JP2013204990A - Missile - Google Patents

Abstract

PROBLEM TO BE SOLVED: To track a target more precisely, relating to a missile which is utilized for tracking a target.SOLUTION: A missile includes a missile head part 3 at which a flat upper-side surface 21 is formed, a dome 26 formed on an upper-side surface 21, a seeker 12 for detecting a sensor value based on a transmission electromagnetic wave penetrating the dome 26, and a guiding device for detecting a target direction at which a target is arranged based on the sensor value. At the missile head part 3, a lower side surface 22 which adjoins the upper-side surface 21 by way of a side edge 25 that follows a straight line is further formed. In such a missile, generation of a body rear surface eddy near the dome 26 is reduced because the upper-side surface 21 and the lower side surface 22 adjoin each other through a linear side edge 25 when it flies at a high speed. In such a missile, an amount of deviation is reduced with respect to a direction in which an electromagnetic wave radiated from a target thereof is propagated by the body rear surface eddy, and a target direction can be detected more precisely, so that tracking the target can take place more precisely.

Description

  The present invention relates to a flying object, and more particularly to a flying object used when tracking a target.

  Flying objects that track the target are known. The flying body is equipped with a control device, a light wave seeker, and a control device. The control device causes the flying object to fly and is controlled by the control device to change the course of the flying object. The light wave seeker creates an image of the target by photographing the target based on the light wave emitted from the target. The control device calculates a target direction in which the target is arranged with respect to the flying object based on the image, and controls the control device so that the flying object tracks the target.

  When such a flying body is flying, a fuselage rear vortex may be generated in the vicinity of the light wave seeker. The fuselage back vortex may refract the light wave emitted from the target and may cause optical path distortion in the optical path through which the light wave propagates. When such a flying object has a large degree of optical path distortion, the target orientation may not be calculated properly, and the flying object may not be properly guided. Such a flying body is desired to track the target more reliably and to measure the target direction with higher accuracy during the flight.

  Japanese Patent Application Laid-Open No. 04-60398 discloses a guided flying body that improves the tracking performance with respect to a target. The guided flying object is a guided flying object with two types of target tracking means, light wave and radio wave, with an optical window at the bottom of the dome of the guidance flying object guidance device, and a dome shape at the beginning of the flight. It is characterized in that a cover for keeping the machine body axis symmetrical is provided, and a clasp and a hinge for allowing the cover to be removed in accordance with a signal from the guidance device.

Japanese Patent Laid-Open No. 04-60398

An object of the present invention is to provide a flying body that tracks a target with higher accuracy.
Another object of the present invention is to provide a flying object for detecting a target orientation in which a target is arranged with higher accuracy.

  In the following, means for solving the problems will be described using the reference numerals used in the modes and examples for carrying out the invention in parentheses. This symbol is added to clarify the correspondence between the description of the claims and the description of the modes and embodiments for carrying out the invention. Do not use to interpret the technical scope.

  The flying body (1) according to the present invention includes a flying body head (3) (40), a dome (26) (46), a seeker (12), and a guidance device (14). The flying body heads (3) and (40) are formed with flat first protrusion-forming surfaces (21) and (41). The domes (26) and (46) are formed on the first protrusion forming surfaces (21) and (41). The seeker (12) detects the sensor value based on the transmitted electromagnetic waves transmitted through the domes (26) and (46). The guidance device (14) detects the target direction in which the target is arranged based on the sensor value. The flying body heads (3) and (40) are further provided with second projecting portion forming surfaces adjacent to the first projecting portion forming surfaces (21) and (41) via the edges (25) and (45) along the straight line. (22) (42) is further formed. In such a flying body (1), when flying at high speed, the first projecting portion forming surfaces (21) (41) and the second projecting portion forming surfaces (22) (42) are straight edges. (25) By adjoining via (45), generation | occurrence | production of a fuselage back surface vortex in the vicinity of the dome (26) (46) is reduced. In such a flying body (1), the direction in which the electromagnetic wave radiated from the target propagates is reduced from being distorted by the fuselage rear vortex, and the target orientation can be detected with higher accuracy. As a result, such a flying object (1) can track the target with higher accuracy by detecting the target orientation with high accuracy.

  The flying body heads (3) and (40) have first side surfaces (23) and (43) adjacent to the first projecting portion forming surfaces (21) and (41) and the second projecting portion forming surfaces (22) and (42). ) And a second side surface (24) adjacent to the first projecting portion forming surfaces (21) and (41) and the second projecting portion forming surfaces (22) and (42). The first side surfaces (23) and (43) are formed flat. The second side surface (24) is formed flat.

  The flying body (1) according to the present invention further includes another dome (47) formed on the second projecting portion forming surfaces (22) and (42). The seeker (12) further detects other sensor values based on other transmitted electromagnetic waves transmitted through the other dome (47). The guidance device (14) detects the target orientation based further on other sensor values.

  The seeker (12) creates an image of the target by photographing the target based on the transmitted electromagnetic wave. The guidance device (14) detects the target orientation based on the image.

  The flying object (1) according to the present invention has the dome cover (4) and the dome cover (4) so that the dome cover (4) covers the dome (26) (46). And a fixing device (16) for fixing to (40). The guidance device (14) is arranged so that the dome cover (4) separates from the flying body head (3) (40) while the flying body head (3) (40) is flying. The fixing device (16) is controlled.

  The flying object (1) according to the present invention further includes a control device (15) for changing the course of the flying object heads (3) and (40). The guidance device (14) controls the control device (15) based on the target direction so that the flying head (3) (40) tracks the target.

  The flying body (1) according to the present invention includes a flying body head (3) (40), a dome (26) (46), a seeker (12), and a guidance device (14). The flying body heads (3) and (40) are formed with flat protrusion-forming surfaces (21) and (41). The domes (26) and (46) are formed on the protruding portion forming surfaces (21) and (41). The seeker (12) detects the sensor value based on the transmitted electromagnetic waves transmitted through the domes (26) and (46). The guidance device (14) detects the target direction in which the target is arranged based on the sensor value. The flying body heads (3) and (40) are adjacent to the first side surfaces (23) and (43) adjacent to the protruding portion forming surfaces (21) and (41), and the protruding portion forming surfaces (21) and (41). A second side surface (24) is further formed. The first side surfaces (23) and (43) are formed flat. The second side surface (24) is formed flat. Such a flying body (1) has the first side surface (23) (43) and the second side surface (24) formed flat when flying at high speed, so that the dome (26) ( 46) Generation of a fuselage back vortex in the vicinity of 46) is reduced. In such a flying body (1), the direction in which the electromagnetic wave radiated from the target propagates is reduced from being distorted by the fuselage rear vortex, and the target orientation can be detected with higher accuracy. As a result, such a flying object (1) can track the target with higher accuracy by detecting the target orientation with high accuracy.

  The flying object according to the present invention can reduce the generation of vortices in the vicinity of the seeker, and can detect the target orientation in which the target is arranged with higher accuracy. As a result, the flying object according to the present invention can track the target with higher accuracy.

FIG. 1 is a side view showing the appearance of a flying object according to the present invention. FIG. 2 is a block diagram showing a flying object according to the present invention. FIG. 3 is a perspective view showing the head. FIG. 4 is a top view showing the head. FIG. 5 is a side view showing the head. FIG. 6 is a perspective view showing the head of the flying body of the comparative example. FIG. 7 is a perspective view showing the head of a flying body of another comparative example. FIG. 8 is a perspective view showing another head. FIG. 9 is a side view showing another head.

  Embodiments of a flying object according to the present invention will be described with reference to the drawings. The flying body includes a flying body body 1 as shown in FIG. The flying body body 1 includes a body part 2, a head part 3, and a dome cover 4, and is formed in a long shape in a direction parallel to the body axis 5. The trunk | drum 2 is formed from the predetermined | prescribed metal material, and is formed in the column shape. The body part 2 is further formed so that the axis of the cylinder overlaps the body axis 5. The head 3 is made of a predetermined metal material and is joined to the body 2. The dome cover 4 is formed of a predetermined metal material, and is formed in a so-called “ogive” shape with a sharp tip.

  The flying object according to the present invention further includes a propulsion device not shown. The propulsion device generates a propulsive force for the flying body 1 to fly. The flying body 1 further includes a main wing. The main wing is arranged on the outer side of the body part 2 of the flying body main body 1, and gives lift to the flying body main body 1 when the flying body main body 1 is flying. Furthermore, when the flying body 1 is flying in the traveling direction 7 so that the angle of attack 6 becomes a predetermined angle, a uniform flow flows in substantially parallel to the traveling direction 7. To do.

  As shown in FIG. 2, the flying object according to the present invention further includes an inertial measurement device 11, a light wave seeker 12, a guidance device 14, a steering device 15, and a fixing device 16. The inertial measurement device 11 is arranged inside the flying body main body 1 and is controlled by the guidance device 14 to measure acceleration at which the flying body main body 1 moves. The light wave seeker 12 is disposed inside the flying body main body 1 and controlled by the guidance device 14 to photograph a subject placed in front of the flying body main body 1 and create an image of the subject.

  When the flying body main body 1 is flying, the control device 15 is controlled by the guidance device 14 to change the traveling direction 7 in which the flying body main body 1 flies to a predetermined direction. The control device 15 includes, for example, a steering blade and a servo device. The steering wing is formed in an airfoil shape and is disposed outside the flying body main body 1. The steering wing is rotatably supported by the flying body 1. The servo device is controlled by the guidance device 14 to rotate the steering blade so that the traveling direction 7 is parallel to a predetermined direction.

  The fixing device 16 fixes the dome cover 4 to the head 3 so that the dome cover 4 covers a part of the head 3. The fixing device 16 further controls the dome cover 4 from the head 3 so that the entire head 3 is exposed by being controlled by the guidance device 14 when the flying body 1 is flying. Separate.

  The guidance device 14 is a computer, and includes a CPU, a storage device, and an interface not shown. The CPU controls the storage device and the interface by executing a computer program installed in the computer. The storage device records the computer program and temporarily records information created by the CPU. The interface outputs information generated by an external device connected to the computer to the CPU, and outputs information generated by the CPU to the external device. The external device includes an inertial measurement device 11, a light wave seeker 12, a steering device 15, and a fixing device 16.

  The guidance device 14 controls the inertial measurement device 11 so that a plurality of accelerations corresponding to a plurality of timings are measured while the flying body 1 is flying. The acceleration corresponding to a certain timing among the plurality of accelerations indicates the acceleration at which the flying body 1 moves at that timing. The guidance device 14 calculates the position, speed, and angle of attack based on the plurality of accelerations. The position indicates the position where the flying body 1 is flying. The speed indicates the speed at which the flying body 1 flies. The angle of attack indicates the angle of attack at which the flying body 1 flies.

  The guiding device 14 controls the fixing device 16 so that the dome cover 4 is separated from the head 3 while the flying body 1 is flying. After the dome cover 4 is separated from the head 3, the guidance device 14 controls the light wave seeker 12 so as to photograph a target and create an image of the target. The guidance device 14 calculates the target orientation based on the image created by the light wave seeker 12. Based on the calculated position, velocity, and angle of attack, the guidance device 14 tracks the target so that the traveling direction 7 is parallel to the detected target direction, that is, the flying body main body 1 tracks the target. Thus, the control device 15 is controlled.

  As shown in FIG. 3, the head 3 is formed with an upper side surface 21 and a lower side surface 22. The upper side surface 21 is formed flat and is formed so as to face the vertically upper side when the flying body 1 is flying in the horizontal direction. The upper side surface 21 is further formed so as to include the edge 25. The edge 25 is formed along a straight line. The edge 25 is arranged so as to be perpendicular to the body axis 5 and substantially perpendicular to the traveling direction 7 in which the flying body 1 flies. The lower side surface 22 is formed flat and is formed so as to face the vertically lower side when the flying body 1 is flying. The lower side surface 22 is further formed so as to include the edge 25. That is, the upper side surface 21 and the lower side surface 22 are adjacent to each other via the edge 25.

  As shown in FIG. 4, the head 3 is further formed with a left side surface 23 and a right side surface 24. The left side surface 23 is formed flat. The left side surface 23 is further formed so as to be along a plane perpendicular to the edge 25 and to be separated from the body axis 5 by a predetermined distance. The right side surface 24 is formed flat. The right side surface 24 is formed on the opposite side of the left side surface 23 and is formed so as to be along a plane perpendicular to the edge 25 and away from the body axis 5 by a distance from the body axis 5 to the left side surface 23. Has been. That is, the head 3 is formed so as to be symmetric with respect to a plane including the body axis 5 and perpendicular to the edge 25.

  The head 3 includes a dome 26. The dome 26 is formed in a flat plate shape. The dome 26 is arranged so that the plane along which the surface of the dome 26 extends and the plane along which the surface of the upper side surface 21 extends substantially coincide. Further, the dome 26 is configured such that infrared light emitted from a light source disposed in front of the flying body 1 is transmitted through the dome 26, and transmitted light transmitted through the dome 26 is applied to the light wave seeker 12. Is arranged.

  The dome cover 4 is arranged so that the dome cover 4 covers the dome 26 and the tip of the dome cover 4 overlaps the body axis 5 when being fixed to the head 3 by the fixing device 16. Yes.

  As shown in FIG. 5, the uniform body 31 flows into the flying body main body 1 when the flying body main body 1 is flying. When the dome cover 4 is separated from the head 3, the uniform flow 31 is because the edge 25 is along a straight line, or the left side surface 23 and the right side surface 24 are flat. The upper branch flow 32 and the lower branch flow 33 are generated in the vicinity of the edge 25. The upper branch flow 32 travels along the upper side surface 21. The lower branch flow 33 travels along the lower surface 22.

  The operation of guiding the flying body 1 so as to track the target is executed by the guidance device 14. The guidance device 14 controls the inertial measurement device 11 to measure the acceleration at which the flying body 1 moves at every predetermined sampling period. The guidance device 14 calculates the position, speed, and angle of attack based on the measured acceleration. The position indicates the position where the flying body 1 is flying. The speed indicates the speed at which the flying body 1 flies. The angle of attack indicates the angle of attack at which the flying body 1 flies.

  When the guide device 14 reaches a range sufficiently close to the target, the guide device 14 controls the fixing device 16 to separate the dome cover 4 from the head 3. After the dome cover 4 is separated from the head 3, the guiding device 14 controls the light wave seeker 12 to photograph the target and create an image showing the target. The guidance device 14 calculates a target orientation based on the image. The target azimuth is calculated based on the position where the target appears in the image, and indicates the direction in which the infrared rays emitted from the target are incident on the lightwave seeker 12. The guidance device 14 controls the flying device 15 so that the traveling direction 7 is parallel to the calculated target direction, that is, the flying body 1 tracks the target. The course of the main body 1 is changed.

  In the comparative example of the flying object according to the present invention, the head 3 in the above-described embodiment is replaced with another head. As shown in FIG. 6, the head 103 is formed in a so-called “ogive” shape with a sharp tip. The head 103 is further formed so that the tip thereof overlaps the fuselage shaft 105. The head 103 includes a dome 126. The dome 126 is formed in a flat plate shape. The dome 126 is arranged so that the infrared light emitted from the light source arranged in front of the flying object is transmitted through the dome 126 and the transmitted infrared light transmitted through the dome 126 is irradiated to the light wave seeker 112. Has been.

  The uniform flow 131 that flows into the flying body of the comparative example flows along the surface of the head 103. The uniform flow 131 further generates a fuselage back vortex 132 as it passes through the corner formed between the surface of the head 103 and the dome 126. Infrared rays radiated from a target placed in front of the flying body may be refracted by the fuselage rear vortex 132, and the fuselage rear vortex 132 may generate optical path distortion that distorts the path through which the infrared rays propagate. is there. That is, the direction in which the infrared rays are incident on the light wave seeker 112 may not be parallel to the direction in which the target is arranged with respect to the flying body when the optical path distortion occurs. For this reason, the flying object of such a comparative example may not be able to properly detect the target orientation when the optical path distortion occurs, and may not be able to properly track the target. is there.

  FIG. 7 shows another comparative example of the flying object according to the present invention. In the flying body of the comparative example, the head 3 in the above-described embodiment is further replaced with another head. The head 203 is made of a predetermined metal material and has a so-called “ogive” shape with a sharp tip. The head 203 is further formed so that the tip thereof overlaps the body shaft 205. The head 203 is formed with a first surface 221 and a second surface 222, and a recess is formed by forming the first surface 221 and the second surface 222. The first surface 221 is formed to be flat and to face the front of the flying body. The second surface 222 is formed so as to be flat, adjacent to the first surface 221, and along a plane parallel to the body axis 205.

  The head 203 includes a dome 226. The dome 226 is formed in a flat plate shape. The dome 226 is disposed so that the plane along which the surface of the dome 226 extends substantially coincides with the plane along which the surface of the first surface 221 extends. The dome 226 is further arranged so that the transmitted wave infrared transmitted through the dome 226 is irradiated to the light wave seeker 212.

  The uniform flow 231 flowing into the flying body of such a comparative example flows along the surface of the head 203. The uniform flow 231 generates a fuselage back vortex 232 as it passes through the corner formed by the surface of the head 203 and the second surface 222. The fuselage back vortex 232 may generate an optical path distortion that distorts a path through which infrared rays radiated from a target arranged in front of the flying body are propagated. For this reason, the flying object of such a comparative example may not be able to properly detect the target orientation when the optical path distortion occurs, and may not be able to properly track the target. is there.

  The flying object according to the present invention has the edge 25 along a straight line when the flying object body 1 flies, or the left side surface 23 and the right side surface 24 are flat, The uniform flow 31 is branched into an upper branch flow 32 and a lower branch flow 33, and the generation of a fuselage back vortex in the vicinity of the dome 26 is further reduced as compared with the comparative example. Can do. For this reason, the guidance device 14 can detect the target orientation with higher accuracy. As a result, such a flying object can track the target with higher accuracy by detecting the target orientation with high accuracy.

  The head 3 can be replaced with another head whose left side surface 23 and right side surface 24 are not formed flat. The head is formed in, for example, a shape obtained by cutting an augive shape along two planes along the upper side surface 21 and the lower side surface 22, respectively. The flying object to which such a lower surface is applied is similar to the flying object in the above-described embodiment because the edge 25 between the upper surface 21 and the lower surface 22 is along a straight line. Thus, the occurrence of a fuselage back vortex in the vicinity of the dome can be reduced, the target orientation can be detected with higher accuracy, and the target can be tracked with higher accuracy.

  The head 3 can be replaced with another lower surface in which the lower surface 22 is formed of a curved surface. That is, the lower side surface and the upper side surface 21 are adjacent to each other through a side formed from a curved line. The flying body to which such a lower surface is applied has a fuselage in the vicinity of the dome in the same manner as the flying body in the above-described embodiment because the left side surface 23 and the right side surface 24 are flat. The occurrence of back vortices can be reduced, the target orientation can be detected with higher accuracy, and the target can be tracked with higher accuracy.

  In another embodiment of the flying object according to the present invention, the head 3 in the above-described embodiment is replaced with another head. As shown in FIG. 8, the head 40 is formed with an upper side surface 41 and a lower side surface 42. The upper side surface 41 is formed flat and is formed so as to face vertically upward when the flying body is flying in the horizontal direction. The upper side surface 41 is further formed so as to include the edge 45. The edge 45 is formed along a straight line. The edge 45 is perpendicular to the body axis 5 and is arranged so as to be substantially perpendicular to the traveling direction 7 in which the flying body flies. The lower side surface 42 is formed so as to be flat and face the vertically lower side when the flying body is flying. The lower side surface 42 is further formed so as to include the edge 45. That is, the upper side surface 41 and the lower side surface 42 are adjacent to each other through the edge 45.

  The head 40 is further formed with a left side surface 43. The left side surface 43 is formed flat. The left side surface 43 is further formed so as to be along a plane perpendicular to the edge 45 and to be separated from the body axis 5 by a predetermined distance. The head 40 is formed to be symmetric with respect to a plane that includes the body axis 5 and is perpendicular to the edge 45. That is, the right side surface of the head 40 is further formed. The right side surface is formed flat. The right side surface is formed on the opposite side of the left side surface 43 and is formed so as to be along a plane perpendicular to the edge 45 and away from the body axis 5 by a distance from the body axis 5 to the left side surface 43. Has been.

  The head 40 includes an upper dome 46 and a lower dome 47. The upper dome 46 is formed in a flat plate shape. The upper dome 46 is arranged so that the plane along which the surface of the upper dome 46 extends and the plane along which the surface of the upper side surface 41 extends substantially coincide. The upper dome 46 further irradiates the light wave seeker 12 with the transmitted infrared light transmitted through the upper dome 46 so that the infrared light radiated from the light source disposed in front of the flying object is transmitted through the upper dome 46. It is arranged so that. The lower dome 47 is formed in a flat plate shape. The lower dome 47 is disposed so that the plane along which the surface of the lower dome 47 is aligned and the plane along which the surface of the upper side surface 41 is aligned. The lower dome 47 further transmits the infrared light emitted from the light source disposed in front of the flying body through the lower dome 47 and the transmitted infrared light transmitted through the lower dome 47 is the light wave seeker 12. It is arrange | positioned so that it may be irradiated.

  In such a flying body, when flying, a uniform flow 51 flows in as shown in FIG. When the dome cover 4 is separated from the head 40, the uniform flow 51 is caused by the fact that the edge 45 is along a straight line or the left side surface 43 and the right side surface thereof are flat. The upper branch flow 52 and the lower branch flow 53 are generated in the vicinity of the edge 45. The upper branch flow 52 travels along the upper side surface 41. The lower branch flow 53 travels along the lower side surface 42. For this reason, such a flying body can further reduce the occurrence of a fuselage rear vortex in the vicinity of the upper dome 46, and further reduce the occurrence of a fuselage rear vortex in the vicinity of the lower dome 47. be able to. Such a flying object can detect the target azimuth with higher accuracy in the same manner as the flying object in the above-described embodiment. As a result, such a flying object can track the target with higher accuracy by detecting the target orientation with high accuracy.

  The head 40 can be replaced with another head whose left side 43 and right side 44 are not formed flat. The head is formed in, for example, a shape obtained by cutting an augive shape along two planes along the upper side surface 41 and the lower side surface 42, respectively. The flying object to which such a lower surface is applied is similar to the flying object in the above-described embodiment because the edge 45 between the upper surface 41 and the lower surface 42 is along a straight line. Thus, the occurrence of a fuselage back vortex in the vicinity of the dome can be reduced, the target orientation can be detected with higher accuracy, and the target can be tracked with higher accuracy.

  The light wave seeker 12 can be replaced with another seeker that detects other electromagnetic waves different from infrared rays. An example of the seeker is a radio wave seeker that detects radio waves radiated from the target. The radio wave seeker includes a plurality of antennas, and detects a direction in which the target is arranged based on a plurality of times at which the radio waves are respectively received by the plurality of antennas. The radio wave may cause optical path distortion due to the fuselage rear vortex in the same manner as infrared rays. For this reason, a flying object to which such a radio wave seeker is applied can detect the target direction in which the target is arranged with higher accuracy in the same manner as the flying object in the above-described embodiment. The target can be tracked with higher accuracy.

  The guidance device 14 can also be formed from a plurality of hardware devices different from the CPU. The plurality of hardware devices respectively execute a plurality of processes executed by the guidance device 14. A flying object to which a plurality of hardware devices are applied has a higher target orientation in which the target is arranged with respect to the flying object in the same manner as the flying object in the above-described embodiment. It can be detected with high accuracy, and the target can be tracked with higher accuracy.

1: Flying body 2: Body part 3: Head part 4: Dome cover 5: Airframe axis 6: Angle of attack 7: Direction of travel 11: Inertial measuring device 12: Light wave seeker 14: Guide device 15: Steering device 16: Fixed Device 21: Upper side 22: Lower side 23: Left side 24: Right side 25: Edge 26: Dome 31: Uniform flow 32: Upper branch flow 33: Lower branch flow 40: Head 41: Upper side 42: Lower side 43: Left side 44: Right side 45: Edge 46: Upper dome 47: Lower dome 51: Uniform flow 52: Upper branch flow 53: Lower branch flow

Claims (7)

A flying body head on which a flat first projection forming surface is formed;
A dome formed on the first protrusion forming surface;
A seeker for detecting a sensor value based on the electromagnetic wave transmitted through the dome;
A guidance device that detects a target direction in which a target is arranged based on the sensor value;
The flying body head is further formed with a second projecting portion forming surface adjacent to the first projecting portion forming surface via an edge along a straight line. In claim 1,
The flying body head is
A first side surface adjacent to the first protrusion forming surface and the second protrusion forming surface;
A second side surface adjacent to the first protruding portion forming surface and the second protruding portion forming surface is further formed;
The first side surface is formed flat,
The second side surface is formed on the opposite side of the first side surface, and is formed flat. In any one of Claims 1-2,
Further comprising another dome formed on the second protrusion forming surface,
The seeker further detects other sensor values based on other transmitted electromagnetic waves transmitted through the other dome,
The guidance device detects the target azimuth based further on the other sensor values. In any one of Claims 1-3,
The seeker creates an image of the target by photographing the target based on the transmitted electromagnetic wave,
The guidance device detects the target azimuth based on the image. In any one of Claims 1-4,
A dome cover,
A fixing device for fixing the dome cover to the flying body head so that the dome cover covers the dome;
The guide device controls the fixing device so that the dome cover is separated from the flying body head while the flying body head is flying. In any one of Claims 1-5,
Further comprising a control device for changing the course of the flying body head,
The guidance device controls the control device based on the target direction so that the flying body head tracks the target. A flying body head on which a flat protrusion-forming surface is formed;
A dome formed on the protrusion forming surface;
A seeker for detecting a sensor value based on the electromagnetic wave transmitted through the dome;
A guidance device that detects a target direction in which a target is arranged based on the sensor value;
The flying body head is
A first side surface adjacent to the first protrusion forming surface;
A second side surface adjacent to the first protrusion forming surface is further formed;
The first side surface is formed flat,
The second side surface is formed on the opposite side of the first side surface, and is formed flat.

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