Abstract
Due to the large launch overload and high spin rate of spin-stabilized projectile, no attitude sensor is adopted in square crossing fixed-cant canard concept, which causes the lack of existing projectile linear theory for the close form solution of swerving motion. This work focuses on swerving orientation prediction with the restricted conditions. By importing the mathematical models of canard force and moment into the projectile angular motion equations, trim angle induced by canard control force is extracted as the analytical solution of angle of attack increment (AOAI). On this basis, analytical orientations of trajectory angular rate increment and swerving increment are obtained via the frozen coefficient method. A series of simulations under different conditions were implemented to validate the expressions in this effort. Results state that increment orientation of swerving motion can be predicted with available trajectory parameters. The analytical orientations indicate trim value of numerical orientations. Deviations between analytical and numerical orientations relate to initial launch angles and control start time, both lower initial launch angle, and the start time which is closer to the end of flight decreases the deviation convergence time.
Highlights
To maintain flight stability, large caliber spin-stabilized projectiles are launched with high spin rate, usually 150–300 r/s [1]
The mass center and around mass center motions of projectile flight effected by canard control force are descripted by the mathematical model of 6-DOF rigid motions, which are established in four reference frames, respectively, inertial reference frame (IRF: xN-yN-zN), velocity reference frame (VRF: x2-y2-z2), no-roll reference frame (NRRF: ξ-η-ζ), and canard reference frame (CRF: ξc-ηc-ζc)
This paper focuses on the swerving orientation prediction for the square crossing fixed-cant canard configuration
Summary
Large caliber spin-stabilized projectiles are launched with high spin rate, usually 150–300 r/s [1]. High coupling between yaw and pitch flight dynamics makes the cost-effective guidance of spin-stabilized projectile a complex task [2]. The rear fin configurations are inapplicable for transforming unguided spin-stabilized projectiles into affordable guided ones In another indirect method, concept of square crossing fixed-cant canard is adopted [10, 11]. Detailed projectile swerving motion is not taken into consideration This concept can effectively improve the impact distribution through field test, but the guiding effect is partly affected by the empirical formula unable to vary with practical flight parameters. The analytical expressions without attitude information are deduced, which can predict the increment orientation for trajectory angular rate and swerving motion induced by canard control force. This work extends Murphy’s theory of gravity-induced trim angle [14] with a nose control force
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