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| '''Proportional navigation''' (also known as '''PN''' or '''Pro-Nav''') is a [[Guidance, navigation and control|guidance law]] (analogous to [[proportional control]]) used in some form or another by most homing air target [[missiles]].<ref>Yanushevsky, page 3.</ref> It is based on the fact that two vehicles are on a [[collision course]] when their direct [[Line-of-sight (missile)|Line-of-Sight]] does not change direction. PN dictates that the missile velocity vector should rotate at a rate proportional to the rotation rate of the line of sight (Line-Of-Sight rate or LOS-rate), and in the same direction.
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| : <math> a_n = N\dot \lambda V</math> | |
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| Where <math> a_n</math> is the acceleration perpendicular to instantaneous line of sight , <math> N</math> is the proportionality constant generally having an integer value 3-5 (dimensionless), <math>\dot \lambda</math> is the line of sight rate, and V is the closing velocity.
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| For example, if the line of sight rotates slowly from north to east, the missile should turn to the right by a certain factor faster than the LOS-rate. This factor is called the Navigation Constant (Knav). | |
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| [[image:PN.PNG]] | |
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| A useful vector notation expresses the acceleration normal to the instantaneous line of sight:
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| : <math> \vec a = N\vec V_r \times \vec \Omega</math> | |
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| where <math>\Omega</math> is the rotation vector of the line of sight:
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| : <math> \vec \Omega = \frac {\vec V_r \times \vec R}{ \vec R \cdot \vec R } </math>
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| where <math>\vec V_r = \vec V_t - \vec V_m</math> is the target velocity relative to the missile and <math>\vec R</math> is the range from missile to target.
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| A rather simple hardware implementation of this guidance law can be found in early [[AIM-9 Sidewinder]] missiles. These missiles use a rapidly rotating [[parabolic mirror]] as a seeker. Simple electronics detect the directional error the seeker has with its target (an [[Infrared|IR]] source), and apply a moment to this gimballed mirror to keep it pointed at the target. Since the mirror is in fact a [[gyroscope]] it will keep pointing at the same direction if no external force or moment is applied, regardless of the movements of the missile. The [[voltage]] applied to the mirror while keeping it locked on the target is then also used (although amplified) to deflect the control surfaces that steer the missile, thereby making missile velocity vector rotation proportional to line of sight rotation. Although this does not result in a rotation rate that is always exactly proportional to the LOS-rate (which would require a constant airspeed), this implementation is equally effective.
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| The basis of proportional navigation was first discovered at sea, and was used by navigators on ships to ''avoid'' collisions. Commonly referred to as [[Constant Bearing Decreasing Range]] (CBDR), the concept continues to prove very useful for conning officers (the person in control of navigating the vessel at any point in time) because CBDR will result in a collision or near miss if action is not taken by one of the two vessels involved. Simply altering course until a change in bearing (obtained by compass sighting) occurs, will provide some assurance of avoidance of collision. Obviously not foolproof, the conning officer of the vessel having made the course change, must continually monitor bearing lest the other vessel does the same. Significant course change, rather than a modest alteration, is prudent. [[International Regulations for Preventing Collisions at Sea]] dictate which vessel must give way but they, of course, provide no guarantee that action will be taken by that vessel. | |
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| ==See also==
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| * [[Motion camouflage]]
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| ==Bibliography==
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| * [http://www.scribd.com/doc/4928882/Tactical-and-Strategic-Missile-Guidance Tactical and Strategic Missile Guidance] by Paul Zarchan
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| * Yanushevsky, Rafael. ''Modern Missile Guidance''. CRC Press, 2007. ISBN 978-1420062267.
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| ==References== | |
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| {{reflist}}
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| {{DEFAULTSORT:Proportional Navigation}}
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| [[Category:Navigation]]
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| [[Category:Missile guidance]]
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