某型战机追踪导引研究

基于对广泛应用与研究的各种比例导引律的比较与分析，提出应用纯比例导引实现战机追踪导引的方法，并通过追踪以不同机动方式逃逸的飞行目标的仿真，说明了它的正确性与可行性。     

基于分数阶微积分理论的最优导引律设计

随着技术的发展及战场环境的日益复杂化,拦截机动目标的需求越来越大。然而传统制导律在拦截机动目标时存在制导精度差、末端过载突变的问题,故提出了一种基于分数阶微积分理论的最优导引律。首先,介绍了分数阶微积分的定义、性质及其数字实现方法;然后,分析了弹目相对运动关系,通过分数阶变阶次建模和最优控制理论推导出了分数阶导引律;最后,仿真结果表明：与传统比例导引法相比,所设计的分数阶最优导引律能够保持比例导引法良好的追踪性能且拦截时间能够缩短2s,末端过载值趋近于0。该方法解决了传统比例导引法在末端由视线角速率发散而导致的末端过载突变问题。     

三维RTPN的追踪导引研究

描述三维RTPN导引的模型是超越非线性微分方程组，不易求解．常规的方法是进行线性化。通过坐标系的变换和引入辅助向量获得了解析的捕获域和截获时间，并在三维空间内对这种追踪导引过程进行了仿真验算。理论分析和仿真表明：所设计的追踪导引律，能使整个追逃过程是在一个由初始相对距离和初始相对速度确定的平面内进行；当导弹采用RTPN导引，目标分别以IPN、RTPN逃逸和非机动飞行时，拦截TPN逃逸导引的目标能量消耗大，截获时间长，捕获域小。     

捷联寻的制导系统弹体追踪导引方法研究

对捷联寻的系统的简易制导方法—弹体追踪法进行全面剖析 ,解析分析了弹体追踪法对导弹速度、目标速度的约束 ,以及弹体阻尼、滞后、舵偏到攻角之间的传递系数对弹体追踪导引性能的影响。通过数学推导及应用控制理论分析与仿真 ,弹体追踪法较比例导引和速度追踪法在导引特性和打击机动目标时性能较差 ,但其成本较低 ,是一种降低制导武器成本的简易制导方法。但采用弹体追踪法时 ,导弹和目标的速度不能太大 ,当制导武器系统在形成导引误差信号存在固有滞后时 ,弹体稳定回路需要有一定阻尼 ,且舵偏到攻角之间的传递系数不能太大 ,即飞行过程中攻角要较小。     

比例导引导弹理想弹道的动态修正

本文基于近红外导弹比例导引的要求，研讨了比例导引规律的实现问题，提出了比例导引理想弹道及其线性化，并实际考虑导弹在发射时的瞄准误差和在制导过程中目标机动运动，进行动态修正的基础上，得出了指导正确设计和使用比例引导弹的重要结论。     

螺旋俯冲机动突防的制导律设计

针对识别和拦截技术高度发展所带来的突防难题，提出高超声速滑翔飞行器（HGV）螺旋俯冲机动突防的概念，并为此设计了一种基于虚拟滑动目标的自适应比例导引律。首先，通过分析HGV绕目标飞行的运动学特性，建立对数型的螺旋运动模型，以该模型为基础利用曲线渐伸线原理设计虚拟目标的滑动轨迹。然后，采用包含时变附加项的比例导引律追踪虚拟目标，从而实现引导HGV进行螺旋俯冲机动以及对真实目标的打击。接着，为提高虚拟目标的跟踪精度以及抵抗外部干扰的能力，设计了制导参数的闭环非线性自适应律，能根据当前偏差在线选择制导参数值。此外，还分析了满足收敛条件的制导参数的取值范围以及其进入闭环更新的策略。最后，分别针对静止目标和低速移动目标进行数值仿真验证，结果表明所设计的制导律不但能够引导HGV实施螺旋俯冲机动，还能够准确地命中目标。     

现实真比例导引拦截任意机动目标捕获区域

主动机动突防技术的发展给大气层外动能拦截带来了严重困难。假设目标机动加速度方向垂直于弹目视线、形式任意且有界，分析了用于大气层外拦截制导的现实真比例导引律（RTPN）对该任意机动目标的捕获区域。首先在考虑拦截器存在机动过载饱和限制的情况下，推导了比例导引系数的选择范围，可使RTPN的制导指令加速度在拦截过程中不超过拦截器饱和过载；其次基于不等式分析方法，在不考虑拦截器过载限制时，推导了RTPN对任意机动目标的捕获区域；然后结合拦截器机动过载限制，推导了RTPN对任意机动目标的更加实用的捕获区域；最后通过数值仿真算例，验证了所提出的理论。     

拦截机动目标的模糊导引律研究

 使用模糊方法研究了三维实际追逃问题的最小能量导引律问题。首先,通过对一些状态变量的定义域进行在线模糊分区,一方面,将非线性模型变为模糊T-S线性模型;另一方面,又能方便地处理目标的任意机动而引起的目标运动方向的变化。其次,利用RH（Receding Hori-zon）控制方法和伴随技术,在目标作对抗性机动条件下,获得了一个有效拦截的导引律。数值仿真结果表明,由这种导引律导引的导弹能够精确拦截任意机动的目标。     

一种攻击大机动目标的变参数组合导引律

针对目标作大机动时的导引问题,提出了一种既简单又有效的比例加变结构组合导引律,给出了其设计机理,并在理论上对变参数进行了优化设计。通过仿真结果比较,验证了此组合导引律可以在固定时间内明显地减少追踪者的脱靶量。     

一种扩展的比例导引规律及其弹道方程的构建

在传统的动力学微分方程的基础上提出了一种扩展的比例导引法 ,并给出了该导引规律下的相对弹道方程。文中的推理过程表明 ,这种导引规律对导弹、目标的运动速度几乎没有限制 ,理论上说明运用该制导规律的导弹将能对付高机动大速度目标 ,其弹道方程的建立 ,使得研究该制导规律下的弹道特性成为可能。     

Unified approach to missile guidance laws: a 3D extension

Since the proportional navigation guidance law was first introduced, many of the researchers had proposed different methodologies to investigate the corresponding performances of all the existing guidance laws. Even though a unified approach was proposed a few years ago, other authors found that under the proposed framework, all the existing guidance laws, namely ideal proportional navigation (IPN), true proportional navigation (TPN), and pure proportional navigation (PPN), were indeed special cases of the mentioned general guidance law. However, the results were restricted to two-dimensional space. In this paper, the author not only extends the results to three-dimensional space, but also to general IPN (GIPN), general TPN (GTPN), and PPN. Unlike conventional researchers, a modified polar coordinate (MPC) is adopted. It is shown that with the property of this MPC, for the line of sight (LOS) based guidance laws (GIPN and GTPN) the number of differential equations required to fully describe the relative dynamics can be reduced from six to three, however, for the missile's velocity-based guidance law, i.e., PPN, five differential equations are required. All the terms of differential equations involve only products and additions of variables. For all the mentioned guidance laws in this paper, only two transformed variables are required to describe the capture region, while the third variable is required to provide the condition of finite turn rate.     

The proportional navigation dilemma-pure or true?

Two generic classes of proportional navigation (PN) laws are compared in detail. One class consists of pursuer-velocity-referenced systems, which include pure proportional navigation (PPN) and its variants; the second category consists of line-of-sight- (LOS-) referenced systems such as true proportional navigation (TPN), generalized true proportional navigation (GTPN), and generalized guidance laws. The existing closed-form solutions are discussed in detail, and the classical linear and quasilinear analytical solutions are summarized. A critical comparison is then made with regard to the definition, implementation, and analytical aspects of the guidance laws, including the method, the nature of solution, and an appraisal of the behavior of the pursuer motion resulting from the laws. It is established that, in spite of some restricted advantages in the solvability of the equations of motion, the LOS-referenced PN schemes suffer from serious limitations in terms of implementation and trajectory behavior. Among the major drawbacks are forward velocity variation requirement, relatively large control effort requirement, restrictions on initial engagement conditions to ensure intercept, lack of robustness, and possibility of unbounded acceleration. It is concluded that PPN is a better guidance law in a practical sense than TPN and its generalizations     

3D guidance law modeling

Proportional navigation (PN) guidance laws (GLs) have been widely used and studied in the guidance literature. But most of the guidance literature on PN has concentrated on the evaluation of empirical PNGLs or GLs obtained from very specific optimality considerations. The authors present a novel approach (called guidance laws modeling) to derive new GLs. They consider the basic requirements of capture and define a complete class of GLs that meet these requirements. It is shown that PN is a natural candidate in this class. The main consequence of this modeling process is the definition of two new GLs: one in 2D space and the other in 3D space. These new GLs can be interpreted as new generalizations of the true proportional navigation (TPN) GL. Moreover, it is shown that these generalizations allow the TPNGL to match the capturability performance of the pure proportional navigation (PPN) GL in terms of initial conditions which allow the guided object to reach its target     

Optimal pure proportional navigation for maneuvering targets

The optimal pure proportional navigation (PPN) guidance law with time-varying navigation gains is considered. Unlike the conventional optimal PPN approach where linearized model was assumed in the optimization process, this work exploits the exact nonlinear formulation of PPN to derive analytically the optimal time trajectory of the navigation gain to minimize a performance index which is a weighted sum of the final time and the integral of the squared acceleration. It is verified that the PPN scheme with constant navigation gain is not only optimal in the vicinity of the interception point, but also optimal for the whole trajectory, if the navigation constant is designed by the methodology proposed here. Based on the optimization results for nonmaneuvering targets, a recursive optimal PPN scheme is proposed for maneuvering targets, wherein the optimal navigation gain and time-to-go are predicted recursively during the interception, and trajectory and performance of the interceptor guided by optimal recursive PPN scheme are evaluated analytically.     

On the generalization of true proportional navigation

A simple framework to define generalized true proportional navigation (GTPN) guidance laws is presented. It is shown that this framework subsumes many of the generalizations presented in the earlier literature. The capture regions of a number of GTPN guidance laws are obtained through a rigorous qualitative analysis. The method of analysis is simpler and lends itself directly to an easy geometrical interpretation. A considerable amount of misinterpretation in the previous results, arising out of certain basic misconceptions, are corrected here. It is shown that a logical application of the guidance philosophy, through a minor modification of GTPN to take into account the direction of rotation of the line-of-sight (LOS), contributes substantially to the expansion of the capture region in the relative velocity space. In particular, it is shown that the capture region also extends to the negative closing velocity region, thus making the modified GTPN almost comparable, so far as the domain of capturability of guidance laws is concerned, to the pure proportional navigation (PPN) guidance law. A number of new results on the exact bounds on the capture region are derived and illustrated through examples     

Recursive time-to-go estimation for homing guidance missiles

This paper addresses the problem of computing accurate time-to-go estimates, which is an important issue in implementing various optimal guidance laws developed for missiles of time-varying velocity. A recursive time-to-go computation method which updates the time-to-go in a noniterative way is presented. The recursive method includes an error compensation feature which explicitly computes the time-to-go error produced by nonzero initial heading errors. The proposed method is simple and straightforward to implement for any missile velocity profiles. Various numerical examples show that the proposed method works effectively for optimal guidance laws as well as proportional navigation and augmented proportional navigation     

反舰导弹变系数修正比例导引研究

针对超音速反舰导弹自导段控制的特点，对比分析了两种典型的非线性导引规律即反馈线性化（FLGL）导引律和逆向接近导引律的优缺点，提出了一种称为变系数修正比例导引的方法，通过对其全弹道仿真结果的分析，说明所提出的导引规律是正确的，具有良好的应用效果。     

变结构控制在导弹制导中的应用综述

简要介绍了变结构控制理论和导弹制导律，对基于变结构控制的导弹制导律进行了比较详细的研究。重点介绍了各种制导律中滑模面的选择和制导律的设计，并给出了一些仿真结果。研究表明，由于变结构控制的应用．使得制导律具有很强的鲁棒性，比传统的比例导引律有更多的优越性。     

Ideal proportional navigation for exoatmospheric interception

Ideal proportional navigation (IPN) is a natural choice for exoatmospheric interception for its mighty capture capability and ease of implementation. The closed-form solution of two- dimensional ideal proportional navigation was conducted in previous public literature, whereas the practical interception happens in the three-dimensional space. A novel set of relative dynamic equations is adopted in this paper, which is with the advantage of decoupling relative motion in the instantaneous rotation plane of the line of sight from the rotation of this plane. The dimension-reduced IPN is constructed in this instantaneous plane, which functions as a three-dimensional guidance law. The trajectory features of dimension-reduced IPN are explored, and the capture regions of dimension-reduced IPN with limited acceleration against nonmaneuvering and maneuvering targets are analyzed by using phase plane method. It is proved that the capture capability of IPN is much stronger than true proportional navigation (TPN), no matter the target maneuvers or not. Finally, simulation results indicate that IPN is more effective than TPN in exoatmospheric interception scenarios.