Ideal proportional navigation

Yuan, Pin-Jar; Chern, Jeng-Shing

doi:10.2514/3.20964

Cited by 136 publications

(47 citation statements)

References 6 publications

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“…In the area of homing guidance, proportional navigation (PN) algorithm [1,2] has been widely used because it is highly efficient and easy for implementation, such as true proportional navigation (TPN) [2], realistic true proportional navigation (RTPN) [3], and ideal proportional navigation (IPN) [4]. However, its poor performance in intercepting maneuvering targets has been exhibited because PN has the required accuracy to intercept a nonmaneuvering target or a weakly maneuvering target.…”

Section: Introductionmentioning

confidence: 99%

Guidance laws with input saturation and nonlinear robustH∞observers

Liao

Luo

et al. 2016

ISA Transactions

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Section: Introductionmentioning

confidence: 99%

Guidance laws with input saturation and nonlinear robustH∞observers

Liao

Luo

et al. 2016

ISA Transactions

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“…In the modified TPN, the commanded acceleration is applied in the direction normal to the LOS and its magnitude is proportional to the product of the LOS angular rate and the closing speed between the missile and aircraft [11]. Generalized proportional navigation (GPN) and ideal proportional navigation (IPN), two more such proportional navigation guidance systems, in which the commanded acceleration is applied in a direction with a fixed bias angle normal to the direction of the LOS and normal to the relative velocity between missile and aircraft, respectively, were presented recently [17], [19].…”

Section: Introductionmentioning

confidence: 99%

“…There are various guidance systems belonging to the family of proportional navigation. In pure proportional navigation (PPN), the commanded acceleration is applied in the direction normal to the missile's velocity, and the magnitude of the commanded acceleration is proportional to the speed of the missile and the angular rate of the line-of-sight (LOS) between the missile and the aircraft [2], [3], [7], [19]. In the traditional true proportional navigation (TPN), the commanded acceleration is applied in a direction normal to the LOS and its magnitude is proportional to the angular rate of the LOS [11].…”

Section: Introductionmentioning

confidence: 99%

Aim Identification with a Minimal Parameter Set

Ravindra

Bar‐Shalom

Gottesman

2007

2007 IEEE Aerospace Conference

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This paper considers the problem of using passive (line-of-sight angle) observations of a surface to air or an air to air missile (pursuer) from an aircraft (evader), to infer whether the missile is or is not aimed at the aircraft. The observations are assumed to be made only on an initial portion of the pursuer's trajectory. The approach is to model the trajectory of the missile with a number of kinematic and guidance parameters, estimate them and use statistical tools to infer whether the missile is guided toward the aircraft or not. A mathematical model is presented for a missile under pure proportional navigation with a changing velocity (direction change as well as speed change), to intercept a nonmaneuvering aircraft. A maximum likelihood estimator (MLE) is used for estimating the missile's motion parameters and a goodness-of-fit test is formulated to test if the aircraft is the aim or not. Using measurement data from several realistic missiles aimed at an aircraft, it is shown that the proposed method can solve this problem successfully. The key to the solution, in addition to the missile model parametrization, is the use of a reliable global optimization algorithm for the MLE. The estimation/decision algorithm presented here can be used for an aircraft to decide, in a timely manner, whether appropriate countermeasures are necessary.

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“…The acronym GIPN comes from the guidance velocity vector in the adopted interception scheme being proportional to the relative velocity between the target and missile if the navigation coefficients are constants and equal [1,2]. Although GIPN produces an acceleration command component that cannot be implemented easily in a real missile, it has been extensively studied due to its mathematical tractability.…”

Section: Introductionmentioning

confidence: 99%

Analysis of General Ideal Proportional Navigation Guidance Laws

Tyan¹

2015

Asian Journal of Control

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In this work, the capture region of the general ideal proportional navigation guidance law is analyzed with the following constraints: (i) the target's input acceleration is subject to independent or magnitude saturation, and (ii) the missile's input acceleration is subject to magnitude saturation. In addition to the case of unbounded maneuverability of missile with or without knowing the target acceleration, the necessary and sufficient condition for a bounded maneuvering missile that captures a nonmaneuvering target is also derived. Furthermore, the conditions that result in zero impact velocity are discovered and discussed in some of the cases. The capture regions that cannot be obtained analytically are determined numerically by a powerful classifier, the least square support vector machines. To have the capture region ready for least square support vector machines, all the state variables are transformed into modified polar variables and non-dimensionalized to reduce the number of independent variables. In order to make the implementation possible in real time, an approximation of the Gaussian radial basis function is adopted to obtain the corresponding nonlinear feature mapping function. Through numerous numerical experiments, the proposed technique is found to be adequate for storing the capture region in an onboard fire control computer.

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Ideal proportional navigation

Cited by 136 publications

References 6 publications

Guidance laws with input saturation and nonlinear robustH∞observers

Guidance laws with input saturation and nonlinear robustH∞observers

Aim Identification with a Minimal Parameter Set

Analysis of General Ideal Proportional Navigation Guidance Laws

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