During the high-speed penetration of projectiles into concrete targets(the impact velocity ranges from 1.0 to1.5 km/s), important factors such as the incident oblique and attacking angles, as well as the asymmetric abrasions of the projectile nose induced by the target-projectile interactions,may lead to obvious deviation of the terminal ballistic trajectory and reduction of the penetration efficien y. Based on the engineering model for the mass loss and nose-blunting of ogive-nosed projectiles established, by using the Differential Area Force Law(DAFL) method and semi-empirical resistance function, a finit differential approach was programmed(PENTRA2D) for predicting the terminal ballistic trajectoryofmassabrasivehigh-speedprojectilespenetrating into concrete targets. It accounts for the free-surface effects on the drag force acting on the projectile, which are attributed to the oblique and attacking angles, as well as the asymmetric noseabrasionoftheprojectile.Itsvalidationontheprediction of curvilinear trajectories of non-normal high-speed penetrators into concrete targets is verifie by comparison with available test data. Relevant parametric influentia analyses show that the most influentia factor for the stability of terminal ballistic trajectories is the attacking angle, followed by the oblique angle, the discrepancy of asymmetric nose abrasion, and the location of mass center of projectile. The terminal ballistic trajectory deviations are aggravated as the above four parameters increase. During the high-speed penetration of projectiles into concrete targets (the impact velocity ranges from 1.0 to 1.5 km / s), important factors such as the incident oblique and attacking angles, as well as the asymmetric abrasions of the projectile nose induced by the based on the engineering model for the mass loss and nose-blunting of ogive-nosed projectiles established, by using the Differential Area Force Law It accounts for the free-surface effects on the drag force acting on the projectile, which are attributed to the oblique and attacking angles, as well as the asymmetric noseabrasionoftheprojectile.Itsvalidationonthepredi ction of curvilinear trajectories of non-normal high-speed penetrators into concrete targets is verifie by comparison with available test data. Relevant parametric influentia analyses show that the most influentia factor for the stability of terminal ballistic trajectories is the attacking angle, followed by the oblique angle, the discrepancy of asymmetric nose abrasion, and the location of mass center of projectile. The terminal ballistic trajectory deviations are aggravated as the above four parameters increase.