Abstract :
Two new guidance laws for short range homing missiles are developed by invoking the sliding mode control (SMC) theory. Guidance law 1 as structured around the basic proportional navigation (PN), with an additive switching term, which is a function of the line of sight (LOS) rate alone. An adaptive procedure is suggested to select the gain of the switching term, in order to reduce chattering. This guidance law is nearly as simple to implement as the PN itself and does not require any explicit target maneuver estimation. Guidance law 2, based on a first order sliding surface, is designed such that it results in a continuous acceleration law, thereby reducing the chattering problem. While explicitly taking into account the effect of aerodynamic drag, it requires the second derivatives of LOS angle and range, which are not directly measured. An estimation scheme, again based on sliding mode theory, is presented to estimate these quantities. Simulation results clearly demonstrate the superior performance of these schemes
Keywords :
adaptive control; digital simulation; missiles; navigation; state estimation; variable structure systems; Guidance law 1; Guidance law 2; LOS angle; adaptive procedure; additive switching term; aerodynamic drag; chattering; continuous acceleration law; first order sliding surface; gain; line of sight rate; planar engagement model; proportional navigation; robust homing missile guidance laws; second derivatives; short range homing missiles; simulation; sliding mode control theory; switching term; Acceleration; Aerodynamics; Degradation; Game theory; Missiles; Navigation; Performance analysis; Performance loss; Robust control; Sliding mode control;
