JP2008309445A - Artificial satellite defensive system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To defend an artificial satellite without breaking an airframe for antisatellite attack, and without causing space debris. <P>SOLUTION: In this artificial satellite defensive system, detection information on the airframe 40 for antisatellite attack heading for an artificial satellite 30 to defend is obtained, and the obtained detection information is transmitted to a control device 20 for controlling the artificial satellite 30. The control device 20 is provided with an emitting information transmitting means 24 for transmitting the emitting information for emitting a decoy generated based on the detection information to the artificial satellite 30, and the artificial satellite 30 is provided with a decoy emitting means 34 for emitting a decoy to deflect the airframe for antisatellite attack from the artificial satellite. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an artificial satellite defense system that defends an artificial satellite from a flying object for anti-satellite attack such as an anti-satellite missile.

As this type of artificial satellite defense system, it is destroyed by bombarding anti-satellite attacks such as anti-satellite missiles that fly toward the target satellite to be protected, or by irradiating them with lasers. There is a technical idea.
As an example, the satellite defense system described in Non-Patent Document 1, for example, places an ASAT weapon-intercepting satellite equipped with many small missiles around an important military satellite to be protected. It actively defends against satellite attack weapons such as artificial satellite missiles.
Edited by Takeshi Hondo, “Latest Defense Technology Taisei”, R & D Planning, Inc., February 11, 1985, p81-84

  However, since all defenses by bombarding anti-satellite missiles, etc. with kinetic energy bullets or intercepting them by laser irradiation involve destruction of anti-satellite missiles, etc. There is a risk of damaging the artificial satellite itself, other artificial satellites, spacecrafts, etc. that are trying to defend as debris.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an artificial satellite defense system that can protect an artificial satellite without destroying a flying object for anti-satellite attacks, and without generating space debris.

  To achieve the above object, the present invention obtains detection information of a flying object for anti-satellite attack toward an artificial satellite to be protected, and transmits the obtained detection information to a control device that controls the artificial satellite. A defense system, wherein the control device is provided with release information transmitting means for transmitting release information for releasing the decoy generated based on detection information to the artificial satellite, and is transmitted to the artificial satellite from the control device. The present invention is characterized in that a decoy emitting means for emitting a decoy for deflecting the flying object for anti-satellite attack from the artificial satellite based on the released information is provided.

  In addition, when the satellite has an accompanying satellite that flies with the satellite, the control device is provided with emission information transmitting means for transmitting emission information for emitting the decoy generated based on the detection information to the accompanying satellite. In addition, the accompanying satellite may be configured to be provided with decoy emitting means for emitting decoy for deflecting the flying object for anti-satellite attack from the artificial satellite based on the emission information transmitted from the control device.

  According to the present invention, since the detection information of the anti-satellite attack flying object flying toward the artificial satellite to be defended is acquired, the decoy is released by the emission information generated based on the acquired detection information. The anti-satellite attacking vehicle can be displaced from the artificial satellite, and the artificial satellite can be protected without destroying the anti-satellite attacking vehicle, so that space debris is not generated.

  The best mode for carrying out the present invention will be described below with reference to the drawings. FIG. 1 is a conceptual diagram of a satellite defense system according to a first embodiment of the present invention, FIG. 2 is a block diagram showing a schematic configuration of a control device and a satellite, and FIG. 3 is a perspective view showing an example of a decoy. It is.

The artificial satellite defense system A according to the first embodiment is configured to include a detection satellite 10, a control device 20, and an artificial satellite (hereinafter simply referred to as "artificial satellite") 30 to be protected.
The “artificial satellite” in the present embodiment includes various unmanned and manned spacecrafts.

  The detection satellite 10 is put in a predetermined orbit, and has a function of acquiring detection information of the anti-satellite attack flying object 40 flying toward the artificial satellite 30 and transmitting the acquired detection information to the control device 20. Have.

The control device 20 plays a role of controlling the artificial satellite 30 and is disposed in a control center K installed on the ground G in the present embodiment.
As shown in FIG. 2, the control device 20 includes a receiving device 22 that receives various information including detection information transmitted from the detection satellite 10 on the input side of the main control device 21. On the side, a transmission device 23 for transmitting various control information including release information for releasing the decoy 50 to the decoy release device 33, which will be described in detail later, is connected to the artificial satellite 30.

The main controller 21 has a function of generating the emission information based on the detection information of the anti-satellite attack vehicle 40.
The “release information” is obtained by analyzing the detection information, and includes a release instruction signal of the decoy 50, a release direction signal indicating a discharge direction, and the like. In addition, when a plurality of decoys 50 are mounted, a discharge number signal indicating the number of discharges, a discharge direction signal of each decoy, and the like are included.
In the present embodiment, the main control device 21 and the transmission device 23 constitute emission information transmission means 24 for transmitting emission information for releasing the decoy generated based on the detection information to the artificial satellite 30.

The artificial satellite 30 has a receiving device 32 for receiving various information including emission information transmitted from the control center K described above on the input side of the main control device 31, and an anti-satellite attack from the artificial satellite 30 on the output side. A decoy discharging device 33 for discharging a decoy 50 for deflecting the flying object 40 is connected.
1 and 2 show only one decoy 50, two or more decoys may be provided.

The decoy release device 33 is under the control of the main control device 31 and has a function of releasing the decoy 50 to the outside based on the release instruction signal and the release direction signal included in the release information.
As shown in FIG. 3, a decoy 50 is a pair of a decoy body 52 equipped with a exothermic gas discharge device 51 for emitting a heat generating gas that emits infrared rays, and a direction in which the decoy body 52 is rotated about an axis O. Gas discharge nozzles 53, 53 are provided.

  In the present embodiment, the decoy 50 for deflecting the flying object 40 against the satellite attack from the artificial satellite 30 based on the release information transmitted from the control device 20 by the main control device 31 and the decoy release device 33. The decoy discharge | release means 34 which discharge | releases is comprised.

The operation of the satellite defense system A having the above-described configuration is as follows.
When the detection satellite 10 detects that the anti-satellite attack vehicle 40 such as an anti-satellite missile is flying toward the artificial satellite 30, the detection information is transmitted to the control device 20. It should be noted that “the anti-satellite attack flying object 40 is flying toward the artificial satellite 30” includes that the anti-satellite attack flying object 40 is launched toward the artificial satellite 30.

The control device 20 receives the detection information transmitted from the detection satellite 10 and transmits the emission information generated based on the detection information to the artificial satellite 30.
When the artificial satellite 30 receives the emission information transmitted from the control device 20 described above, the artificial satellite 30 emits the decoy 50 based on various signals included in the emission information.

The exothermic gas is ejected from the gas discharge nozzles 53 of the discharged decoy 50, and the decoy 50 itself is rotated by the ejection of the exothermic gas.
That is, the decoy 50 rotates and releases the exothermic gas, thereby forming the exothermic gas cloud P between the anti-satellite attack vehicle 40 and the artificial satellite 30. This makes it possible to make the artificial satellite 30 indistinguishable even when an infrared seeker is mounted on the anti-satellite attack vehicle 40, thereby decoying the orbit of the anti-satellite attack vehicle 40. You can avoid hits by moving to the 50 side. Further, since the anti-satellite attack vehicle 40 is not destroyed, space debris is not generated.
The exothermic gas cloud P is considered to be effective even when an image seeker is mounted on the anti-satellite attack vehicle 40.

  Next, a satellite defense system according to a second embodiment of the present invention will be described with reference to FIG. 4 together with FIGS. FIG. 4 is a conceptual diagram of a satellite defense system according to the second embodiment of the present invention. Note that the detection satellite, the anti-satellite attack flying object, and the decoy are the same as those described in the first embodiment, and therefore, the same reference numerals are used and the description thereof is omitted.

  The satellite defense system B according to the second embodiment includes the detection satellite 10, the control device 60, the artificial satellite to be protected (hereinafter simply referred to as “artificial satellite”) 80, and the associated satellite 70. It is configured.

The control device 60 plays a role of controlling the artificial satellite 80 as described above, and is disposed in the control center K installed on the ground G in the present embodiment.
The control device 60 includes a receiving device 62 that receives various types of information including detection information transmitted from the detection satellite 10 on the input side of the main control device 61, and a decoy emission device described above on the output side. A transmission device 63 for transmitting various control information including release information for releasing the decoy 50 to the accompanying satellite 70 is connected.

The main control device 61 has a function of generating the emission information based on the detection information of the anti-satellite flying object 40.
The control device 60 shown in the present embodiment is different from the control device 20 described above in that the generated emission information is transmitted to the accompanying satellite 70.

  Unlike the artificial satellite 30 described in the first embodiment, the artificial satellite 80 is not provided with a decoy emitting means, and includes, for example, an already launched artificial satellite.

  The accompanying satellite 70 is flying in the vicinity of the artificial satellite 80 in the vicinity of the artificial satellite 80, and is transmitted from the control center K to the input side of the main controller 71. A receiving device 72 that receives various types of information including release information is connected to the output side, and the decoy discharging device 33 described above is connected to the output side.

By providing the accompanying satellite 70 with the decoy emitting device 33, for example, an existing artificial satellite 80 that does not have a function to be protected can be easily protected. Further, when the decoy 50 to be discharged is exhausted, the satellite 80 can be continuously protected by launching another accompanying satellite 70.
In the present embodiment, the main control device 71 and the decoy discharge device 33 provide a decoy 50 for deflecting the anti-satellite attack vehicle 40 from the artificial satellite 80 based on the release information transmitted from the control device 60. The decoy discharge | release means 73 to discharge | release is comprised.

The operation of the satellite defense system B having the above-described configuration is as follows.
When the detection satellite 10 detects that the anti-satellite attack vehicle 40 such as an anti-satellite missile is flying toward the artificial satellite 80, the detection information is transmitted to the control device 60.

The control device 60 receives the detection information transmitted from the detection satellite 10 and transmits the emission information generated based on the detection information to the associated satellite 70.
When the companion satellite 70 receives the emission information transmitted from the control device 60 described above, the accompanying satellite 70 emits the decoy 50 based on various signals included in the emission information.

The exothermic gas is ejected from the gas discharge nozzles 53 of the discharged decoy 50, and the decoy 50 itself is rotated by the ejection of the exothermic gas.
In other words, by releasing the exothermic gas while the decoy 50 rotates, a exothermic gas cloud (not shown) is formed between the anti-satellite attack vehicle 40 and the artificial satellite 80. This makes it possible to make the artificial satellite 80 indistinguishable even when an infrared seeker or an image seeker is mounted on the anti-satellite attack vehicle 40. The trajectory can be shifted to the decoy 50 side to avoid hits. Further, since the anti-satellite attack vehicle 40 is not destroyed, space debris is not generated.

The present invention is not limited to the above-described embodiments, and the following modifications can be made.
In each of the embodiments described above, the detection satellite has a function of detecting a flying object for anti-satellite attack toward the artificial satellite to be protected and transmitting this detection information to a control device that controls the artificial satellite. Although an example has been described, the present invention is not limited to this, and the radar apparatus 90 shown in FIGS. Further, both the detection satellite 10 and the radar device 90 may be used together.
Furthermore, the artificial satellite itself may be provided with a function of detecting a flying object for anti-satellite attack toward the artificial satellite to be protected.

  In the second embodiment described above, the example having one accompanying satellite has been described as an example. However, a configuration having two or more accompanying satellites may be used. In this case, the emission information transmitting means transmits the emission information generated based on the detection information for releasing the decoy to any or all of the accompanying satellites.

1 is a conceptual diagram of a satellite defense system according to a first embodiment of the present invention. It is a block diagram which shows schematic structure of a control apparatus and an artificial satellite. It is a perspective view which shows an example of a decoy. It is a conceptual diagram of the artificial satellite defense system which concerns on 2nd embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Detection satellite 20,60 Control apparatus 22,62 Emission information transmission apparatus 30,80 Artificial satellite 32,72 Decoy emission apparatus 40 Flying object 50 for satellite attack Decoy 51 Exothermic gas discharge apparatus 52 Decoy body 53 Gas discharge nozzle 70 Accompanying satellite 90 Radar equipment

Claims (4)

A satellite defense system that acquires detection information of a flying object for anti-satellite attack toward an artificial satellite to be protected, and transmits the acquired detection information to a control device that controls the artificial satellite,
The control device is provided with emission information transmitting means for transmitting the emission information for releasing the decoy generated based on the detection information to the artificial satellite,
The artificial satellite defense characterized in that the artificial satellite is provided with a decoy emitting means for emitting a decoy for deflecting the flying object for anti-satellite attack from the artificial satellite based on the emission information transmitted from the control device. system. A satellite defense system that acquires detection information of a flying object for anti-satellite attack toward an artificial satellite to be protected, and transmits it to a control device that controls the acquired artificial satellite,
It has an accompanying satellite that will fly along with the artificial satellite to be protected,
The control device is provided with emission information transmitting means for transmitting the emission information for releasing the decoy generated based on the detection information to the accompanying satellite,
A satellite defense system characterized in that the accompanying satellite is provided with a decoy emitting means for emitting a decoy for deflecting the flying object for anti-satellite attack from the artificial satellite based on the emission information transmitted from the control device. .   The artificial satellite defense system according to claim 1 or 2, wherein the decoy is equipped with a heat generation gas discharge device for discharging heat generation gas radiating infrared rays.   The artificial satellite according to claim 3, wherein the decoy is provided with one or a plurality of pairs of gas discharge nozzles in a direction in which the decoy body is rotated in the decoy body on which the exothermic gas discharge device is mounted. Defense system.

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