Image You are Posting say other Wise Its Seeker is 14 km And Kinematic range 120 km
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Before FPA technogy
IRS missiles are smarter and use the gimballed seeker head combined with what is known as
proportional guidance in order to avoid oscillation and to fly an efficient intercept path.
I think it is quite clear you don't actually understand any of the words you have just written and basically just mashing different unrelated terms together
Firstly, the kinematic range of missile is the distance that it can fly before it fall down. It isn't related at all to the effective range or the engagement range. For example: AGM-65 can fly as far as 27 km but its LOBL seeker can't lock target from distance further than 10 km, so that reduce the engagement range of it significantly. R-27ET and R-27T suffer the same issue, they have big motor, but they are LOBL missile, so they can't take advantage of the maximum range of the motor.
Secondly, IIR missile also have
proportional guidance and gimballed head, the gimbal is used to increase the field of regard of the seeker (better HOBS) and the proportional guidance is used so that missile will aim at the future predicted position of the target instead of their current position
The difference between a spin reticle infrared missile and a focal plane array (imaging) infrared missile is not in the gimbal or the proportional navigation. The difference between them is in how they see their target. The reticle infrared missile such as R-73 and R-27ET has mechanical modulators, also known as reticle. In layman terms, a reticle is a circular lens with sequentially-arranged transparent and opaque or parts on it (this should not be confused with the reticle with cross hair often seen on sniper rifles).
The most simple form of reticle has 2 parts on it, one-half transparent, the other half opaque. As the reticle spins, the target radiation falling on the opaque portion is blocked and produces no detector signal. A target image falling on the transparent portion is passed on to the detector. As a result, when the reticle spinning, IR radiation from a target off center is alternately passed and blocked, resulting in amplitude modulation (AM). The phase of this modulation relative to a spin reference is used to tell target direction from center.
Finding target direction is not the only purpose of reticles, some forms of reticle also help seeker distinguish targets from the background signal. For that purpose, these reticles divided into very small opaque and transparent slides, this is often called full spokes reticles. The design is based on the assumption that the signal from real targets such as aircraft is often a point or very small, while false signal such as cloud reflection is often distributed over a large area. When the reticle rotates, it will chop the radiation from optics before they can go to the detector. If the targets are very large, such as clouds, the energy will transmit through most transparent slides, resulting in detection but with very little change in output signal. But if the target is small, IR radiation will pass through a single transparent slide only, resulting in an output signal in style of separate square pulses. This helps the missile distinguish between massive clutter such as clouds and real targets such as aircraft.
To give the seeker ability to determine the direction and at the same time distinguish between the signal from real target versus cloud, one method is to combine the 2 patterns introduced earlier into a single reticle, this form of reticles are called rising sun reticles. A rising sun reticle has one-half semi-transparent while the other half consists of fan blades shape sectors, these sectors are divided into transparent and opaque parts.
The method of determining target direction and rejecting clutter of rising sun reticles is the combination of two methods introduced before. It is important to note that, the way missiles scan will be the deciding factor for the pattern on their spatial filters. Most early IR missiles used spin scan tracker combined with rising sun reticles. For this scanning method, the goal is to get the target to the center of the reticle. When the target is at the center, the signal is not modulated by the reticle’s spoke, as a result, generate zero voltage for the detector and the missile knows it flying toward the correct direction.
The main problem with spin scan design and rising sun reticle design is that because the seeker always looking at the target, it is more vulnerable to decoys.
One way to get around this problem is by using conical scanning (con-scan) and full spokes reticles. Conical scanning in Infrared guided missiles is very similar to conical scanning of radar. In a conical scan tracker, the missile’s instantaneous field of view rotates around the target so that target is always at the center of the rotating “beam” pattern and the radiation from target is at the certain point on the edge of the reticles.
Using the same principles as introduced earlier, when the reticle rotates, thanks to the opaque spokes, it will chop the radiation from optics before they can go to the detector. If the target is at the center of the nutating beam, the detector output will have a fixed pulse width that equal to the chopping frequency of the reticles. On the other hands, if the target is not at the center of the nutating beam, the output of the detectors will have a varied pulse with.
Firstly You Don' really understand Guidance Principle
Do you Even Know What is "Homing of Target"
Once the missile closes to self-homing distance, it turns on its active radar seeker and searches for the target aircraft. If the target is in or near the expected location, the missile will find it and guide itself to the target from this point. If the missile is fired at short range, within visual range (WVR) or the near BVR, it can use its active seeker just after launch, making the missile truly "fire and forget"
Active radar homing is rarely employed as the only guidance method of a missile. It is most often used during the terminal phase of the engagement, mainly because since the radar transceiver has to be small enough to fit inside a missile and has to be powered from batteries, therefore having a relatively low
ERP, its range is limited.
To overcome this, most such missiles use a combination of Radio Command Guidance And INS modes in order to fly from the launch point until the target is close enough to be detected and tracked by the missile
Radio Command guidance is a type of
missile guidance in which a ground station or aircraft relay signals to a
guided missile via
radio control or through
a wire connecting the missile to the launcher and tell the missile where to steer in order to intercept its target. This control may also command the missile to detonate, even if the missile itself has a
fuze.
Typically, the system giving the guidance commands is tracking both the target and the missile or missiles via
radar. It determines the position and velocity of the target and the position and velocity of the missile and calculates whether their paths will intersect. If not, the guidance system will relay commands to the missile(s), telling them to move their fins in such a way to steer themselves in the direction necessary for them to end up on an interception course with the target. If the target maneuvers, the guidance system can notice this and update the missiles' course continuously to counteract the maneuvering. If the missile passes close to the target, either its own
proximity or
contact fuze will detonate the warhead, or the guidance system can estimate when the missile will pass near the target and send a detonation signal.
Dedicated
radio antenna or antennas for communicating with the missile(s). On others, the radar itself is actually able to send coded pulses which the missile can pick up and interpret as guidance commands. Sometimes to aid the tracking station, the missile will contain a radio transmitter, making it easier to track. Also, sometimes there is a dedicated radar antenna on the tracking station for tracking the missile as well as one or more for tracking targets. It is especially these types of systems which may be able to communicate with the missile via the same radar energy it uses for tracking it.
I fully understand what is "homing on target"
Seeker on active radar missiles are not powerful enough to lock on target from max range, so the mid course guidance is used to guide the missile till it can acquire the target by itself. But the point is that the radar seeker can discriminate and acquire target by themselves once they are at the target area. A reticle infrared seeker doesn't have that capability, that why most infrared guidance missile are LOBL and even the manufacturer admit R-27T and R-27ET must be used in lock-before launch mode. R-27T and R-27ET doesn't have a mid course command guide like R-27R and R-27ER because they must acquire target before they are launched, mid course guide is quite irrelevant once the seeker acquire target.
