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Some topics in multiple hypothesis estimation and control using non-quadratic cost functionsTanner, Gwen Lettice January 1997 (has links)
No description available.
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Digital bank-to-turn control and guidanceMcConnell, George January 1988 (has links)
No description available.
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Estimation for homing guidanceKee, Ronald James January 1992 (has links)
No description available.
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Application of optimal control to bank-to-turn CLOS guidanceRoddy, D. J. January 1985 (has links)
No description available.
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Modern filter-controllers for bank-to-turn CLOS guidanceFleming, Ronald John January 1987 (has links)
No description available.
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Integrated tracking and guidanceBest, Robert Andrew January 1996 (has links)
No description available.
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Sensors, measurement fusion and missile trajectory optimisationMoody, Leigh January 2003 (has links)
When considering advances in “smart” weapons it is clear that air-launched systems have adopted an integrated approach to meet rigorous requirements, whereas air-defence systems have not. The demands on sensors, state observation, missile guidance, and simulation for air-defence is the subject of this research. Historical reviews for each topic, justification of favoured techniques and algorithms are provided, using a nomenclature developed to unify these disciplines. Sensors selected for their enduring impact on future systems are described and simulation models provided. Complex internal systems are reduced to simpler models capable of replicating dominant features, particularly those that adversely effect state observers. Of the state observer architectures considered, a distributed system comprising ground based target and own-missile tracking, data up-link, and on-board missile measurement and track fusion is the natural choice for air-defence. An IMM is used to process radar measurements, combining the estimates from filters with different target dynamics. The remote missile state observer combines up-linked target tracks and missile plots with IMU and seeker data to provide optimal guidance information. The performance of traditional PN and CLOS missile guidance is the basis against which on-line trajectory optimisation is judged. Enhanced guidance laws are presented that demand more from the state observers, stressing the importance of time-to-go and transport delays in strap-down systems employing staring array technology. Algorithms for solving the guidance twopoint boundary value problems created from the missile state observer output using gradient projection in function space are presented. A simulation integrating these aspects was developed whose infrastructure, capable of supporting any dynamical model, is described in the air-defence context. MBDA have extended this work creating the Aircraft and Missile Integration Simulation (AMIS) for integrating different launchers and missiles. The maturity of the AMIS makes it a tool for developing pre-launch algorithms for modern air-launched missiles from modern military aircraft.
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Sensors, measurement fusion and missile trajectory optimisationMoody, Leigh 07 1900 (has links)
When considering advances in “smart” weapons it is clear that air-launched
systems have adopted an integrated approach to meet rigorous requirements,
whereas air-defence systems have not. The demands on sensors, state
observation, missile guidance, and simulation for air-defence is the subject of
this research. Historical reviews for each topic, justification of favoured
techniques and algorithms are provided, using a nomenclature developed to unify these disciplines. Sensors selected for their enduring impact on future systems are described and simulation models provided. Complex internal systems are reduced to simpler models capable of replicating dominant features, particularly those that adversely effect state observers.
Of the state observer architectures considered, a distributed system comprising
ground based target and own-missile tracking, data up-link, and on-board
missile measurement and track fusion is the natural choice for air-defence. An
IMM is used to process radar measurements, combining the estimates from
filters with different target dynamics. The remote missile state observer
combines up-linked target tracks and missile plots with IMU and seeker data to
provide optimal guidance information.
The performance of traditional PN and CLOS missile guidance is the basis
against which on-line trajectory optimisation is judged. Enhanced guidance
laws are presented that demand more from the state observers, stressing the
importance of time-to-go and transport delays in strap-down systems
employing staring array technology. Algorithms for solving the guidance twopoint
boundary value problems created from the missile state observer output
using gradient projection in function space are presented.
A simulation integrating these aspects was developed whose infrastructure,
capable of supporting any dynamical model, is described in the air-defence
context. MBDA have extended this work creating the Aircraft and Missile
Integration Simulation (AMIS) for integrating different launchers and missiles.
The maturity of the AMIS makes it a tool for developing pre-launch algorithms
for modern air-launched missiles from modern military aircraft.
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A New Paradigm in Optimal Missile GuidanceMorgan, Robert W. January 2007 (has links)
This dissertation investigates advanced concepts in terminal missile guidance. The terminal phase of missile guidance usually lasts less than ten seconds and calls for very accurate maneuvering to ensure intercept. Technological advancements have produced increasingly sophisticated threats that greatly reduce the effectiveness of traditional approaches to missile guidance. Because of this, terminal missile guidance is, and will remain, an important and active area of research. The complexity of the problem and the desire for an optimal solution has resulted in researchers focusing on simplistic, usually linear, models. The fruit of these endeavors has resulted in some of the world's most advanced weapons systems. Even so, the resulting guidance schemes cannot possibly counter the evolving threats that will push the system outside the linear envelope for which they were designed. The research done in this dissertation greatly extends previous research in the area of optimal missile guidance. Herein it is shown that optimal missile guidance is fundamentally a pairing of an optimal guidance strategy and an optimal control strategy. The optimal guidance strategy is determined from a missile's information constraints, which are themselves largely determined from the missile's sensors. The optimal control strategy is determined by the missile's control constraints, and works to achieve a specified guidance strategy. This dichotomy of missile guidance is demonstrated by showing that missiles having different control constraints utilize the same guidance strategy so long as the information constraints are the same. This concept has hitherto been unrecognized because of the difficulty in developing an optimal control for the nonlinear set of equations that result from control constraints. Having overcome this difficulty by indirect means, evidence of the guidance strategy paradigm emerged. The guidance strategy paradigm is used to develop two advanced guidance laws. The new guidance laws are compared qualitatively and quantitatively with existing guidance laws.
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Fuzzy Logic Guidance System Design For Guided MissilesVural, Ozgur Ahmet 01 January 2003 (has links) (PDF)
This thesis involves modeling, guidance, control, and flight simulations of a canard
controlled guided missile.
The autopilot is designed by a pole placement technique. Designed autopilot is
used with the guidance systems considered in the thesis.
Five different guidance methods are applied in the thesis, one of which is the
famous proportional navigation guidance. The other four guidance methods are
different fuzzy logic guidance systems designed considering different types of
guidance inputs.
Simulations are done against five different target types and the performances of the
five guidance methods are compared and discussed.
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