JP7446251B2 - Satellite constellation systems and satellite constellations - Google Patents

Description

The present disclosure relates to satellite constellations for monitoring flying objects and the like.

There are projectile countermeasure systems that are based on the assumption that projectiles fly in a ballistic trajectory.
The projectile countermeasure system detects the spray (plume) at the time of launch using an infrared observation device mounted on a geostationary orbit satellite, predicts the landing position based on movement information from the initial stage of the flight, and uses the countermeasure system to respond.
During launch, extremely hot gas spreads over a wide area. Therefore, it is possible to detect flying objects even when monitoring from a geostationary orbit.

However, recently, flying objects that intermittently eject and change their flight path during flight have appeared, posing a new threat.
In order to track a projectile that has stopped ejecting, it is necessary to detect the temperature of the projectile's body. Therefore, high-resolution and high-sensitivity infrared monitoring is required, which cannot be achieved with conventional monitoring using geostationary satellites.

Therefore, research has begun on a system that uses low-orbit satellite constellations to monitor flying objects from a much closer distance than in geostationary orbit.
There is also a long-awaited system for constant monitoring using a constellation of low-orbit satellites, and immediately transmitting information to response assets after a projectile launch is detected.
A low orbit satellite constellation is a satellite constellation consisting of a group of low orbit satellites.
A low orbit satellite constellation is one or more low orbit satellites.
A low orbit satellite is an artificial satellite that flies in a low orbit, such as LEO.
LEO is an abbreviation for Low Earth Orbit.

Patent Document 1 discloses a monitoring satellite that orbits in a low orbit and comprehensively monitors areas at specific latitudes within the entire spherical surface of the earth.

Patent No. 4946398

A huge number of low-orbit satellites are required to provide constant monitoring and maintain communication lines using a low-orbit satellite constellation.
In addition, unlike geostationary satellites that appear almost fixed relative to the earth-fixed coordinate system, low-orbit satellites change their flight position from time to time, so they require monitoring equipment equipped with infrared monitoring equipment and a configuration of communication satellite constellations. Therefore, the method of data transmission becomes an issue.

The present disclosure aims to enable constant monitoring of flying objects and the like.

The satellite constellation system of the present disclosure includes:
It includes a first satellite constellation and a second satellite constellation.
Each of the first satellite constellation and the second satellite constellation includes a plurality of artificial satellites whose number is a multiple of six,
The plurality of artificial satellites fly in an inclined orbit or a polar orbit.
The normal lines of the plurality of orbital planes corresponding to the plurality of artificial satellites are shifted by equal angles in the azimuth direction.
The plurality of raceway surfaces constitute one or more raceway surface sets consisting of six raceway surfaces.
The timing of the six artificial satellites orbiting on the six orbital planes of each orbital plane set is synchronized.
The timings at which the plurality of artificial satellites of the first satellite constellation and the plurality of artificial satellites of the second satellite constellation orbit are synchronized.

According to the present disclosure, it is possible to constantly monitor flying objects and the like.

1 is a configuration diagram of a satellite constellation system 100 in Embodiment 1. FIG. FIG. 2 is a configuration diagram of an artificial satellite 210 in Embodiment 1. FIG. 2 is a configuration diagram of an artificial satellite 220 in Embodiment 1. FIG. 4 is a configuration diagram of a flying object monitoring system 101 in Embodiment 4.

In the embodiments and drawings, the same or corresponding elements are denoted by the same reference numerals. Descriptions of elements assigned the same reference numerals as explained elements will be omitted or simplified as appropriate.

Embodiment 1.
The satellite constellation system 100 will be explained based on FIGS. 1 to 3.

***Explanation of configuration***
The configuration of satellite constellation system 100 will be explained based on FIG. 1.
Satellite constellation system 100 includes a satellite constellation 201, a satellite constellation 202, and ground equipment 110.

Satellite constellation 201 includes a plurality of artificial satellites 210. The number of artificial satellites 210 is a multiple of six.
The plurality of artificial satellites 210 fly in an inclined orbit or a polar orbit. For example, the orbit of each artificial satellite 210 is an inclined orbit, a polar orbit, and a circular orbit.
The normals of the plurality of orbital planes corresponding to the plurality of artificial satellites 210 are shifted by equal angles in the azimuth direction.
The plurality of raceway surfaces constitute one or more raceway surface sets consisting of six raceway surfaces.
The timings at which the six artificial satellites 210 orbit on the six orbital planes of each orbital plane set are synchronized.

Satellite constellation 202 includes a plurality of artificial satellites 220. The number of artificial satellites 220 is a multiple of six.
The plurality of artificial satellites 220 fly in an inclined orbit or a polar orbit. For example, the orbit of each artificial satellite 210 is an inclined orbit, a polar orbit, and a circular orbit.
The normals of the plurality of orbital planes corresponding to the plurality of artificial satellites 220 are shifted by equal angles in the azimuth direction.
The plurality of raceway surfaces constitute one or more raceway surface sets consisting of six raceway surfaces.
The timings at which the six artificial satellites 220 orbit on the six orbital planes of each orbital plane set are synchronized.

The orbiting timings of the plurality of artificial satellites 210 of the satellite constellation 201 and the plurality of artificial satellites 220 of the satellite constellation 202 are synchronized.

Satellite constellation 201 and satellite constellation 202 form a communication cross-link.
That is, the plurality of artificial satellites 210 of the satellite constellation 201 form a communication network and communicate among themselves. Further, the plurality of artificial satellites 220 of the satellite constellation 202 form a communication network, and the artificial satellites 220 communicate with each other. Further, the satellite constellation 201 and the satellite constellation 202 form a communication network, and the artificial satellites 210 and 220 communicate with each other.

The ground facility 110 includes a communication device 111 and a satellite control device 112, and controls each satellite constellation (201, 202) by communicating with each artificial satellite (210, 220). Specifically, the ground equipment 110 performs control to synchronize the plurality of artificial satellites 210 of the satellite constellation 201. Furthermore, the ground equipment 110 performs control for synchronizing the plurality of artificial satellites 210 of the satellite constellation 202. Furthermore, the ground equipment 110 performs control for synchronizing the plurality of artificial satellites 210 and the plurality of artificial satellites 220. Furthermore, the ground equipment 110 analyzes monitoring data obtained from each artificial satellite (210, 220) and generates information (for example, position information) on the monitoring target.
The satellite control device 112 is a computer that generates various commands and monitoring target information for controlling each artificial satellite (210, 220), and includes hardware such as a processing circuit and an input/output interface. The processing circuit generates various commands and monitoring target information. An input device and an output device are connected to the input/output interface. Satellite control device 112 is connected to communication device 111 via an input/output interface.
The communication device 111 communicates with each artificial satellite (210, 220). Specifically, the communication device 111 transmits various commands and monitoring target information to each artificial satellite (210, 220). The communication device 111 also receives monitoring data transmitted from each artificial satellite (210, 220).

The configuration of the artificial satellite 210 will be explained based on FIG. 2.
The artificial satellite 210 includes a communication device 211, a communication device 212, a monitoring device 213, a propulsion device 214, an attitude control device 215, a satellite control device 216, a power supply device 217, and an analysis device 218.

Communication device 211 is a communication device for communicating with ground equipment 110. For example, the communication device 211 receives various commands and monitoring target information from the ground equipment 110. Furthermore, the communication device 211 transmits monitoring data obtained by the monitoring device 213 to the ground equipment 110.

The communication device 212 is a communication device for inter-satellite communication. For example, the communication device 212 communicates monitoring data or monitoring target information with communication devices (212, 222) of other artificial satellites (210, 220).
For example, communication device 212 is an optical communication device. An optical communication device is a communication device that uses light waves.

The monitoring device 213 is a device for monitoring a monitoring target, and generates monitoring data. The monitoring data is data corresponding to an image of the monitored object.
For example, the monitoring device 213 is a monitoring device (first infrared monitoring device) that points toward the earth's center and uses infrared rays to detect the launch of a flying object.
A flying object is an example of a monitoring target, and after the injection at the time of launch ends, it glides while repeating intermittent injection.
For example, monitoring device 213 is a wide field of view monitoring device. A wide field of view monitoring device is a monitoring device that has a lower resolution than that of a high resolution monitoring device, but a wider field of view than the field of view of a high resolution monitoring device.
The satellite 210 may include one monitoring device 213 that is a first infrared monitoring device and a wide field monitoring device. Further, the artificial satellite 210 may include two monitoring devices 213, a monitoring device 213 that is a first infrared monitoring device and a monitoring device 213 that is a wide-field monitoring device.

The propulsion device 214 is a device that provides propulsion to the artificial satellite 210, and changes the speed of the artificial satellite 210. Specifically, propulsion device 214 is an electric propulsion device. For example, propulsion device 214 is an ion engine or a Hall thruster.

The attitude control device 215 is a device for controlling attitude factors such as the attitude of the artificial satellite 210 and the angular velocity of the artificial satellite 210.
The attitude control device 215 changes each attitude element in a desired direction. Alternatively, the attitude control device 215 maintains each attitude element in a desired direction. The attitude control device 215 includes an attitude sensor, an actuator, and a controller. Attitude sensors include gyroscopes, earth sensors, sun sensors, star trackers, thrusters and magnetic sensors. Actuators include attitude control thrusters, momentum wheels, reaction wheels, and control moment gyros. The controller controls the actuator according to the measurement data of the attitude sensor or various commands from the ground equipment 110.
The attitude control device 215 can be used as a device for changing the viewing direction of the monitoring device 213 (a viewing direction changing device).

The satellite control device 216 is a computer that controls each device of the artificial satellite 210, and includes a processing circuit. For example, the satellite control device 216 controls each device according to various commands transmitted from the ground equipment 110.

The power supply device 217 includes a solar cell, a battery, a power control device, and the like, and supplies power to each device of the artificial satellite 210.

The analysis device 218 is provided in the artificial satellite 210 when the artificial satellite 210 analyzes monitoring data to generate monitoring target information instead of the ground equipment 110.

The configuration of the artificial satellite 220 will be explained based on FIG. 3.
The artificial satellite 220 includes a communication device 221, a communication device 222, a monitoring device 223, a propulsion device 224, an attitude control device 225, a satellite control device 226, and a power supply device 227.
These devices correspond to the devices (211 to 217) of the artificial satellite 210.

However, the monitoring device 223 has the following characteristics.
For example, the monitoring device 223 is a monitoring device (second infrared monitoring device) that uses infrared rays to monitor the flying object after the ejection during launch is directed toward the edge of the earth and against the background of space.
For example, monitoring device 213 is a high resolution monitoring device. A high-resolution surveillance device is a surveillance device that has a field of view narrower than that of a wide-field surveillance device, but has a resolution higher than that of a wide-field surveillance device.
The satellite 220 may include one monitoring device 223 that is a second infrared monitoring device and a high resolution monitoring device. Further, the artificial satellite 220 may include two monitoring devices 223: a monitoring device 223 that is a second infrared monitoring device and a monitoring device 223 that is a high-resolution monitoring device.

The processing circuits provided in each of the satellite control device 112, the satellite control device 216, and the satellite control device 226 will be explained.
The processing circuit may be dedicated hardware or a processor that executes a program stored in memory.
In the processing circuit, some functions may be realized by dedicated hardware, and the remaining functions may be realized by software or firmware. That is, the processing circuit can be implemented in hardware, software, firmware, or a combination thereof.
The dedicated hardware is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC, an FPGA, or a combination thereof.
ASIC is an abbreviation for Application Specific Integrated Circuit.
FPGA is an abbreviation for Field Programmable Gate Array.

The pointing function of the artificial satellite 210 will be explained.
The artificial satellite 210 has a pointing function for directing the monitoring direction toward the monitoring target.
For example, satellite 210 includes a reaction wheel. The reaction wheel is a device for controlling the attitude of the artificial satellite 210. Body pointing is achieved by the reaction wheel controlling the attitude of the satellite 210.
For example, the satellite 210 includes a pointing mechanism. The pointing mechanism is a mechanism (viewing direction changing device) for changing the viewing direction of the monitoring device 213. For example, a driving mirror or the like is used as the pointing mechanism.
Like the artificial satellite 210, the artificial satellite 220 has a pointing function.

The adjustment of satellite altitude and orbital inclination will be explained.
The relative angle of the normal to the orbital plane of each artificial satellite (210, 220) when viewed from the north pole is determined by the correlation between the satellite altitude and the orbital inclination angle.
By finely adjusting the appropriate orbital inclination angle under altitude conditions that maintain the number of satellite orbits per day, it is possible to operate the satellite constellation (201, 202) while maintaining the relative angle between the orbital planes. .
Satellite control device 112 generates commands for controlling the altitude of each artificial satellite. Further, the satellite control device 112 generates a command for controlling the orbital inclination angle of each artificial satellite. The satellite control device 112 then transmits these commands to each artificial satellite.
In each artificial satellite (210, 220), the satellite controller (216, 226) adjusts each of the satellite altitude and orbit inclination according to these commands. Specifically, the satellite control device (216, 226) controls the propulsion device (214, 224) according to these commands. By changing the satellite speed, the propulsion devices (214, 224) can adjust the satellite altitude and orbital inclination.
When the flight speed of the artificial satellites (210, 220) increases, the altitude of the artificial satellites increases. As the satellite's altitude increases, its ground speed decreases.
When the flight speed of the artificial satellites (210, 220) decreases, the altitude of the artificial satellites decreases. As the altitude of the satellite decreases, the ground speed of the satellite increases.
If the propulsion device (214, 224) generates thrust in a direction perpendicular to the orbital plane at the point (equinox) where the satellite (210, 220) crosses the equator, the orbital inclination angle can be effectively fine-tuned. be able to.

Synchronization of multiple artificial satellites (210, 220) will be explained.
The plurality of satellites constitute one or more satellite sets. Each satellite set consists of six satellites.
A plurality of orbital planes corresponding to a plurality of artificial satellites constitute one or more orbital plane sets. Each raceway set consists of six raceways.
The timings at which the six artificial satellites 220 orbit on the six orbital planes of each orbital plane set are synchronized.

A first specific example of synchronization of a plurality of artificial satellites (210, 220) will be described.
In each orbital plane set, the m-th artificial satellite is called an artificial satellite (m). Further, the orbit of the m-th artificial satellite is referred to as orbit (m).
The timing at which the artificial satellite (1) passes the northernmost point of the orbital plane (1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (3) passes a point where the in-plane phase is shifted by +120 degrees from the northernmost end of the orbital plane (3).
Timing (5) is the timing when the artificial satellite (5) passes a point where the in-plane phase is shifted by +240 degrees from the northernmost end of the orbital plane (5).
In-plane phase means phase within the orbital plane.
The positive direction in the in-plane phase is the direction opposite to the direction in which the satellite is traveling. In other words, the negative direction in the in-plane phase is the same direction as the advancing direction of the artificial satellite.
Timing (1) is also synchronized with the following timings (4), (6), and (2).
Timing (4) is the timing when the artificial satellite (4) passes the southernmost point of the orbital plane (4).
Timing (6) is the timing when the artificial satellite (6) passes a point where the in-plane phase is shifted by +120 degrees from the southernmost end of the orbital plane (6).
Timing (2) is the timing when the artificial satellite (2) passes a point where the in-plane phase is shifted by +240 degrees from the southernmost end of the orbital plane (2).

A second specific example of synchronization of a plurality of satellites (210, 220) will be described.
The x-th artificial satellite in the (n+1)th artificial satellite set is referred to as artificial satellite (6n+x). "n" is 1, and "x" is an integer of 1 or more and 6 or less.
The x-th raceway surface in the (n+1)th raceway surface set is referred to as a raceway surface (6n+x).
The orbital period of each artificial satellite is represented by "T".
The timing at which the artificial satellite (6n+1) passes through the orbital plane (6n+1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (6n+3) passes a point where the in-plane phase is shifted by +120 degrees from the northernmost end of the orbital plane (6n+3).
Timing (5) is the timing when the artificial satellite (6n+5) passes a point where the in-plane phase is shifted by +240 degrees from the northernmost end of the orbital plane (6n+5).
The timing at which the artificial satellite (6n+4) passes through each in-plane phase point in the orbital plane (6n+4) is referred to as timing (4).
Timing (4) is synchronized with timings (6) and (2) below.
Timing (6) is the timing when the artificial satellite (6n+6) passes a point in the orbit plane (6n+6) whose in-plane phase is shifted by +120 degrees from a point corresponding to the in-plane phase of the artificial satellite (6n+4).
Timing (2) is the timing when the artificial satellite (6n+2) passes a point in the orbit plane (6n+2) whose in-plane phase is shifted by +240 degrees from a point corresponding to the in-plane phase of the artificial satellite (6n+4).
Further, the artificial satellite (6n+4) passes the northernmost point of the orbital plane (6n+4) at a timing when T/2 has elapsed after the artificial satellite (6n+1) passes the northernmost point of the orbital plane (6n+1).

A third specific example will be described regarding synchronization of a plurality of artificial satellites (210, 220).
The timing at which the artificial satellite (6n+1) passes through the orbital plane (6n+1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (6n+3) passes a point where the in-plane phase is shifted by +120 degrees from the northernmost end of the orbital plane (6n+3).
Timing (5) is the timing when the artificial satellite (6n+5) passes a point where the in-plane phase is shifted by +240 degrees from the northernmost end of the orbital plane (6n+5).
Timing (1) is also synchronized with the following timings (4), (6), and (2).
Timing (4) is the timing when the artificial satellite (6n+4) passes the southernmost point of the orbital plane (6n+4).
Timing (6) is the timing when the artificial satellite (6n+6) passes a point where the in-plane phase is shifted by +120 degrees from the southernmost end of the orbital plane (6n+6).
Timing (2) is the timing when the artificial satellite (6n+2) passes a point where the in-plane phase is shifted by +240 degrees from the southernmost end of the orbital plane (6n+2).

A fourth specific example will be described regarding synchronization of a plurality of artificial satellites (210, 220).
The timing at which the artificial satellite (1) passes the northernmost point of the orbital plane (1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (3) passes through a point where the in-plane phase is shifted by -120 degrees from the northernmost end of the orbital plane (3).
Timing (5) is the timing when the artificial satellite (5) passes through a point where the in-plane phase is shifted by -240 degrees from the northernmost end of the orbital plane (5).
Timing (1) is also synchronized with the following timings (4), (6), and (2).
Timing (4) is the timing when the artificial satellite (4) passes the southernmost point of the orbital plane (4).
Timing (6) is the timing when the artificial satellite (6) passes through a point where the in-plane phase is shifted by -120 degrees from the southernmost end of the orbital plane (6).
Timing (2) is the timing when the artificial satellite (2) passes through a point whose in-plane phase is shifted by -240 degrees from the southernmost end of the orbital plane (2).

A fifth specific example will be described regarding synchronization of a plurality of artificial satellites (210, 220).
The timing at which the artificial satellite (6n+1) passes through the orbital plane (6n+1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (6n+3) passes a point where the in-plane phase is shifted by -120 degrees from the northernmost end of the orbital plane (6n+3).
Timing (5) is the timing when the artificial satellite (6n+5) passes a point where the in-plane phase is shifted by -240 degrees from the northernmost point of the orbital plane (6n+5).
The timing at which the artificial satellite (6n+4) passes through each in-plane phase point in the orbital plane (6n+4) is referred to as timing (4).
Timing (4) is synchronized with timings (6) and (2) below.
Timing (6) is the timing when the artificial satellite (6n+6) passes a point in the orbital plane (6n+6) whose in-plane phase is shifted by -120 degrees from a point corresponding to the in-plane phase of the artificial satellite (6n+4).
Timing (2) is the timing when the artificial satellite (6n+2) passes a point in the orbital plane (6n+2) whose in-plane phase is shifted by -240 degrees from a point corresponding to the in-plane phase of the artificial satellite (6n+4).
Further, the artificial satellite (6n+4) passes the northernmost point of the orbital plane (6n+4) at a timing when T/2 has elapsed after the artificial satellite (6n+1) passes the northernmost point of the orbital plane (6n+1).

A sixth specific example of synchronization of a plurality of satellites (210, 220) will be described.
The timing at which the artificial satellite (6n+1) passes through the orbital plane (6n+1) is referred to as timing (1).
Timing (1) is synchronized with timings (3) and (5) below.
Timing (3) is the timing when the artificial satellite (6n+3) passes a point where the in-plane phase is shifted by -120 degrees from the northernmost end of the orbital plane (6n+3).
Timing (5) is the timing when the artificial satellite (6n+5) passes a point where the in-plane phase is shifted by -240 degrees from the northernmost point of the orbital plane (6n+5).
Timing (1) is also synchronized with the following timings (4), (6), and (2).
Timing (4) is the timing when the artificial satellite (6n+4) passes the southernmost point of the orbital plane (6n+4).
Timing (6) is the timing when the artificial satellite (6n+6) passes a point where the in-plane phase is shifted by -120 degrees from the southernmost end of the orbital plane (6n+6).
Timing (2) is the timing when the artificial satellite (6n+2) passes a point where the in-plane phase is shifted by -240 degrees from the southernmost end of the orbital plane (6n+2).

***Features and effects of Embodiment 1***
In the first satellite constellation (201), an appropriate viewing range and an appropriate number of artificial satellites (210) are used depending on the orbital inclination angle and the orbital altitude. Furthermore, each artificial satellite is equipped with a monitoring device (213) and a communication device (212), and the monitoring device is oriented toward the geocenter. This enables constant monitoring and constant communication in mid-latitude zones.
By synchronously controlling the first satellite constellation (201) and the second satellite constellation (202), constant monitoring of the mid-latitude zone is realized, and two or more satellites simultaneously monitor any point in the mid-latitude zone. It can be monitored by satellite. Then, based on the principle of aerial triangulation, the position coordinates of the monitored object can be derived.
Furthermore, since the gap between the monitorable range at the north and south ends of the monitoring range is filled, the monitoring range is expanded in the latitude direction.
Furthermore, since gaps in the monitorable range that rarely occur in low latitude zones near the equator are filled, all of the low latitude zones can be monitored.
Furthermore, when the object to be monitored is a plurality of flying objects that pose a threat to maintaining safety, even if the plurality of flying objects are launched at the same time, it becomes possible to monitor all the flying objects at the same time.

The features and effects when the monitoring device 213 is the first infrared monitoring device in the satellite constellation 201 and the monitoring device 223 is the second infrared monitoring device in the satellite constellation 202 will be described.
By synchronously controlling the satellite constellations (201, 202), it is possible to constantly monitor the mid-latitude zone using the first infrared monitoring device oriented toward the geocenter on a minimum of 12 orbital planes. can. If the object to be monitored is a flying object, the launch of the flying object can be detected.
When a projectile is launched, a high-temperature spray called a plume is ejected by the propulsion device. Since the plume has a high temperature and a wide diffusion range, the plume can be detected by the first infrared monitoring device oriented toward the earth's center.
On the other hand, flying objects that have appeared in recent years change their flight path by intermittently ejecting during flight after the ejection during launch has ended. Therefore, in order to predict the flight path and landing position, it is necessary to monitor and track the body of the flying object, which has risen in temperature. However, in monitoring by the first infrared monitoring device oriented toward the earth's center, the flying object information is buried in background noise.
Therefore, the second infrared monitoring device performs rim observation. Rim observation allows flying objects to be monitored in the deep space background, making it possible to track and monitor flying objects without burying information about the flying object in background noise.
In other words, the first satellite constellation (201) detects the launch of a flying object, and the second satellite constellation (202) detects the main body of the flying object in the deep space background after the injection is completed, thereby tracking and monitoring the flying object. becomes possible.

The features and effects will be described when the monitoring device 213 in the satellite constellation 201 is a wide-field monitoring device and the monitoring device 223 in the satellite constellation 202 is a high-resolution monitoring device.
The first satellite constellation (201) equipped with a wide-field monitoring device makes it possible to comprehensively monitor the mid-latitude zone and detect the launch of a flying object.
After the injection during launch ends, the temperature of the projectile body is not as high as that of the plume. Also, the dimensions of the projectile body are much smaller than the diffused size of the plume. However, a second satellite constellation (202) equipped with high-resolution monitoring equipment allows continued monitoring of the spacecraft.
In general, there are technical and cost constraints in increasing the resolution of wide-field monitoring devices. Therefore, a high-resolution monitoring device will be prepared separately. However, it is generally difficult to widen the monitoring range of a high-resolution monitoring device. Therefore, a high-resolution monitoring device for a narrow area is used. The second satellite constellation cannot comprehensively monitor the mid-latitude zone at once. However, by changing the viewing direction, a high-resolution monitoring device for a narrow area can monitor any point in the mid-latitude zone. Therefore, by directing the field of view of the second satellite constellation toward the flying object detected by the first satellite constellation, it becomes possible to monitor the flying object with high resolution.

The characteristics and effects of the communication cross-link between satellite constellation 201 and satellite constellation 202 will be explained.
The second satellite constellation (202) can continuously monitor the targets discovered by the first satellite constellation (201). Furthermore, the second satellite constellation can obtain detailed information with high resolution.
For example, after the first artificial satellite (210) of the first satellite constellation detects the launch of a flying object, the first artificial satellite flies to the second artificial satellite (220) flying behind in the second satellite constellation. body information is transmitted via communication cross-links. Thereby, the second artificial satellite can monitor the flying object while tracking it with high resolution by changing the viewing direction to the vicinity of the launch point.

The characteristics and effects when the communication devices (212, 222) of each artificial satellite (210, 220) are optical communication devices will be explained.
By using optical communication devices, large amounts of information can be transmitted in a short time. The arrival of flying objects is an emergency situation that poses a threat to maintaining safety. However, the optical communication device has the advantage of being able to transmit information about flying objects in a short time, making it possible to take countermeasures.

Embodiment 2.
Regarding satellite constellation system 100, mainly the differences from Embodiment 1 will be explained.

***Explanation of configuration***
The configuration of satellite constellation system 100 is the same as the configuration in the first embodiment.
However, the satellite constellation system 100 may include two or more satellite constellations 201 or may include two or more satellite constellations 202.

***Features and effects of Embodiment 2***
The second embodiment has the same features as the first embodiment, and the second embodiment provides the same effects as the first embodiment.
In particular, the second embodiment has the advantage of being able to cope with the case where a plurality of flying objects are launched at the same time.
Furthermore, the second embodiment has the following features and effects. After the first artificial satellite (210) of the first satellite constellation detects the launch of a flying object, the first artificial satellite sends the flying object information to a second artificial satellite (220) flying behind in the second satellite constellation. is transmitted by communication cross-links. Thereby, the second artificial satellite can monitor the flying object while tracking it with high resolution by changing the viewing direction to the vicinity of the launch point. Further, the second artificial satellite transmits tracking information of the flying object tracked with high resolution to a third artificial satellite flying behind in the third satellite constellation via a communication cross link. Thereby, the third artificial satellite can track a flying object that moves over time with high resolution.

Embodiment 3.
Regarding satellite constellation system 100, differences from Embodiment 1 and Embodiment 2 will mainly be described.

***Explanation of configuration***
Satellite constellation system 100 includes a plurality of satellite constellations including satellite constellation 201 and satellite constellation 202. Satellite constellation system 100 may include two or more satellite constellations 201 or may include two or more satellite constellations 202.
Each satellite constellation (201, 202) comprises multiple satellites (210, 220).
However, the number of artificial satellites included in one satellite constellation is six or more, and may or may not be a multiple of six.

***Features and effects of Embodiment 3***
Embodiment 3 has the same features as Embodiment 1 and Embodiment 2, and Embodiment 3 produces similar effects.

Furthermore, the third embodiment has the following features and effects.
The six or more satellites in each satellite constellation operate synchronously with overlapping service areas. Therefore, in the event of a failure in any of the satellite constellations, backup can be provided by the satellite constellations that are not in failure. Additionally, services that require two or more satellites to target the same target at the same time, such as measuring position coordinates through spatial triangulation, will become possible.
Furthermore, when monitoring flying objects using a monitoring device, it is possible to cope with the simultaneous launch of a plurality of flying objects.
The six or more satellites in each satellite constellation operate synchronously in the same orbital plane and with even phases. This increases the frequency of revisiting the same orbital plane.
Six or more artificial satellites in each satellite constellation operate synchronously in orbits spaced at equal intervals in the longitude direction. This allows each satellite constellation to alternately continue monitoring and communication services to specific areas of the earth's surface in response to changes in longitude and latitude as the earth rotates.
The six or more artificial satellites in each satellite constellation are operated synchronously on orbital planes that are offset at equal intervals in the longitudinal direction, and are operated synchronously with the phases within the orbital plane offset at equal intervals. This allows each satellite constellation to alternately continue monitoring and communication services to specific points on the earth's surface in response to changes in longitude and latitude as the earth rotates.

Embodiment 4.
Regarding the flying object monitoring system 101, mainly the differences from the first to third embodiments will be explained based on FIG. 4.

***Explanation of configuration***
The configuration of the flying object monitoring system 101 will be explained based on FIG. 4. The flying object monitoring system 101 is a type of satellite constellation system 100.
The flying object monitoring system 101 includes a satellite constellation group 203, a satellite constellation group 204, and ground equipment 110.
Satellite constellation group 203 is one or more satellite constellations that include satellite constellation 201. Specifically, satellite constellation group 203 is one or more satellite constellations 201.
Satellite constellation group 204 is one or more satellite constellations that include satellite constellation 202. Specifically, satellite constellation group 204 is one or more satellite constellations 202.
Satellite constellation 201 and satellite constellation 202 are as described in Embodiments 1 to 3.

***Features and effects of Embodiment 4***
The fourth embodiment has the same features as the first to third embodiments, and the fourth embodiment provides the same effects as the first to third embodiments.
In particular, the fourth embodiment has the following features and effects.

The features and effects when the monitoring device 213 is the first infrared monitoring device in the satellite constellation 201 and the monitoring device 223 is the second infrared monitoring device in the satellite constellation 202 will be described.
The first satellite constellation (201) equipped with the first infrared monitoring device detects the launch of the flying object while the flying object is gliding while repeatedly ejecting intermittently after the injection at the time of launch ends. be able to. Furthermore, the first satellite constellation may transmit the projectile information to a second satellite constellation (202) comprising a second infrared monitoring device. The second satellite constellation can then track the projectile.
If the propulsion device of the projectile ejects again and the flight direction and flight speed of the projectile change, the first satellite constellation can detect the re-ejection. Further, the first satellite constellation can transmit the vehicle information to the second satellite constellation. The second satellite constellation can then track the projectile.

The features and effects will be described when the monitoring device 213 in the satellite constellation 201 is a wide-field monitoring device and the monitoring device 223 in the satellite constellation 202 is a high-resolution monitoring device.
Even if the second infrared monitoring device is a high-resolution monitoring device with a narrow field of view, the monitoring target can be tracked without omission by changing the field of view direction.
For example, suppose that a high-temperature object is detected in an emergency situation such as a fire or an explosion, and then the high-temperature object is monitored in detail with high resolution to respond to the emergency situation. In this case, a high-temperature object discovered by the first satellite constellation (201) equipped with a wide-area monitoring device is quickly and comprehensively monitored with high resolution by the high-resolution monitoring device of the second satellite constellation (202). Can be done. Furthermore, by continuing high-resolution monitoring by subsequent satellites, it will be possible to quickly grasp disaster situations that are dependent on time, such as the spread of fire.

＊＊＊Supplementary information regarding the implementation form＊＊＊
The satellite constellation system 100 can be used as a satellite information transmission system that detects the launch of a flying object and transmits the flying object information to a countermeasure system in near real time.
Satellite constellation system 100 includes a group of monitoring satellites equipped with infrared monitoring equipment. The satellite constellation system 100 includes a group of communication satellites forming a mesh-like communication network.
The term "near real-time" is used to take into account the time delay contributing to information transmission and the waiting time until the satellite sends and receives information at the fastest timing.

When a projectile is launched, the high-temperature atmosphere diffuses, making it easier to monitor. However, in the post-boost phase, the body of the projectile has a small solid angle visible to monitoring satellites, and the temperature rise is not as pronounced as in the plume. Therefore, if background land area information is mixed with the flying object information, there is a concern that the flying object may not be identified. The post-boost phase is the phase after injection has stopped.
Therefore, a monitoring method called rim observation that aims at the Earth's periphery will be used to monitor the body of the flying object, which has risen in temperature, against the background of deep space.
This makes it possible to monitor flying objects without the flying object information being buried in noise.

The satellite control device 112 or the analysis device 218 functions as a flight path prediction device that integrates flying object information indicating high-temperature objects detected by a plurality of monitoring satellites (210, 220) and analyzes changes in position information over time. Function. This makes it possible to track the flying object and predict its flight path.
Even if a flying object intermittently re-injects and changes direction during flight, the flight path prediction device tracks the traveling direction and continuously acquires time-series information, making it possible to take action against the flying object. It becomes possible.

Response assets include aircraft, ships, and vehicles deployed on land, sea, and air. In addition, there are also ground-mounted equipment.
There is also a means to directly transmit information to individual coping assets. However, due to security restrictions, it may not be possible to disclose the location information of individual assets. Therefore, when the satellite information transmission system uses a special dedicated system, commands to response assets and flying object information are aggregated to a response ground center (a type of ground equipment 110), and commands to response assets are executed from the response ground center. It is reasonable to do so.
The method of operating a satellite information transmission system varies depending on the configuration and operation method of the entire system.

Each embodiment is an illustration of a preferred form and is not intended to limit the technical scope of the present disclosure. Each embodiment may be implemented partially or in combination with other embodiments.

100 satellite constellation system, 101 flying object monitoring system, 110 ground equipment, 111 communication device, 112 satellite control device, 201 satellite constellation, 203 satellite constellation group, 204 satellite constellation group, 210 artificial satellite, 211 communication device, 212 communication device, 213 monitoring device, 214 propulsion device, 215 attitude control device, 216 satellite control device, 217 power supply device, 218 analysis device, 220 artificial satellite, 221 first communication device, 222 second communication device, 223 monitoring device, 224 propulsion device, 225 attitude control device, 226 satellite control device, 227 power supply device.

Claims (21)

A satellite constellation system that constantly monitors the launch of projectiles that change flight paths by intermittently ejecting them during flight over a wide area from low to mid-latitudes, and transmits information to response assets when a projectile launch is detected. ration system,
a first satellite constellation and a second satellite constellation; each of the first satellite constellation and the second satellite constellation includes a plurality of artificial satellites whose number is a multiple of six;
The plurality of artificial satellites fly in a low inclined orbit or a polar orbit,
The plurality of orbital planes corresponding to the plurality of artificial satellites have mutual normals shifted by equal angles in an azimuth direction,
The plurality of raceway surfaces constitute one or more raceway surface sets consisting of six raceway surfaces,
The timing of the six satellites orbiting on the six orbital planes of each orbital plane set is synchronized,
The orbit timings of the plurality of artificial satellites of the first satellite constellation and the plurality of artificial satellites of the second satellite constellation are synchronized ,
the first satellite constellation and the second satellite constellation form a communication cross-link;
the satellite of the first satellite constellation transmits flight object information to the satellite of the second satellite constellation via the communication cross-link after detecting the launch of the projectile;
The satellite of the second satellite constellation tracks and monitors the heated flying object in a deep space background.
Satellite constellation system. Each satellite of the first satellite constellation is:
Equipped with a first infrared monitoring device that detects the launch of projectiles pointing toward the earth's center,
Each satellite of the second satellite constellation is
The satellite constellation system according to claim 1, further comprising a second infrared monitoring device that monitors the flying object with space as a background, pointing toward the circumference of the earth. Each satellite of the first satellite constellation is equipped with a wide field of view monitoring device;
Each artificial satellite of the second satellite constellation includes a high-resolution monitoring device and a viewing direction changing device for changing the viewing direction of the high-resolution monitoring device,
The wide-field monitoring device is a monitoring device that has a resolution lower than that of the high-resolution monitoring device but has a wider field of view than the field of view of the high-resolution monitoring device,
The satellite according to claim 1 or 2, wherein the high-resolution monitoring device is a monitoring device that has a field of view narrower than that of the wide-field monitoring device but has a resolution higher than that of the wide-field monitoring device. constellation system. Each artificial satellite of the first satellite constellation and each artificial satellite of the second satellite constellation includes a communication device,
A satellite constellation system according to any one of claims 1 to 3, wherein the first satellite constellation and the second satellite constellation form a communication cross-link. The satellite constellation system according to claim 4, wherein the communication device is an optical communication device. a first satellite constellation group including the first satellite constellation;
a second satellite constellation group including the second satellite constellation;
Equipped with
Each artificial satellite of the first satellite constellation group includes a first infrared monitoring device and a communication device,
Each artificial satellite of the second satellite constellation group includes a second infrared monitoring device and a communication device,
The first infrared monitoring device is a monitoring device that uses infrared rays to detect the launch of a flying object that glides while repeating intermittent injection after the end of the injection at the time of launch, pointing toward the earth's center,
The second infrared monitoring device is a monitoring device that uses infrared rays to monitor the flying object after the injection at the time of launch has ended, with the space as a background, pointing toward the circumference of the earth,
The satellite constellation system of claim 1, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. a first satellite constellation group including the first satellite constellation;
a second satellite constellation group including the second satellite constellation;
Equipped with
Each satellite of the first satellite constellation group includes a wide-field monitoring device and a communication device,
Each satellite of the second satellite constellation group includes a high-resolution monitoring device, a viewing direction changing device, and a communication device,
The viewing direction changing device is a device for changing the viewing direction of the high resolution monitoring device,
The wide-field monitoring device is a monitoring device that has a resolution lower than that of the high-resolution monitoring device but has a wider field of view than the field of view of the high-resolution monitoring device,
The high-resolution monitoring device is a monitoring device that has a field of view narrower than the field of view of the wide-field monitoring device, but has a resolution higher than the resolution of the wide-field monitoring device,
The satellite constellation system of claim 1, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. A satellite constellation that is a first satellite constellation included in the satellite constellation system according to any one of claims 1 to 7. A satellite constellation that is a second satellite constellation included in the satellite constellation system according to any one of claims 1 to 7. comprising a plurality of satellite constellations including the first satellite constellation and the second satellite constellation ,
In the plurality of satellite constellations, the timings at which the plurality of artificial satellites orbit each other are synchronized.
A satellite constellation system according to claim 1 . Each satellite of the plurality of satellite constellations includes a communication device,
11. The satellite constellation system of claim 10, wherein the plurality of satellite constellations form a communication cross-link. The satellite constellation system according to claim 11, wherein the communication device is an optical communication device. The plurality of satellite constellations include a first satellite constellation group and a second satellite constellation group,
Each artificial satellite of the first satellite constellation group includes a first infrared monitoring device and a communication device,
Each artificial satellite of the second satellite constellation group includes a second infrared monitoring device and a communication device,
The first infrared monitoring device is a monitoring device that uses infrared rays to detect the launch of a flying object that glides while repeating intermittent injection after the end of the injection at the time of launch, pointing toward the earth's center,
The second infrared monitoring device is a monitoring device that uses infrared rays to monitor the flying object after the injection at the time of launch has ended, with the space as a background, pointing toward the circumference of the earth,
11. The satellite constellation system of claim 10, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. The plurality of satellite constellations include a first satellite constellation group and a second satellite constellation group,
Each satellite of the first satellite constellation group includes a wide-field monitoring device and a communication device,
Each satellite of the second satellite constellation group includes a high-resolution monitoring device, a viewing direction changing device, and a communication device,
The viewing direction changing device is a device for changing the viewing direction of the high resolution monitoring device,
The wide-field monitoring device is a monitoring device that has a resolution lower than that of the high-resolution monitoring device but has a wider field of view than the field of view of the high-resolution monitoring device,
The high-resolution monitoring device is a monitoring device that has a field of view narrower than the field of view of the wide-field monitoring device, but has a resolution higher than the resolution of the wide-field monitoring device,
11. The satellite constellation system of claim 10, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. A satellite constellation included in the satellite constellation system according to any one of claims 10 to 14. Equipped with multiple satellite constellations including a first satellite constellation and a second satellite constellation ,
Each of the plurality of satellite constellations includes six or more plurality of satellites ,
The timing at which the plurality of artificial satellites orbit in the plurality of orbital planes is synchronized,
In the plurality of satellite constellations, the timings at which the plurality of artificial satellites orbit each other are synchronized.
A satellite constellation system according to claim 1 . Each satellite of the plurality of satellite constellations includes a communication device,
17. The satellite constellation system of claim 16, wherein the plurality of satellite constellations form a communication cross-link. The satellite constellation system according to claim 17, wherein the communication device is an optical communication device. The plurality of satellite constellations include a first satellite constellation group and a second satellite constellation group,
Each artificial satellite of the first satellite constellation group includes a first infrared monitoring device and a communication device,
Each artificial satellite of the second satellite constellation group includes a second infrared monitoring device and a communication device,
The first infrared monitoring device is a monitoring device that uses infrared rays to detect the launch of a flying object that glides while repeating intermittent injection after the end of the injection at the time of launch, pointing toward the earth's center,
The second infrared monitoring device is a monitoring device that uses infrared rays to monitor the flying object after the injection at the time of launch has ended, with the space as a background, pointing toward the circumference of the earth,
17. The satellite constellation system of claim 16, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. The plurality of satellite constellations include a first satellite constellation group and a second satellite constellation group,
Each satellite of the first satellite constellation group includes a wide-field monitoring device and a communication device,
Each satellite of the second satellite constellation group includes a high-resolution monitoring device, a viewing direction changing device, and a communication device,
The viewing direction changing device is a device for changing the viewing direction of the high resolution monitoring device,
The wide-field monitoring device is a monitoring device that has a resolution lower than that of the high-resolution monitoring device but has a wider field of view than the field of view of the high-resolution monitoring device,
The high-resolution monitoring device is a monitoring device that has a field of view narrower than the field of view of the wide-field monitoring device, but has a resolution higher than the resolution of the wide-field monitoring device,
17. The satellite constellation system of claim 16, wherein the first satellite constellation group and the second satellite constellation group form a communication cross-link. A satellite constellation included in the satellite constellation system according to any one of claims 16 to 20.

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