To maximize the payload mass, an aerocapture trajectory should be flown in such a way that both the final △V and the total heat load are minimized. At very high velocities, the heating due to radiation of high temperature gases in the shock-layer exceeds the heat due to convection. For some aerocapture missions, such a heat load can be 15 times larger than the heat load due to convection. Thus, convective heat load may in some cases be neglected. It is analytically proven that radiative heat load is minimized by the same trajectory that minimizes the final △V: a bang-bang trajectory, with full lift-up, full lift-down commands. Next, a novel guidance that plans a bang-bang trajectory with constraints in the attitude kinematics is introduced. This allows for achieving an optimal trajectory with only one parameter to be tuned. For the case studied, values of △V as low as 100 m/s can be ensured for entry angles between -6° and -5° and a large spectrum of perturbations; with the same guidance, radiative heat load is reduced by up to 20% with respect to traditional aerocapture-guidance methods. Finally, a lateral guidance that makes use of information on the final inclination of the predicted trajectory is introduced. Such guidance allows for very high accuracy in the inclination requirements with only two reversals, and also requires only a single parameter to be tuned. Depending on the tuning, a maximum inclination error of less than 0.1° can be guaranteed.
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机译:为了使有效载荷质量最大化,应以使最终ΔV和总热负荷均最小的方式飞行航空轨迹。在很高的速度下,由于冲击层中高温气体的辐射而产生的热量超过了由于对流引起的热量。对于某些航空飞行任务,由于对流,这种热负荷可能比热负荷大15倍。因此,在某些情况下可以忽略对流热负荷。分析证明,通过使最终△V最小的相同轨迹将辐射热负荷最小化:具有完全升起,完全升起命令的爆炸轨迹。接下来,介绍了一种新颖的指导,该指导计划了在姿态运动学上受约束的爆炸轨迹。这允许通过仅一个要调谐的参数来实现最佳轨迹。对于所研究的情况,对于-6°至-5°的入射角和较大的摄动范围,可以确保△V值低至100 m / s。在相同的指导下,与传统的航空制导方法相比,辐射热负荷最多可减少20%。最后,介绍了一种侧向引导,该侧向引导利用了有关预测轨迹的最终倾斜度的信息。这样的引导只需要两次反转就可以非常精确地满足倾斜要求,并且也只需要调整一个参数即可。根据调整情况,可以确保最大倾斜误差小于0.1°。
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