EP3048410A1 - Seeker for a guided missile - Google Patents

Abstract

The invention relates to a seeker head (4) for a guided missile (2) with an outer housing (58, 60), a detector unit (20) with a matrix detector (22), an optical system (6) for imaging an object (28). from an object scene (30) surrounding the guided missile (2) to the matrix detector (22) comprising input optics (10) and an optical joint (12) and a roll pitch system (40) for aligning at least the input optics (10) on the object (28) with a rolling frame (42) and a pitch frame (44).

In order to be able to detect even distant and weakly radiating objects (28) when the guided missile (2) is rolling, it is proposed that the detector unit (20) is arranged roll-stable on the rolling frame (42).

Description

The invention relates to a seeker head for a missile with an outer housing, a detector unit with a matrix detector, an optical system for imaging an object from an object scene surrounding the missile to the detector comprising an input optic and an optical hinge and a roll pitch system for Aligning at least the entrance optics on the object with a rolling frame and a pitch frame.

Target seeking guided missiles are equipped with a seeker head with input optics that can track the movement of a moving target. For this purpose, an input optics is movably mounted to a dome of the missile or its outer casing and driven by a motor so that it is pivotable in a large angular range. Such a viewfinder optics is from the DE 10 2010 055 493 A1 known.

For detecting targets which are located at a very long distance from the missile, a very accurate image with small aberrations on an imaging unit, such as a matrix detector, is advantageous in order to reliably detect the target as such, even at a great distance.

It is an object of the present invention to provide a seeker head for a guided missile, with which even small and distant objects can be found.

This object is achieved by a seeker head of the type mentioned, in which according to the invention, the detector unit is arranged roll-stable on the rolling frame.

The invention is based on the consideration that it requires the optical detection of very distant and small targets of a very sensitive seeker. The sensitivity of a seeker depends especially on the exposure time of the detector system, so for example the integration time of a matrix detector. The maximum possible exposure time for a sharp imaging of the object on the matrix detector in turn depends on the scene dynamics during the integration time, ie on the movement of the image of the object over the detector surface.

The invention further proceeds from the consideration that it may be advantageous to let a guided missile roll around the missile axis during its flight. Correspondingly, the search head, which is structurally connected to the guided missile, rolls along with it and also a matrix-fixedly arranged matrix detector. In order to be able to track a somewhat laterally located object, for example, the input optics of the seeker head oriented thereon must be unrolled, ie rotated at the same roll rate counter to the direction of roll of the seeker head so that it remains stationary in space. There is thus a relative rotation between input optics and a structure-fixed matrix detector. Accordingly, the object imaged by the optics also rotates on the sensitive surface of the matrix detector.

Depending on the roll speed of the guided missile, the object scene smeared by this rotation, in particular on the edge of the sensitive area of the matrix detector, so that details such as point targets can no longer be clearly recognized there. This reduces the sensitivity of the seeker and thus its optical range. Although image enhancement algorithms can reduce image blurring in the edge area of the sensitive area of the matrix detector, it is not complete enough to obtain high sensitivity of the seeker during fast reel.

To solve this problem, the invention proposes the separation of matrix detector and outer housing according to the invention. By attaching the detector unit to the rolling frame, the matrix detector is rotated with the input optics, so that the object imaged by it is dot-stable on the matrix detector even with an enrotation rotation of the input optics. As a result, the maximum integration time and thus the sensitivity of the seeker, for example, be limited only by the refresh rate and no longer from the roles of the missile. It can be realized a highly sensitive seeker for finding even small and distant objects.

The seeker head is advantageously arranged at the tip of the guided missile and in particular under a dome. The optical system suitably comprises a catadioptric optic with an input optic and an optical hinge. The input optics in particular comprises Cassegrain optics and is expediently designed in the form of a mirror optic having a concave aspherical main mirror and a convex aspherical aspirating mirror. The primary mirror, that is, the mirror on which the rays from the object scene first impinge, as well as the secondary mirror are expediently arranged in the pitch frame and thus about the roll axis coaxial with the missile axis or Suchkopfachse, and a pitch axis two-dimensional pivot.

The optical joint is expediently used to track the beam path onto the matrix detector during a movement of the input optics. The optical joint may be a mirror joint with multiple mirror surfaces. Particularly advantageously, the optical joint is a prism joint with a plurality of reflective prisms. It is expedient to have four mirrors or reflecting prism surfaces. A simple embodiment of the optical joint can be achieved if the beam path from the input optics extends at least partially within the optical joint symmetrically to the roll axis and to the pitch axis of the optics. In the transition from a primary part to a secondary part of the optical joint, the beam path expediently runs symmetrically to the pitch axis.

The missile is suitably an actively propelled missile with a rocket engine and steering vanes for controlling the flight and directing the orientation of the missile. For this purpose, the guided missile, in particular the seeker head, is equipped with a control unit which is prepared for steering the missile in response to the signals of the matrix detector and for this purpose activates the steering vanes of the guided missile.

The detector unit is arranged roll-stable on the rolling frame, so attached to the rolling frame in such a way that it rotates with each rolling movement of the rolling frame. The matrix detector is expediently sensitive in the infrared spectral range, so that heat sources can be detected.

In order to at least largely suppress a thermally induced excitation of charge carriers in the matrix detector and thus noise of the matrix detector, the seeker head in an advantageous embodiment of the invention comprises a cooler for cooling the matrix detector. During operation, the operating temperature of the matrix detector is expediently cooled down to a temperature whose equivalent spectral range in the radiation maximum lies energetically below the sensitive spectral range of the matrix detector.

In order to realize a short cooling time at the start of operation of the matrix detector, a relatively bulky cooler, for example a Joule-Thomson cooler, is necessary. Such a cooler would represent a large moment of inertia on the roll axis if it were to co-roll with the detector unit. To avoid this, the radiator is expediently arranged rigidly to the outer housing. In a rolling movement of the missile and a Entrollbewegung the input optics, the detector unit thus rotates to the radiator, but otherwise remains in the other spatial directions expediently immovable to the radiator.

In order to achieve a good cooling of the matrix detector, the cooler is expediently a gas cooler with a gas outlet, which is expediently aligned with the detector unit. In addition, the gas outlet is advantageously parallel, in particular coaxial, aligned with the roll axis. During operation, relaxed and cooled by the expansion cooling gas escape from the gas outlet and meet the detector unit and cool it.

To allow the relative rotational movement between the matrix detector and the cooler, a gap can be arranged between these two units. In order to prevent excessive leakage of the cooling gas from a cooling gas volume, the gap is suitably sealed by means of a ceramic seal. Also possible is a silicone seal or a seal with polytetrafluoroethylene (PTFE). Appropriately, the sealing surfaces of the seal are biased pressed against each other. During a rolling movement, the two sealing surfaces rub against each other and thus maintain their sealing effect.

The image signals generated by the matrix detector are transmitted to a control unit for evaluation. The control unit is expediently structurally fixed in the seeker head, that is to say fixed rigidly to the outer housing, at least with a part which carries out the image evaluation and / or controls a rolling drive. Due to the unrolling movement, ie the roll relative movement of the matrix detector to the outer housing, it is necessary to transmit the data to the control unit via a communication unit permitting the rolling motion of the matrix detector.

The communication unit can be equipped with sliding contacts, which are guided via a slip ring. At a high data rate, it is advantageous to transmit the detector signals without contact. For this purpose, the communication unit expediently comprises a transmitter and a receiver for wireless data transmission between transmitter and receiver, in particular from the matrix detector to the control unit and / or vice versa. The transmitter is, for example, frame-mounted and the receiver is fixed to the housing. One possibility for wireless data transmission may be the inductive coupling, with two conductor loops or antennas forming the transmitter and the receiver. Also a capacitive coupling is possible. Furthermore, an optical data transmission for wireless transmission of the data can be considered. Ideally, a known data transmission standard with sufficient data rate, for example WLAN or WHDI, is used.

A power supply of the matrix detector is advantageously carried out via a slip ring. In this respect, expediently a power supply device is present, which has a power storage, a slip ring and a power line between the power storage and slip ring. The slip ring is suitably connected to a grinding element, which rotates in contact with the rolling ring during an unwinding movement. The grinding element is expediently wired to a current input of the detector unit.

If the guided missile rolls during its flight and the matrix detector is unrolled in order to obtain a still image of the object, the rolling frame is advantageously held stationary relative to the outside space of the seeker head or relative to the object scene with respect to the rolling movement. In other words, the absolute roll rate of the rolling frame disappears. The absolute roll rate here can be understood as a geo-related rolling movement per time, which disappears when the input optics are focused on a stationary object relative to the seeker head.

The speed of the rolling movement of the outer housing, that is, its roll rate, is usually derived from a measured variable of a structure-fixed sensor in order to initiate a control of a rolling drive an equally fast counter-rolling of the rolling frame, so its Entolling, so that the absolute roll rate of the input optics disappears. This can be done using the so-called "strapdown principle" take place, in which is closed from a course of an acceleration to the rolling rate of the outer housing and hereby the rolling drive is controlled.

Alternatively or additionally, there is the possibility that the absolute roll rate of the rolling frame is sensory detected as such, in particular by a rolling frame fixed roll sensor. The thus detected absolute roll rate can then be controlled by means of a sensor signal to zero or a desired roll value.

For this purpose, the seeker head in a further advantageous embodiment of the invention comprises a rolling frame fixedly arranged roll sensor for detecting a rolling movement of the rolling frame. The roll sensor may be an acceleration sensor, such as a gyro sensor, a yaw rate sensor, an inertial inertial sensor (IMU), or the like. Due to the rolling-frame-fixed arrangement, ie the rigid connection to the matrix detector, a rolling motion of the matrix detector and also a movement of the input optics rigidly coupled to the matrix detector with respect to the rolling can be measured.

The control of the rolling frame is expediently carried out by a control unit for controlling further drives of the seeker head, for example a pitch drive. The control unit may be identical to the control unit for steering the missile during its flight and for controlling the seeker head functions.

In a further advantageous embodiment of the invention, the seeker head comprises a housing-mounted motion sensor for detecting the movement of the outer housing. Through this, a roll rate can be determined and a roll drive of the rolling frame can be controlled or regulated so that it assumes a desired roll value.

The invention is further directed to a method of imaging an object of an object scene onto a missile seeker array detector in which an input optics of an optical system of the seeker head is imaged by means of a roll pitch system having a rolling frame and a pitch frame Object is aligned and the object is imaged by the optical system on the matrix detector.

It is an object of the method directed invention to provide a method of imaging even a small and distant target the matrix detector and a sensory detection of this target can be done with the aid of the matrix detector.

This object is achieved by a method of the type mentioned above, in which, according to the invention, an outer housing of the seeker head rolls around a roll axis relative to the object scene surrounding it and the matrix detector rotates relative to the outer housing and rolls with the rolling frame.

In an advantageous embodiment of the invention, the image of the object rests on the matrix detector with outer housing rolling around the roll axis. Expediently, the matrix detector also rests in the space in the frame of the rolling frame. Such a rest applies, for example, to a mapped object that is stationary relative to the roll axis. During a movement of the object relative to the seeker head, the imaging of the object can also move over the sensitive area of the matrix detector. In this case, the input optics is expediently tracked to the moving object, whereby this expediently also the matrix detector is tracked in its rolling motion. The alignment of the input optics on the object is advantageously carried out by a rotation about two axes relative to the missile axis, in particular a roll axis and a pitch axis. The resting of the matrix detector in space, so a disappearance of the absolute rolling motion, can be achieved by driving the rolling frame against the rolling direction of the outer housing.

The matrix detector is expediently a detector sensitive in the infrared spectral range. In order to keep a thermally induced excitation of charge carriers in the matrix detector and thus a noise of the matrix detector as low as possible, the matrix detector is advantageously cooled. For this purpose, advantageously from a housing-mounted cooler of the seeker head cooling gas is sprayed against a detector having the matrix detector and rotating relative to the radiator about the roll axis detector unit.

In order to enable a stable alignment of the input optics on the object, it is proposed in a further advantageous embodiment of the invention that a roll rate of the rolling frame is detected by a rolling frame fixedly arranged roll sensor. Conveniently, the roll rate is controlled to a desired roll value using the roll sensor data. The controller may include a controller so that the roll value is controlled to the desired roll value. The roll rate may be the absolute roll rate, ie a roll speed relative to the object scene.

A further advantageous embodiment of the invention provides that a rolling rate of the outer housing is determined with the aid of an outer housing-fixed motion sensor. The motion sensor is expediently an inertial sensor, in particular an acceleration sensor or a yaw rate sensor. With the aid of the determined value of the roll rate, a rolling drive can be controlled so that the rolling frame is rotated relative to the outer housing in opposition to its rolling direction of rotation. The roll rate of the rolling frame is thereby reduced. Also in this way, the rolling rate of the rolling frame can be controlled or regulated to a desired roll value.

Depending on the accuracy of the motion sensor, it may happen that the rolling frame rolls with a remaining roll rate, so does not rest completely free of space in the room. Such a remaining absolute roll rate can be detected by means of a roll frame fixed roll sensor. Conveniently, the roll rate is controlled by the data of the roll sensor to a desired roll value, in particular regulated. This control is advantageously done with data from both the motion sensor and the roll sensor.

In order to detect even rapid movements of the rolling frame, it is advantageous if the roll sensor is a sensor that can reliably detect even very fast movements. However, for cost and / or weight reasons, it may be expedient to use a simpler sensor in which it may happen that over the course of time it has a measurement error, in particular a cumulative measurement error, for example in the form of a drift. In order to reduce this at least in part, it is proposed that in the control of the roll rate to the desired roll value, a measurement error of a rolling frame fixed roll sensor with the help of a housing-fixed motion sensor is at least partially detected and taken into account. If, for example, there is a measurement error of the roll sensor that fluctuates greatly over time, then it can be detected by the stationary motion sensor and / or at least partially compensated.

During a movement of the object, in particular a rapid movement around the seeker head around, the input optics expediently remains aligned with the object. Accordingly, the rolling frame rolls to allow such tracking of the entrance optics on the object. In the following, such roles as rolling motion, so that even at a roll rate of zero, a rolling motion is possible, however, by tracking the input optics on a caused by the roll axis moving object is caused. Such a rolling motion can be very fast, especially when the object is moving through or near the roll axis. In order to keep the absolute roll rate stable on the desired roll value, it is also advantageous if, with the aid of the roll sensor, a rolling movement is detected in addition to the roll rate of the roll frame, which is generated by tracking the object with the input optics.

Appropriately, the rolling drive is controlled so that controlled by means of the driven for tracking the object rolling motion and the data of the roll sensor, a roll rate of the rolling frame to the desired roll value, in particular regulated. The movement of the image of the object on the sensitive surface of the matrix detector can be used reliably for evaluating the movement of the object relative to the seeker head or to the roll axis.

Another possibility for controlling the absolute roll rate to a desired value is to determine a roll rate of the roll frame by means of data obtained from an image of the object scene on the matrix detector. Accordingly, the roll drive can be controlled and the roll rate controlled to a desired roll value, in particular regulated.

The previously given description of advantageous embodiments of the invention contains numerous features, which are given in the individual subclaims partially summarized in several. However, these features may conveniently be considered individually and summarized to meaningful further combinations. In particular, these features can be combined individually and in any suitable combination both with the method according to the invention and with the device according to the invention according to the independent claims. Thus, process features can also be formulated objectively as properties of the corresponding device unit and vice versa. For example, the control unit is suitable and prepared to carry out corresponding method features.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of embodiments, which will be described in connection with the drawings. The embodiments serve to explain the invention and do not limit the invention to the combination of features specified therein, not even in terms of functional features. In addition, suitable features of each embodiment may also be explicitly considered isolated, removed from one embodiment, incorporated into another embodiment to complement it, and / or combined with any of the claims.

FIG 1

einen schematischen Längsschnitt durch den vorderen Teil eines Lenkflugkörpers mit einem Suchkopf und

FIG 2

ein Ablaufschema eines Verfahrens zum Entrollen einer Eingangsoptik.

Show it:

FIG. 1

a schematic longitudinal section through the front part of a guided missile with a seeker head and

FIG. 2

a flowchart of a method for unrolling an input optics.

FIG. 1 shows the front part of a guided missile 2 in a schematic longitudinal section and there in particular the seeker head 4 at the tip of the missile 2. The seeker 4 is equipped with an optical system 6, which is located immediately behind a dome 8 in a foremost tip of the seeker 4 , The optical system 6 comprises a Cassegrain optics with an input optics 10 and an optical joint 12. The input optics 10 includes a concave primary mirror 14 and a convex catching mirror 16. Via the optical joint 12, the input optics 10 are optically via a detector optics 18 with a detector unit 20, which has a matrix detector 22 on a carrier 24 in a detector housing 26. An object 28 of an object scene 30 is imaged onto the matrix detector 22 via the input optics 10, the optical joint 12 and the detector optics 18.

The optical joint 12 is formed of two prism blocks 32, 34, which are designed to be movable relative to each other. Here, the first prism block 32 is pivotable relative to the second prism block 34 about a pitch axis 36 and both prism blocks 32, 34 are rotatable about a roll axis 38, which extends in the axial direction or the longitudinal axis of the guided missile 2. The first prism block 32 is fixedly connected to the input optics 10 so that it is rotatable about the pitch axis 36 and the roll axis 38. The second prism block 34 is firmly connected to the detector optics 18 and the detector unit 20, so that these units are rotatable in the operation of the seeker head 4 only about the roll axis 38.

The entire optical system 6 is therefore stored in a roll pitch system 40, the rolling frame 42 and pitch frame 44 in FIG. 1 are shown only schematically. The rolling frame 42 carries all rolling elements of the optical system 6, including the nickbaren elements, and is rigidly attached to a rotor block 46. The pitch frame 44 carries all nickbaren elements, such as the input optics 10 and the prism block 32nd

The detector unit 20 is also fixed to the rotor block 46 which is rotatable about the roll axis 38 via bearings 48 by means of a rolling drive 50 having a rotor 52 and a stator 54. About the bearing 48, the rotor block 46 is held in a stator block 56 which is rigidly secured to the outer housing 58 of the seeker head 4 and the outer housing 60 lying behind it of the other missile 2. Attached to the rear of the stator block 56 is a radiator 62 having a forwardly directed gas outlet 64 which is aligned with the detector unit 20 and opens immediately thereafter. The cooler 62 is supplied with gas via two gas containers 66 during the operation of the seeker head 4.

Also rigidly connected to the rotor block 46 and thus rotatable about the roll axis 38 is a nickel electronics 68, a roll sensor 70, a detector electronics 72 and a communication unit 74 with a transmitter 76 and a receiver 78. The transmitter 76 can also be used as a receiver and the receiver 78th act as a transmitter, so that bidirectional communication is possible. Transmitter 76 and receiver 78 are designed as annular discs, and the transmitter 76 is rigidly connected to the rotor block 46 and the receiver 78 is rigidly connected to the stator block 56.

Furthermore, the rotor block 46 carries a power transmission unit 80 with a slip ring 82 and a brush 84 for transmitting electrical energy from a housing-fixed energy storage, not shown, to the detector unit 20. Here, the slip ring 82 is wired to the detector unit 20 and the brush 84 to the energy storage. Connected to the rotor block 46 is also an optical grating 86 by means of which an optical tap 88 of a housing-fixed control unit 90, the rotational speed of the rotor block 46 relative to the stator block 56 can be determined. The rolling rate of the stator block 56 or of the outer housing 58 can be detected by the control unit 90 via a motion sensor 92, which is likewise fixed to the housing, and which is designed as an initial sensor or IMU (inertial measurement unit). For this purpose, the motion sensor 92 detects acceleration values, for example a centrifugal force acceleration and / or accelerations in other spatial directions, and thereby determines from an initial state a later instantaneous state, for example a roll rate, an airspeed and optionally other further variables.

The guided missile 2 is a self-propelled and not shown rudder steerable missile, which is launched for example from a canister. About his rocket engine, the guided missile 2 flies toward a predetermined destination, which is stored for example in the control unit 90 or another control unit, for example by means of coordinates. Also possible is the specification of an optical target, for example, the object 28, which is optically detected and passed before or after the start of the missile 2 to the corresponding control unit 90. As it approaches the object 28, it is imaged on the matrix detector 22 via the optical system 6. A movement of the image of the object 28 on the sensitive surface of the matrix detector 22 firstly leads to a movement of the input optics 10 so that it remains aligned as centered as possible on the object 28. Secondly, the movement leads to a steering command for aligning the longitudinal axis of the guided missile 2 in the direction of the object 28, so that the guided missile 2 follows the object 28 in this manner.

Prior to the activation of the matrix detector 22, it is cooled down by the cooler 62 to a temperature at which a thermally induced excitation of charge carriers in the matrix detector 22 and thus a noise of the matrix detector 22 in the infrared spectral region is greatly reduced compared to room temperature, so that weakly radiating in the infrared Objects of the object scene 30 and in particular the targeted object 28 are detected. For this purpose, in the interior of the cooler 62 relaxed and thus greatly cooled cooling gas is blown through the gas outlet 64 to the rear side of the carrier 24, so that this and strongly cool the matrix detector 22 with him. The gas is distributed in the gap between the rotor block 46 and the radiator 62 to the rear and is discharged there.

During the flight of the guided missile 2, it may happen that this rolls around its roll axis 38. This can cause roll rates of more than 1 Hz. Without an unrolling of the rolling frame 42 or the rotor block 46, the field of view of the input optics 10 would rotate at this frequency and a focus on the object 28 would be possible only in an orientation of the input optics 10 exactly in the direction of the roll axis. Nevertheless, an exact lateral focusing of the Input optics 10 to allow the object 28, the roll rate of the outer housing 58 and the stator block 56 is detected by the motion sensor 92. Based on the data of the motion sensor 92, the control unit 90 controls the rolling drive 50, so that the rolling frame 42 rotates counter to the rolling direction of the outer housing 58 and with the rolling rate determined by the motion sensor 92. As a result, the alignment of the detector optics 18 in the room - apart from changes caused by the airspeed and possibly change in direction of the missile 2 - and also the image of the object 28 rests accordingly rests, with no proper movement of the object 28, on the sensitive surface of the matrix detector 22.

An alternative method of unrolling may be performed using the roll sensor 70. This can also detect a roll rate of the rolling frame 42, so that the control unit 90, which is connected to the roll sensor 70 via the communication unit 74, can control an unrolling of the rolling frame 42 by the corresponding control of the rolling drive 50. In this method, it is also possible to control the roll rate of the rolling frame 42. The controlled variable here is, for example, a measured centrifugal force acceleration, which acts on the roll sensor 70. The feed of the rolling drive 50 is controlled by the control unit 90 so that the centrifugal force and thus the absolute roll rate are regulated to zero, for example.

Another method is the interaction of the motion sensor 92 with the roll sensor 70 to control the absolute roll rate of the roll frame 42 to a desired roll value, such as zero. For this, the absolute roll rate is controlled by means of the control unit 90 and the motion sensor 92 as described in the first method. In principle, the roll sensor 70 would have to confirm the desired absolute roll rate. If this is not the case, the signal of the roll sensor 70 can be used as an additional signal from the control unit 90 to set the desired absolute roll rate of the rolling frame 42. The unrolling thus consists of two components: a component resulting from the signal of the motion sensor 92 and a component resulting from the signal of the roll sensor 70 and added to the first component.

In a rapid movement of the object 28 transversely to the roll axis 38, in particular when moving very close to the roll axis 38 over, the tracking of the Object 28 with the input optics 10 lead to a very sudden and very fast rolling movement of the rolling frame 42. This rolling motion is a movement that is detected by the roll sensor 70 in addition to the rotation of the rolling frame 42. The roll sensor 70 is prepared for this purpose and thus a very fast detecting sensor, which is able to accurately detect fast movements and rapid movement changes. Since the rolling motion of the rolling frame 42 for tracking the input optics 10 is controlled by the control unit 90 and controlled by means of the optical grating 86, the control unit 90 can also separate this rolling motion from the unrolling movement of the rolling frame 42 from the signal from the roll sensor 70. A control of the Entrollrotation remains possible.

In a further method, it may happen that the measurements of the roll sensor 70 are subject to a measurement inaccuracy. For example, a drift that can result in a roll measurement error is added from a plurality of fluctuating accelerations. Such a measurement error can be detected by the control unit 90 using the data of the motion sensor 92. The motion sensor 92 rotates relatively constantly with the roll rate of the outer housing 58, and its possible measurement error can be detected and compensated by the signal of the roll sensor 70 from the control unit 90. If measurement errors of the roll sensor 70 occur later, for example caused by strong Nachlenkbeschleunigungen the input optics 10, these errors can be detected by the data of the motion sensor 92 and compensated by the control unit 90, since this less stressed in the time of strong deflection of the input optics 10 is and delivers more accurate results.

Of course, it is also possible to combine individual components of the described method for controlling, in particular regulation, the roll rate to a desired roll value.

A corresponding procedure is in FIG. 2 exemplified. The motion sensor 92 detects a first roll rate RR ₁ and supplies the corresponding data to the control unit 90. This controls the roll drive 50 to unroll the roll frame 42. A roll roll RR ₂ is detected by the roll sensor 70, which feeds its data to the control unit 90. With the aid of this correction data, the roller drive 50 is likewise activated, so that a more accurate unrolling takes place. This is detected in a control loop by the roll sensor 70 and used by the control unit 90 for control.

A movement of the image of the object 28 on the sensitive surface of the matrix detector 22 is detected by the detector electronics 72 and corresponding data is supplied to the control unit 90. This controls a tracking of the input optics 10 on the object 28, so that an additional rolling movement RB of the rolling frame 42 is generated, which is added to the desired roll rate. The rolling motion RB is detected by the roll sensor 70 and the corresponding signal is passed on to the control unit 90. This separates from the signal the two movements, namely the residual rolling rate RR ₂ of the rolling motion RB, and further controls the rolling drive 50 so that the residual rolling rate RR ₂ disappears or assumes a desired value.

Depending on the nature of the object scene 30, its image on the sensitive surface of the matrix detector 22 can also be used to set the absolute roll rate. If, for example, a horizon is depicted, the sun and or another known and stable object, its image rests on the sensitive surface of the matrix detector 22 as the roll frame 42 disappears and the flight of the guided missile 2 disappears of the rolling frame 42 can be detected by a circular scan of the image on the matrix detector 22, for example by image acquisition. This circle can be used to control the absolute roll rate.

LIST OF REFERENCE NUMBERS

2

Missile

4

seeker

6

optical system

8th

cathedral

10

input optics

12

optical joint

14

Primehrspiegel

16

Fangspiegel

18

detector optics

20

detector unit

22

matrix detector

24

carrier

26

detector housing

28

object

30

object Scene

32

prism block

34

prism block

36

pitch axis

38

roll axis

40

Roll-pitch system

42

roll frame

44

Nick frame

46

rotor block

48

camp

50

roll drive

52

rotor

54

stator

56

stator block

58

outer casing

60

outer casing

62

cooler

64

gas outlet

66

gas tank

68

Nick electronics

70

roll sensor

72

detector electronics

74

communication unit

76

transmitter

78

receiver

80

Power transmission unit

82

slip ring

84

brush

86

optical grating

88

tap

90

control unit

92

motion sensor

RB

rolling motion

RR ₁

roll rate

RR ₂

Rest roll rate

Claims (15)

Seeker head (4) for a guided missile (2) with an outer casing (58, 60), a detector unit (20) with a matrix detector (22), an optical system (6) for imaging an object (28) from a guided missile (2 ) surrounding object scene (30) on the matrix detector (22) comprising an input optics (10) and an optical hinge (12) and with a roll pitch system (40) for aligning at least the input optics (10) on the object (28) with a rolling frame (42) and a pitch frame (44),
characterized,
that the detector unit (20) is arranged firmly on the roll roll frame (42). Seeker head (4) according to claim 1,
marked
by a cooler (62) for cooling the matrix detector (22), which is arranged rigidly to the outer housing (58, 60). Seeker head (4) according to claim 2,
characterized,
in that the cooler (62) is a gas cooler with a gas outlet (64) aligned coaxially with the roll axis (38) and on the detector unit (20). Seeker head (4) according to one of the preceding claims,
marked
by a communication unit (74) with a rolling frame fixed transmitter (76) and a housing-fixed receiver (78) for wireless data transmission between transmitter (76) and receiver (78). Seeker head (4) according to one of the preceding claims,
marked
by a roll frame fixed roll sensor (70) for detecting a rolling movement of the roller frame (42). Seeker head (4) according to one of the preceding claims,
marked
by a housing-mounted movement sensor (92) for detecting a movement of the outer housing (58, 60). A method for imaging an object (28) of an object scene (30) on a matrix detector (22) of a seeker head (4) for a guided missile (2) in which an input optics (10) of an optical system (6) of the seeker head (4) a roll pitch system (40) having a rolling frame (42) and a pitch frame (44) to which the object (28) is aligned and the object (28) being directed by the optical system (6) onto the matrix detector (22 ),
characterized,
in that an outer housing (58) of the seeker head (4) rolls around a roll axis (38) relative to the surrounding object scene (30) and the matrix detector (22) rotates relative to the outer housing (58) and rolls with the roll frame (42). Method according to claim 7,
characterized,
in that the matrix detector (22) rests in space and the image on the matrix detector (22) rests with outer housing (58) rolling around the roll axis (38). Method according to claim 7 or 8,
characterized,
that cooling gas is sprayed from a housing-fixed cooler (62) of the seeker head (4) against a detector unit (20) which has the matrix detector (22) and rotates relative to the cooler (62) about the roll axis (38) and thus the matrix detector (22) is cooled. Method according to one of claims 7 to 9,
characterized,
in that a roll rate of the rolling frame (42) is detected by a rolling frame (70) fixed to the rolling frame and the roll rate is regulated to a desired roll value by means of the data of the roll sensor (70). Method according to one of claims 7 to 10,
characterized,
that a roll rate of the outer housing (58) is determined by means of an outer housing-fixed motion sensor (92), a roll drive (50) is controlled by means of the determined value, so that the rolling frame (42) is rotated relative to the outer housing (58) against its rolling direction of rotation remaining roll rate of the rolling frame (42) is detected by means of a roll frame fixed roller sensor (70) and the roll rate is controlled by the data of the roll sensor (70) to a desired roll value. Method according to claim 11,
characterized,
that when controlling the rolling rate to the desired roll value, a measurement error of the roll sensor (70) in the form of a drift by using the motion sensor (92) is at least partly recognized and taken into account. Method according to one of claims 10 to 12,
characterized,
in that, in addition to the roll rate of the rolling frame (42), a rolling movement is detected by means of the roll sensor (70), which is generated by tracking the object (28) with the input optics (10). Method according to claim 13,
characterized,
in that the rolling drive (50) is controlled in such a way that a rolling rate of the rolling frame (42) is regulated to the desired roll value by means of the rolling movement controlled to track the object (28) and the data of the roll sensor (70). Method according to one of claims 7 to 14,
characterized,
in that a rolling rate of the rolling frame (42) is regulated to a desired roll value by means of data obtained from an image of the object scene (30) on the matrix detector (22).

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