems
Optimization
Parameter estimation
Stability
Unmanned aerial vehicles
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Summary:Navigation of the short-range unmanned aerial vehicles (UAV) requires the evaluation of parameters such as the velocity vector and position in real-time using an onboard computer. The use of the complex algorithms capable of working with nonlinear systems reduces the efficiency of calculations; therefore, the urgent task is to reduce the computational complexity of the existing algorithms while maintaining the required accuracy, which allows you to release CPU resources for solving other tasks that are needed for the UAV control system. The use of a flat Earth model for solving a navigation problem allows using the linear differential equations to describe movements in UAV space and using the linear Kalman filter as a basis for an algorithm for estimating navigation parameters. The rejection of iterative recalculation of the Kalman filter gain factors significantly reduces the number of arithmetic operations but at the same time retains the required accuracy of the estimation of navigation parameters, and the optimization of the multiplication of sparse zeros of the matrices further reduces the computational complexity. In this regard, the use of an algorithm for solving a navigation problem, which has a minimum number of arithmetic operations, increases the efficiency of processing data from the control system as a whole and allows for better controllability of the UAVs.
ISSN:0094-243X
1551-7616
DOI:10.1063/5.0035917