JP6707206B2 - Spacecraft control device, spacecraft control method, and program - Google Patents

Description

The present invention relates to a spacecraft control device, a spacecraft control method, and a program that perform orbital maintenance control and unloading of angular momentum of a spacecraft that orbits around an celestial body.

The spacecraft is equipped with an attitude control actuator that controls the attitude of the spacecraft and a thruster that maintains the longitude and latitude of the spacecraft within a desired range. The spacecraft is, for example, a geostationary satellite, an earth observation satellite, a spacecraft, or the like. As an example of the attitude control actuator, a reaction wheel, a CMG (Control Moment Gyro), or the like is mounted on the spacecraft. Various disturbance torques such as solar radiation torque and magnetic torque act on the spacecraft. Therefore, it is necessary to rotate the reaction wheel to absorb the disturbance torque and maintain the attitude of the spacecraft in a desired direction. Since the rotation speed of the reaction wheel is limited, it is possible to suppress an increase in the rotation speed of the reaction wheel and maintain the rotation speed of the reaction wheel within a normal range. This is called unloading of the angular momentum accumulated in the attitude control actuator. Specifically, unloading is performed by generating unloading torque using a thruster.

Patent Documents 1 and 2 disclose techniques for performing orbit hold control for maintaining the longitude and latitude of a spacecraft within a desired range and unloading angular momentum. The thruster mounted on the satellite disclosed in Patent Document 1 is ejected in the vicinity of the descending node of the orbit and in the vicinity of the ascending node. The control system disclosed in U.S. Pat. No. 6,096,839 uses spacecraft optimization using a cost function optimization over a receding horizon subject to constraints on the spacecraft attitude and inputs to the thrusters to unload excess momentum. Generate control input commands to simultaneously control the thruster and spacecraft momentum exchange devices.

JP-A-9-277997 JP, 2016-124538, A

A propellant is required to perform the above-described trajectory maintenance control and angular momentum unloading. When the propellant is exhausted, the spacecraft cannot perform orbit hold control and angular momentum unloading. Therefore, it is required to reduce the amount of propellant used in the trajectory maintenance control and the unloading of the angular momentum.

On the other hand, in order to increase the communication capability of the spacecraft, it is required to increase the power generated by the spacecraft, and the solar battery paddle of the spacecraft tends to be large. As the size of the solar array paddle increases, the effect of solar radiation pressure on the spacecraft increases. As a result, in order to compensate for the eccentricity of the satellite's orbit, which is increased by the influence of solar radiation pressure, the control amount of the east-west control for keeping the longitude of the satellite within the desired range is increased. Further, since the solar radiation pressure torque acting on the spacecraft also increases, the angular momentum of the attitude control actuator mounted on the spacecraft tends to be saturated. In this case, for example, in two locations near the ascending node and the descending node, or in the vicinity of the descending node and the ascending node of the orbit, as described in Patent Document 1, orbital holding control and angular momentum unloading. Doing and may not be optimal from the perspective of reducing propellant usage.

The control system disclosed in Patent Document 2 optimizes the operation of a spacecraft by using model predictive control (MPC) over a backward horizon. The control system determines the next state of the spacecraft based on the current state of the spacecraft, the current model of the spacecraft, and the current control inputs to the spacecraft. Therefore, the dimension of the optimization variable of MPC becomes a huge number of several tens to several hundreds, and the processing becomes complicated.

The present invention has been made in view of the above circumstances, the amount of propellant used is small, and the processing for performing orbital holding control and angular momentum unloading is performed by a computer mounted on a spacecraft. An object of the present invention is to provide a spacecraft control device, a spacecraft control method, and a program that are simplified so as to be possible.

In order to achieve the above object, a spacecraft control device according to the present invention includes an angular momentum calculation unit, a command value calculation unit, a thruster control unit, and a gimbal control unit. The angular momentum calculation unit calculates the angular momentum of the spacecraft that orbits the celestial body. The command value calculation unit includes a thruster command value for instructing the ejection of at least one thruster of the plurality of thrusters attached to the structure of the spacecraft via the gimbal mechanism, and the gimbal mechanism at the time of thruster ejection. An angle command value that indicates the angle of is calculated. The thruster control unit controls the thruster based on the thruster command value. The gimbal control unit controls the gimbal mechanism based on the angle command value. The command value calculation unit obtains the solution of the nonlinear programming problem in which the total of the injection amounts of the thrusters in the plurality of injection sections is the objective function under the first constraint condition, and thus the thruster commands of the plurality of injection sections are obtained. Value and angle command value are calculated. The first constraint of the nonlinear programming problem is based on the first function and the second function. The first function has the thruster command value and the angle command value in a plurality of injection sections in the trajectory as arguments, the thruster is controlled based on the thruster command value, and the gimbal mechanism is controlled based on the angle command value. In this case, the amount of change in the orbital element representing the orbit of the spacecraft and the amount of change in angular momentum are output while the spacecraft goes around the orbit. The second function outputs the control amount of the orbital element and the control amount of the angular momentum while the spacecraft goes around the orbit with the orbital element, the time change rate of the orbital element, and the angular momentum as arguments. The first constraint condition is that the change amount of the trajectory element and the control amount of the trajectory element match, and the change amount of the angular momentum and the control amount of the angular momentum match.

According to the present invention, under the first constraint condition in which the change amount of the trajectory element and the control amount of the trajectory element match, and the change amount of the angular momentum and the control amount of the angular momentum match, The solution of the nonlinear programming problem in which the total injection amount of thrusters in the injection section is the objective function is obtained. Since the solution of the non-linear programming problem is obtained and the thruster command value and the angular command value are calculated, the amount of propellant used is small, and the processing for orbit hold control and angular momentum unloading is simplified.

The figure which shows the example of a structure of a geostationary satellite in Embodiment 1 of this invention. The figure which shows the example of attachment to the spacecraft of the thruster in Embodiment 1. FIG. 3 is a diagram showing an example of the thruster and gimbal mechanism according to the first embodiment. Block diagram showing a configuration example of a spacecraft control device according to the first embodiment FIG. 3 is a block diagram showing a configuration example of a command value calculation unit according to the first embodiment. Flowchart showing an example of operation of command value calculation performed by the command value calculation unit according to the first embodiment The flowchart which shows an example of the operation|movement of the calculation of the 2nd function which the 2nd function calculation part which concerns on Embodiment 1 performs. The figure which shows the structural example of the command value calculation part which concerns on Embodiment 2 of this invention. Flowchart showing an example of operation of command value calculation performed by the command value calculation unit according to the second embodiment Configuration diagram showing an example of a hardware configuration of a spacecraft control device according to an embodiment Configuration diagram showing another example of the hardware configuration of the spacecraft control device according to the embodiment

Hereinafter, a spacecraft control device according to an embodiment of the present invention will be described in detail with reference to the drawings. In the drawings, the same or equivalent parts are designated by the same reference numerals.

(Embodiment 1)
The spacecraft control device according to the first embodiment will be described by taking a spacecraft control device mounted on a geostationary satellite that orbits the earth, which is an example of a spacecraft, as an example. This spacecraft control device performs orbit hold control for maintaining the geostationary satellite in a target orbit and unloading of the angular momentum accumulated in the attitude control actuator for controlling the attitude of the geostationary satellite.

As described above, FIG. 1 shows a geostationary satellite which is a control target of the spacecraft control device according to the first embodiment. The geostationary satellite 10 shown in FIG. 1 includes a structure 5, a gimbal mechanism 31, 32, 33, 34 attached to the structure 5, and thrusters 21, 22, 23, 34, which are attached to the gimbal mechanisms 31, 32, 33, 34, respectively. 24, and. The gimbal mechanisms 31, 32, 33, 34 have the same structure, and are attached to a surface 51 of the outer surface of the structure 5 located on the opposite side of the surface 50 facing the earth. The thrusters 21, 22, 23, and 24 are attached to the surface 51 so that the ejection directions thereof are different from each other. The thrusters 21, 22, 23, and 24 are also referred to as NW thruster 21, NE thruster 22, SW thruster 23, and SE thruster 24, respectively. The thrusters 21, 22, 23, 24 and the gimbal mechanisms 31, 32, 33, 34 are controlled by the spacecraft control device described later. Specifically, the spacecraft control device controls the angles of the gimbal mechanisms 31, 32, 33, and 34 shown in FIG. 1 and is attached to the structure 5 via the gimbal mechanisms 31, 32, 33, and 34. , 23, 24 are ejected to perform orbit hold control of the geostationary satellite 10 and unload the angular momentum.

As shown in FIG. 2, for ease of understanding, _{x H} axis, _{y H} axis, and a base of _{z H} axis, the centroid C. geostationary satellite 10 M. Set the orbit coordinate system with the origin of (Center of Mass) and refer to it appropriately. The x _H axis is the center of the earth 4, which is the celestial body located at the center of the orbit, and the center of mass C. M. Pass through. The z _H axis is the direction normal to the orbital plane of the geostationary satellite 10. The y _H axis constitutes the x _H axis and the z _H axis and the coordinates of the right-handed system. From each of the gimbal mechanisms 31, 32, 33, 34, the center of mass C.I. M. The attachment distances r indicating the distances to are the same as each other. x _H y _H plane projected centroid C. M. To the thrusters 21, 22, 23, and 24, and the angle ψ that is an acute angle formed by the x _H axis are the same. x _H z _H plane projected centroid C. M. To the thrusters 21, 22, 23, and 24, and the angle γ that is an acute angle formed by the z _H axis are the same.

Since the gimbal mechanisms 31, 32, 33, and 34 have the same structure, the gimbal mechanism 31 will be described with reference to FIG. The rotation axes of the gimbal mechanism 31 are the x _T axis and the y _T axis which are orthogonal to each other. an axis perpendicular to the xT axis and yT axis and _{z T} axis. The z _T axis is located parallel to the thrust axis of the thruster 21 attached to the gimbal mechanism 31. The gimbal angle around the x _T axis is α, and the gimbal angle around the y _T axis is β. When the gimbal angles α and β are 0, the z _T axis is the center of mass C. M. Even if the thruster 21 is jetted through, the torque does not act on the geostationary satellite 10. When at least one of the gimbal angles α and β is not 0, torque acts on the geostationary satellite 10 when the thruster 21 is jetted.

The thrusters 21, 22, 23, 24 and the gimbal mechanism 31, 32, 33, 34 described above are controlled by the spacecraft control device 1 shown in FIG. The spacecraft control device 1 controls the angles of the gimbal mechanisms 31, 32, 33, and 34 and ejects at least one of the thrusters 21, 22, 23, and 24 to control the orbit of the geostationary satellite 10. Unload angular momentum.
The spacecraft control device 1 includes an orbit determination unit 11 that calculates the orbital elements of the geostationary satellite 10, an angular momentum calculation unit 12 that calculates the angular momentum of the geostationary satellite 10, and thruster command values for the thrusters 21, 22, 23, and 24. And a command value calculation unit 13 that calculates an angle command value for the gimbal mechanisms 31, 32, 33, and 34, a thruster control unit 14 that controls the thrusters 21, 22, 23, and 24 based on the thruster command value, and an angle command value. The gimbal control part 15 which controls the gimbal mechanism 31, 32, 33, 34 based on this is provided.

The orbit determination unit 11, for example, GPS information acquired from a GPS (Global Positioning System) receiver mounted on the geostationary satellite 10, a range received from a ground station, a range rate, and an azimuth angle of the geostationary satellite 10. And the orbital element of the geostationary satellite 10 is calculated from the elevation angle information and the like. The range indicates the distance from the ground station to the geostationary satellite 10. The range rate indicates the rate of change in the distance from the ground station to the geostationary satellite 10. The ground station can obtain the azimuth angle and the elevation angle of the geostationary satellite 10 from the observation using the optical camera on the ground. The orbit determination unit 11 removes the periodic fluctuation component from the instantaneous values of the orbit elements of the geostationary satellite 10 to calculate the average orbit elements. The orbital elements include, for example, eccentricity, tilt angle and the like. In the following description, the average orbital element is used as the orbital element of the geostationary satellite 10. The periodic fluctuation component is a periodic fluctuation component which is generated by perturbation of the earth's gravity, for example, the tidal force of a perturbed celestial body such as the sun or the moon, and whose period is equal to or less than the threshold value. The trajectory determination unit 11 sends the calculated average trajectory element to the command value calculation unit 13. The trajectory determination unit 11 further calculates the time change rate of the average trajectory element and sends the time change rate of the average trajectory element to the command value calculation unit 13. The time change rate of the average trajectory element indicates the change amount of the average trajectory element in a sufficiently short time.

The angular momentum calculation unit 12 uses the attitude information of the geostationary satellite 10 obtained from sensors such as a star sensor, a gyro sensor, a magnetic sensor, an earth sensor, and a sun sensor mounted on the geostationary satellite 10 to determine the attitude of the geostationary satellite 10 and The attitude angular velocity is calculated and the angular momentum of the geostationary satellite 10 is calculated. The angular momentum calculation unit 12 sends the calculated angular momentum to the command value calculation unit 13.

Although detailed description will be given later, the command value calculation unit 13 obtains a solution of the nonlinear programming problem to hold the geostationary satellite 10 within a predetermined range from the target orbit, and a thruster command value and an angle command. Calculate the value. The thruster command value is a command value for at least one of the thrusters 21, 22, 23, and 24. Specifically, the thruster command value includes, for example, the injection timing, the injection phase, the total injection amount of the thrusters 21, 22, 23, 24, the ratio of the injection amount to the total injection amount, and the like. The angle command value indicates the gimbal angles α, β of at least one of the gimbal mechanisms 31, 32, 33, 34 at the time of injection of the thrusters 21, 22, 23, 24, respectively.

The thruster control unit 14 controls the thrusters 21, 22, 23 and 24 based on the thruster command value calculated by the command value calculation unit 13. The gimbal control unit 15 controls the gimbal mechanism 31, 32, 33, 34 based on the angle command value calculated by the command value calculation unit 13.

As shown in FIG. 5, the command value calculation unit 13 includes a first function calculation unit 131 that calculates a first function described below, a second function calculation unit 132 that calculates a second function described below, and a first function. Constraint condition setting unit 133 that determines a first constraint condition in which the output of the first function and the output of the second function match, and the second angle in which the angles of the gimbal mechanisms 31, 32, 33, and 34 are within the determined range. Of the thrusters 21, 22, 23, 24 in the plurality of injection sections under the first constraint condition and the second constraint condition. And a solution solver 135 that calculates the thruster command value and the angle command value by determining the solution of the nonlinear programming problem. The command value calculator 13 holds in advance latitude and longitude allowable ranges of the geostationary satellite 10, angular momentum allowable ranges, and gimbal angles α and β allowable ranges.

The first function calculation unit 131 uses the thruster command value and the angle command value in a plurality of injection sections as arguments to obtain a first function including the following formulas (13)-(16). The first function is when the thrusters 21, 22, 23, 24 are controlled based on the thruster command value that is an argument, and the gimbal mechanisms 31, 32, 33, 34 are controlled based on the angle command value that is an argument. In addition, the change amount of the orbital element and the change amount of the angular momentum are output while the geostationary satellite 10 goes around the orbit.

The second function calculation unit 132 acquires the average trajectory element and the temporal change rate of the average trajectory element from the trajectory determination unit 11, and acquires the angular momentum from the angular momentum calculation unit 12. Then, the second function calculation unit 132 uses the average orbital element, the time change rate of the average orbital element, and the angular momentum of the geostationary satellite 10 as arguments, and the following (17), (20), (22), ( 24) A second function including the expression is obtained. The second function outputs the control amount of the average orbital element of the geostationary satellite 10 and the control amount of the angular momentum of the geostationary satellite 10.

The first constraint condition setting unit 133 acquires the first function from the first function calculation unit 131, and acquires the second function from the second function calculation unit 132. Then, the first constraint condition setting unit 133 is a conditional expression indicating that the change amount of the trajectory element and the control amount of the average trajectory element match, and that the change amount of the angular momentum and the control amount of the angular momentum match. The first constraint condition that is

The second constraint condition setting unit 134 obtains a second constraint condition, which is a conditional expression indicating that the angles of the gimbal mechanisms 31, 32, 33, 34 are within the defined range.

Under the first constraint condition and the second constraint condition, the solution solver 135 determines the objective function for the nonlinear programming problem in which the sum of the injection amounts of the thrusters 21, 22, 23, 24 in the plurality of injection sections is the objective function. Find a solution that minimizes. As a result, the thruster command value and the angle command value for each of the plurality of injection sections are calculated.

Details of the allowable range that the command value calculation unit 13 holds in advance will be described. The command value calculation unit 13 holds in advance an allowable range of deviation of the geostationary satellite 10 from the target position. Specifically, the latitude target value φ _ref and the holding accuracy Δφ _max of the geostationary satellite 10 and the longitude target value λ _ref and the holding accuracy Δλ _max of the geostationary satellite 10 are held in advance. The latitude target value φ _ref and the longitude target value λ _ref indicate the above-described target trajectory. The latitude holding accuracy Δφ _max and the longitude holding accuracy Δλ _max indicate a predetermined range in which the geostationary satellite 10 is held and which includes a target orbit.
The range of latitude φ of the geostationary satellite 10 is expressed by the following equation (1). The range of the longitude λ of the geostationary satellite 10 is represented by the following equation (2).
φ _ref −Δφ _max ≦φ≦φ _ref +Δφ _max (1)
λ _ref −Δλ _max ≦λ≦λ _ref +Δλ _max (2)

In the case of the geostationary satellite 10, φ _ref is 0. If the observation target of the geostationary satellite 10 is Japan, λ _ref is, for example, 140°. The latitude holding accuracy Δφ _max and the longitude holding accuracy Δλ _max are, for example, 0.1°. In this case, the latitude range of the geostationary satellite 10 is −0.1° or more and 0.1° or less, and the longitude range of the geostationary satellite 10 is 139.9° or more and 140.1° or less. Is.

Furthermore, the command value calculation unit 13 holds in advance an allowable range of deviation of the angular momentum of the geostationary satellite 10 from the target value. Specifically, the command value calculation unit 13 holds in advance the target values h _xref , h _yref , h _zref of the angular momentum of the geostationary satellite 10 in the inertial system and the holding precisions Δh _xmax , Δh _ymax , Δh _zmax of the angular momentum in advance. ing.

The range of angular momentum of the geostationary satellite 10 is expressed by the following equations (3)-(5).
h _xref −Δh _xmax ≦h _x ≦h _xref +Δh _xmax (3)
_{h yref -Δh ymax ≦ h y ≦} h yref + Δh ymax (4)
h _zref −Δh _zmax ≦h _z ≦h _zref +Δh _zmax (5)
For example, in the case of a zero momentum satellite, h _xref , h _yref , and h _zref are all 0. In the case of the bias momentum satellite, none of h _xref , h _yref and h _zref is zero. Δh _xmax , Δh _ymax , and Δh _zmax are determined according to the magnitude of angular momentum that can be compensated by the attitude control actuator mounted on the geostationary satellite 10, such as a reaction wheel or CMG (Control Moment Gyro). _Let Δh _xmax , Δh _ymax , and Δh _zmax be, for example, 30 Nms.

Further, the command value calculation unit 13 holds the allowable range of the drive angle of the gimbal mechanism in advance. Specifically, the command value calculation unit 13 holds in advance the upper limits α _max , β _max and the lower limits −α _max , −β _max of the drive angles of the gimbal mechanisms 31, 32, 33, 34.

The upper limits α _max , β _max and the lower limits −α _max , −β _max of the drive angles of the gimbal mechanisms 31, 32, 33, 34 are the above-mentioned sensor, attitude control actuator, and attitude for acquiring the attitude information of the geostationary satellite 10. The attitude control system including the control device for controlling the control actuator is determined according to the magnitude of the disturbance torque that can be compensated. By rotating the gimbal mechanism 31, 32, 33, 34 and injecting the thrusters 21, 22, 23, 24, torque acts on the geostationary satellite 10. The torque magnitude T is proportional to the square norm of the gimbal angle, the thrust magnitude F of the thrusters 21, 22, 23 and 24, and the mounting distance r, as expressed by the following equation (6).

After the geostationary satellite 10 has been launched, the mounting distance r cannot be changed. The thrust magnitude F of the thrusters 21, 22, 23, 24 is considered to be constant on the orbit. Therefore, the torque magnitude T is adjusted by the gimbal angles α and β. A larger torque can be applied to the geostationary satellite 10 by increasing the gimbal angles α and β. Increasing the gimbal angles α and β improves the ability to unload the angular momentum accumulated in the geostationary satellite 10. However, the torque acting on the geostationary satellite 10 by the injection of the thrusters 21, 22, 23, 24 is a disturbance torque for the attitude control system of the geostationary satellite 10. Therefore, if the magnitude T of the torque is too large, the attitude control system becomes unstable and the attitude of the geostationary satellite 10 cannot be maintained. Therefore, the gimbal angles α and β are determined according to the upper limit value T _max of the disturbance torque that can be compensated by the attitude control system. The maximum value α _max of the gimbal angle α is expressed by the following equation (7). The maximum value β _max of the gimbal angle β is represented by the following equation (8). Κ in the following equations (7) and (8) is a positive number less than 1.

The ranges of gimbal angles α and β are expressed by the following equations (9) and (10).
−α _max ≦α≦α _max (9)
−β _max ≦β≦β _max (10)

The command value calculation unit 13 holds in advance the latitude and longitude ranges of the geostationary satellite 10, the angular momentum range, and the gimbal angle α and β ranges. The command value calculation unit 13 calculates the thruster command value and the angle command value by finding the solution of the nonlinear programming problem based on these allowable ranges. Specifically, the command value calculation unit 13 obtains a solution that minimizes the objective function under the first constraint condition described later. After explaining the overall flow of the command value calculation unit 13 with reference to FIG. 6, individual steps will be sequentially described in detail. The first function calculation unit 131 obtains the first function by using the thruster command value and the angle command value in the plurality of injection sections as arguments (step S11). The second function calculation unit 132 acquires the average trajectory element from the trajectory determination unit 11 and the angular momentum calculation unit 12 (step S12). The second function calculation unit 132 obtains the second function by using the average orbital element, the time change rate of the average orbital element, and the angular momentum of the geostationary satellite 10 as arguments (step S13). The first constraint condition setting unit 133 is a conditional expression indicating that the variation amount of the trajectory element and the control amount of the average trajectory element match, and that the variation amount of the angular momentum matches the control amount of the angular momentum. The first constraint condition is obtained (step S14). The second constraint condition setting unit 134 obtains a second constraint condition, which is a conditional expression indicating that the angles of the gimbal mechanisms 31, 32, 33, 34 are within the defined range (step S15). The solution finding unit 135 finds an objective function (step S16). The solving unit 135 determines the objective function for the nonlinear constraint problem based on the objective function that is the sum of the first constraint condition, the second constraint condition, and the injection amounts of the thrusters 21, 22, 23, and 24 in the plurality of injection sections. By obtaining the solution to be minimized, the thruster command value and the angle command value are calculated (step S17). The command value calculation unit 13 outputs the thruster command value and the angle command value to the thruster control unit 14 and the gimbal control unit 15, respectively (step S18).

Details of each step in FIG. 6 will be described in order. Details of the processing in step S11 will be described. The first function calculation unit 131 obtains the first function by using the thruster command value and the angle command value in the plurality of injection sections as arguments. An example will be described in which N injection sections are provided per round of the orbit. A case where the thruster command value is an instruction to inject two of the thrusters 21, 22, 23, and 24 in each of the N injection sections will be described as an example. The combination of the two is either a set of the NW thruster 21 and the NE thruster 22, a set of the SW thruster 23 and the SE thruster 24, a set of the SW thruster 23 and the NW thruster 21, or a set of the NE thruster 22 and the SE thruster 24. Is. It is possible to reduce the amount of propellant used by injecting only two of the thrusters 21, 22, 23, 24 in one injection section.

Two of the thrusters 21, 22, 23, and 24 that are injected in the j (1≦j≦N)-th injection section are referred to as a _j and b _j . a _j and b _j are any of a set of NW thruster 21 and NE thruster 22, a set of SW thruster 23 and SE thruster 24, a set of SW thruster 23 and NW thruster 21, and a set of NE thruster 22 and SE thruster 24. It is. thruster _a j for injecting the j-th injection interval, when the total injection amount of _{b j} and _{F j,} using the distribution coefficient xi] _j to determine the respective injection quantity a j, _{b j,} thrusters _a j, The injection amounts f _aj and f _bj of b _j are represented by the following equations (11) and (12). The distribution coefficient ξ _j is a coefficient that satisfies the condition of −1≦ξ _j ≦1. When ξ _j =1 only thruster a _j fires, when ξ _j =−1 only thruster b _j fires, and when ξ _j =0 thrusters a _j , b _j are equal To jet.

The parameters of the first function are the total injection amount F _{j in} the j-th injection section, the distribution coefficient ξ _{j in} the j-th injection section, the average longitude λ _{avgj in} the j-th injection section, and the j-th injection section. The angles are α _aj , β _aj , α _bj , β _bj . The angles α _aj and β _aj are angles in the j-th injection section of the gimbal mechanism 31, 32, 33, 34 that attaches the thruster a _j to the structure 5. The angles α _bj and β _bj are angles in the j-th injection section of the gimbal mechanism 31, 32, 33, 34 that attaches the thruster b _j to the structure 5.

The change amount of the orbital element, which is the output of the first function, is based on the linearized Gaussian planet equation, the total injection amount F _j , the distribution coefficient ξ _j , the average longitude λ _avgj , and the angles α _aj and β. _{It is} represented by _aj , α _bj , and β _bj . The amount of change in the orbital element includes the amount of change in each of the average eccentricity vector, the average inclination angle vector, and the average longitude of the point directly below. Further, the amount of change in the angular momentum, which is the output of the first function, is based on the linearized Euler's equation, the total injection amount F _j , the distribution coefficient ξ _j , the average longitude λ _avgj , and the angles α _aj , β. It is represented by _aj , α _bj , and β _bj .

The total change amount of the orbital elements and the total change amount of the angular momentum caused by the injection of the thrusters 21, 22, 23, 24 in the N injection sections are represented by the following equations (13)-(16). In the following equation (13), G _e (F _j , ξ _j , λ _avgj , α _aj , β _aj , α _bj , β _bj ) is a Gaussian planet equation for the eccentricity vector. In the formula (14) below, G _i (F _j , ξ _j , λ _avgj , α _aj , β _aj , α _bj , β _bj ) is a Gaussian planet equation for the tilt angle vector. In the formula (15) below, G _λ (F _j , ξ _j , λ _avgj , α _aj , β _aj , α _bj , β _bj ) is a Gaussian planet equation with respect to the mean longitude. In the following equation (16), E _h (F _j , ξ _j , λ _avgj , α _aj , β _aj , α _bj , β _bj ) is Euler's equation regarding the angular momentum of the geostationary satellite 10. The first function calculation unit 131 determines the above parameters, obtains a first function including the following expressions (13) to (16), and sends the first function to the first constraint condition setting unit 133.

Since the processing of step S11 of FIG. 6 has been described above, the processing of steps S12 and S13 performed in parallel with step S11 of FIG. 6 will be described below. In step S<b>12, the second function calculation unit 132 acquires the average trajectory element and the time change rate of the average trajectory element from the trajectory determination unit 11, and acquires the angular momentum from the angular momentum calculation unit 12. Then, in step S13, the second function calculation unit 132 determines the parameters by using the average orbital element, the time change rate of the average orbital element, and the angular momentum of the geostationary satellite 10 as arguments, and determines the average orbital element of the geostationary satellite 10. And a second function that outputs the control amount of the angular momentum of the geostationary satellite 10 are obtained. The control amount of the average trajectory element is the control amount of the average trajectory element which should be achieved by injecting the thrusters 21, 22, 23 and 24. The average trajectory element to be controlled includes an average eccentricity vector, an average inclination angle vector, and an average direct point longitude.

The outline of the process of step S13 in which the second function calculating unit 132 calculates the second function will be described with reference to FIG. 7, and then the details of each step will be described. The second function calculator 132 determines the radius e _R of the circle centered on the origin of the trajectory coordinate system that determines the target value e _target of the average eccentricity vector (step S21). The second function calculating unit 132 averages the target value e _target of the average eccentricity vector set at the intersection of the line segment connecting the earth 4 and the sun with the circle having the radius e _R centered on the origin of the orbit coordinate system. A control amount Δe _c for bringing the eccentricity vector closer is calculated (step S22). The second function calculating unit 132 sets any one of the yearly average tilt angle vector, the monthly average tilt angle vector, and the daily average tilt angle vector according to the magnitude of the latitude retention accuracy Δφ _max to control the average tilt. It is determined as an angle vector (step S23). The second function calculator 132 calculates the control amount Δi _c for the average tilt angle vector determined in step S23 (step S24). The second function calculator 132 calculates the control amount Δλ _c of the average direct point longitude (step S25). The second function calculator 132 calculates the control amount Δh _c of the angular momentum (step S26). As shown in FIG. 7, the second function calculation unit 132 can perform the processes of steps S21, S23, S25, and S26 in parallel.

The processing of steps S21 and S22 will be described. The second function calculating unit 132 sets the target value e _target of the average eccentricity vector at the intersection of the line segment connecting the earth 4 and the sun with the circle having the radius e _R centered on the origin of the orbit coordinate system, and The control amount Δe _c of the average eccentricity vector represented by the equation (17) is calculated. In the following equation (17), e _OD is the average eccentricity vector calculated by the trajectory determining unit 11. K _e is a positive coefficient. The second term −K _e (e _OD −e _target ) in the following equation (17) corresponds to the feedback control amount. The first term −δe _FF in the following equation (17) corresponds to the feedforward control amount. The feedforward control amount compensates for fluctuations in the average eccentricity vector due to perturbations acting on the geostationary satellite 10, for example, solar radiation pressure, the tidal force of the moon, and the tidal force of the sun. Δe _FF in the following formula (17) is expressed by the following formula (18). In the equation (18) below, e′ _OD is the time change rate of e _OD , and T _c is the cycle in which the geostationary satellite 10 orbits.
_{Δe c = -δe FF -K e (} e OD -e target) (17)
δe _FF =e' _OD T _c (18)

The target value e _target of the average eccentricity vector in the above equation (17) is set at the intersection of the line segment connecting the earth 4 and the sun with the circle of radius e _R centered on the origin of the orbit coordinate system. e _R is represented by the following formula (19). Δλ _M is a longitude error generated by an error of the average trajectory element calculated by the trajectory determination unit 11, an injection error of the thrusters 21, 22, 23, 24, and the like. Δλ _M is a value that satisfies 0<Δλ _M <Δλ _max , and is 0.02°, for example.

Since the processing in steps S21 and S22 in FIG. 7 has been described above, the processing in steps S23 and S24 performed in parallel with steps S21 and S22 in FIG. 7 will be described. The second function calculator 132 controls an average tilt angle vector, for example, an annual average tilt angle vector, a monthly average tilt angle vector, a daily average tilt angle vector, and the like. The second function calculator 132 controls the average tilt angle vector suitable for the magnitude of the latitude retention accuracy Δφ _max . For example, when 0.040°×(1+κ _φ )≦Δφ _max , the second function calculating unit 132 determines the annual average tilt angle vector as the control target. In the case of 0.0040°×(1+κ _φ )<Δφ _max <0.040°×(1+κ _φ ), the second function calculation unit 132 determines the monthly average tilt angle vector as the control target. When Δφ _max <0.004°×(1+κ _φ ), the second function calculating unit 132 determines the daily average tilt angle vector as the control target. The kappa _phi, is a positive coefficient, for example, is set to 1.1.

The control amount Δi _c of the average tilt angle vector is expressed by the following equation (20). In the following equation (20), i _OD is the average tilt angle vector calculated by the trajectory determining unit 11. i _target is a target value of the determined average tilt angle vector. K _i is a positive constant. The second term −K _i (i _OD −i _target ) in the following equation (20) corresponds to the feedback control amount. The first term −δi _FF in the following equation (20) corresponds to the feedforward control amount. The feedforward control amount compensates for the fluctuation of the average tilt angle vector due to the perturbation acting on the geostationary satellite 10. δi _FF is expressed by the following equation (21). In the following equation (21), di _FF /dt is the time change rate of the average tilt angle vector.
Δi _c =−δi _FF −K _i (i _OD −i _target ) (20)

Since the description of steps S23 and S24 in FIG. 7 is as above, the processing of step S25 performed in parallel with steps S23 and S24 in FIG. 7 will be described. The second function calculator 132 calculates the control amount Δλ _c of the average direct point longitude, which is represented by the following equation (22). In the following equation (22), λ _OD is the average direct point longitude calculated by the trajectory determining unit 11. In the following formula (22), λ _target is a target value of the average direct point longitude. K _λ is a positive coefficient. The second term −K _λ (λ _OD −λ _target ) in the following equation (22) corresponds to the feedback control amount. The first term −δλ _EF in the following equation (22) corresponds to the feedforward control amount. The feedforward control amount compensates for fluctuations in the average direct point longitude due to the perturbation acting on the geostationary satellite 10. δλ _EF is represented by the following equation (23). In the following equation (23), λ′ _OD is the angular velocity of the average direct point longitude. In the following equation (23), λ″ _OD is the angular acceleration of the average direct point longitude.
Δλ _c =−δλ _FF −K _λ (λ _OD −λ _target ) (22)

Since the description of step S25 in FIG. 7 has been given above, the processing of step S26 performed in parallel with step S25 in FIG. 7 will be described. The second function calculator 132 calculates the control amount Δh _c of the angular momentum represented by the following equation (24). In the following equation (24), h _AD is the angular momentum of the geostationary satellite 10 in the inertial system calculated by the angular momentum calculation unit 12. The second term −K _h (h _AD −h _ref ) in the equation (24) below corresponds to the feedback control amount. K _h is a positive coefficient. The first term −δh _FF in the equation (24) below corresponds to the feedforward control amount. The feedforward control amount compensates for the variation amount of the angular momentum in the inertial system caused by the perturbation torque. The most dominant torque among the perturbation torques is the torque due to the solar radiation pressure. Let τ _SRP be the solar radiation pressure torque acting on the geostationary satellite 10, and δh _FF is approximated by the following equation (25). h _ref is a target value of the angular momentum in the inertial system, and is represented by the following formula (26). The command value calculation unit 13 holds in advance each component of the target value h _ref of the angular momentum.
Δh _c =−δh _FF −K _h (h _AD −h _ref ) (24)
δh _FF =T _c τ _SRP (25)
h _ref =[h _xref , h _yref , h _zref ] ^T (26)

The second function calculation unit 132 sends the second function including the expressions (17), (20), (22), and (24) to the first constraint condition setting unit 133.

Since the processing of steps S12 and S13 in FIG. 6 has been described above, the processing of the subsequent step S14 will be described. The first constraint condition setting unit 133 is a conditional expression indicating that the change amount of the trajectory element and the control amount of the average trajectory element match, and that the change amount of the angular momentum and the control amount of the angular momentum match. Find the first constraint. The first constraint condition setting unit 133 sends the first constraint condition including the following equations (27)-(30) to the solution finding unit 135.
Δe _c =δ _e (27)
Δi _c =δ _i (28)
Δλ _c =δ _λ (29)
Δh _c =δ _h (30)

Since the processing of step S14 of FIG. 6 has been described above, the processing of subsequent step S15 will be described. The second constraint condition setting unit 134 obtains a second constraint condition, which is a conditional expression indicating that the angles of the gimbal mechanisms 31, 32, 33, 34 are within a predetermined range. The second constraint condition setting unit 134 sends the second constraint condition including the following expressions (31) to (34) to the solution finding unit 135.
-Α _max ≤α _aj ≤α _max (31)
-Β _max ≤ β _aj ≤ β _max (32)
-Α _max ≤α _bj ≤α _max (33)
−β _max ≦β _bj ≦β _max (34)

Since it is clear that the injection amount of the thrusters 21, 22, 23, 24 is larger than 0, the following equation (35) is established. Further, as described above, regarding the distribution coefficient in the injection section j, the following expression (36) is established.
0≦F _j (35)
-1 ≤ ξ _j ≤ 1 (36)

Since the description of step S15 in FIG. 6 has been given above, the processing of subsequent steps S16 and S17 will be described. The solution calculating unit 135 determines an objective function for the nonlinear constraint problem based on the objective function that is the sum of the first constraint condition, the second constraint condition, and the injection amounts of the thrusters 21, 22, 23, and 24 in the plurality of injection sections. By obtaining the solution to be minimized, the thruster command value and the angle command value for each of the plurality of injection sections are calculated. The objective function is expressed by the following equation (37).

The solution finding unit 135 finds a solution of the total injection amount F _j , the distribution coefficient ξ _j , the average longitude λ _avgj , and the angles α _aj , β _aj , α _bj , and β _bj in each of the injection sections. In solving nonlinear programming problems, methods such as sequential quadratic programming and interior point method are used. The solution _finding unit 135 obtains the injection timing including the start position and the end position of the injection section of the thrusters 21, 22, 23, 24 from the solution of λ _avgj obtained by solving the nonlinear programming problem. Further, the solution finding unit 135 obtains the injection amount of the thrusters 21, 22, 23, 24 in the injection section from the solution of F _j , ξ _j obtained by solving the nonlinear programming problem. Further, the solution finding unit 135 obtains the gimbal angle when the thrusters 21, 22, 23, and 24 are ejected from the solutions of α _aj , β _aj , α _bj , and β _bj obtained by solving the nonlinear programming problem.

Since the description of steps S16 and S17 in FIG. 6 has been given above, the processing of the subsequent step S18 will be described. The solution finding unit 135 sends a thruster command value indicating the injection timing and injection amount of the thrusters 21, 22, 23, 24 to the thruster control unit 14, and sends an angle command value indicating the gimbal angle to the gimbal control unit 15.

The thruster control unit 14 controls and ejects the thrusters 21, 22, 23, and 24 based on the thruster command value. The gimbal control unit 15 controls the gimbal angles of the gimbal mechanisms 31, 32, 33, 34 based on the angle command value. By solving the nonlinear programming problem as described above and calculating the thruster command value and the angular command value, the processing for performing orbital holding control and angular momentum unloading can be simplified while reducing the amount of propellant used. Is possible.

As described above, according to the spacecraft control device 1 according to the first embodiment, the solution that minimizes the objective function, which is the total thruster injection amount, is obtained for the nonlinear programming problem, and the thruster command value and the angle command are calculated. By calculating the value, it is possible to simplify the processing for performing the trajectory maintenance control and the angular momentum unloading while suppressing the amount of propellant used.

According to the spacecraft control device 1 according to the first embodiment, when it is necessary to inject the thrusters 21, 22, 23, and 24 at positions apart from the ascending and descending points, the thruster 21 is rotated during one round of the orbit. , 22, 23, and 24 need to be injected a plurality of times, it is possible to perform processing for performing orbital holding control and unloading of angular momentum while suppressing the amount of propellant used.

(Embodiment 2)
Although the constraint conditions of the nonlinear programming problem in the first embodiment are the first constraint condition and the second constraint condition, the nonlinear programming problem may further include other constraint conditions. The configuration of the spacecraft control device 1 according to the second embodiment is the same as the configuration of the spacecraft control device 1 according to the first embodiment shown in FIG. FIG. 8 is a diagram showing a configuration example of a command value calculation unit according to the second embodiment of the present invention. The command value calculation unit 16 according to the second embodiment further includes a third constraint condition setting unit 136 in addition to the configuration of the command value calculation unit 13 according to the first embodiment shown in FIG. The third constraint condition setting unit 136 sets a third constraint condition, which is a conditional expression indicating that the angular momentum is within a defined range, at least immediately before or immediately after the injection of each of the plurality of injection intervals. Obtained and sent to the solution finding unit 135.

The outline of the process in which the command value calculation unit 16 calculates the thruster command value and the angle command value will be described with reference to FIG. The processing of steps S11-S16 and S18 is the same as the processing shown in FIG. In the command value calculation unit 16 according to the second embodiment, the third constraint condition setting unit 136 sets the angular momentum within the defined range at least immediately before and immediately after the injection of each of the plurality of injection sections. A third constraint condition that is a conditional expression indicating that there is is obtained (step S19). The solution finding unit 135 finds an objective function (step S16). The solution calculating unit 135 uses the first constraint condition, the second constraint condition, the third constraint condition, and the nonlinear function based on the objective function that is the sum of the injection amounts of the thrusters 21, 22, 23, and 24 in the plurality of injection sections. For the problem, the thruster command value and the angle command value are calculated by finding a solution that minimizes the objective function (step S20). The subsequent processing is the same as the processing shown in FIG.

When α _max and β _max in the equations (31) to (34) are reduced, the torque acting on the geostationary satellite 10 during the injection of the thrusters 21, 22, 23, and 24 is reduced. That is, the fluctuation of the angular momentum caused by the ejection of the thrusters 21, 22, 23, 24 is suppressed. Even if the fluctuation of the angular momentum is suppressed by reducing α _max and β _max , the angular momentum is within the range defined by the above formulas (3) to (5) immediately before or immediately after the injection in the injection section. There are things that are not in. Therefore, the third constraint condition setting unit 136 is a third constraint that is a conditional expression indicating that the angular momentum is within a predetermined range at least immediately before or immediately after the injection in each of the plurality of injection intervals. Find the conditions. That is, the third constraint condition setting unit 136 obtains the third constraint condition, which is a conditional expression indicating that at least one of the following expressions (38) and (39) is satisfied. H _j ⁽⁻⁾ in the following equation (38) is the angular momentum immediately before the injection in the j-th injection section. The angular momentum immediately before the injection in the jth injection section is the angular momentum of the geostationary satellite 10 immediately before the start of injection of the thrusters 21, 22, 23, 24 in the jth injection section. H _j ⁽⁺⁾ in the following equation (39) is the angular momentum immediately after the injection in the j-th injection section. The angular momentum immediately after the injection of the j-th injection section is the angular momentum of the geostationary satellite 10 immediately after the injection of the thrusters 21, 22, 23, 24 in the j-th injection section. h _j ⁽⁻⁾ and h _j ⁽⁺⁾ are functions of the variables F _j , ξ _j , λ _avgj , α _aj , β _aj , α _bj , β _bj .
h _ref −Δh _max ≦h _j ⁽⁻⁾ ≦h _ref +h _max (38)
h _ref −Δh _max ≦h _j ⁽⁺⁾ ≦h _ref +h _max (39)

For each component of h _j ^(−), the following (40)-(42) is established, as in the above expressions (3)-(5). Further, with respect to each component of h _j ^(+), the following (43)-(45) is established as in the above expressions (3)-(5).
h _xref −Δh _xmax ≦h _xj ⁽⁻⁾ ≦h _xref +Δh _xmax (40)
^{_{h yref -Δh ymax ≦ h yj (}} -) ≦ h yref + Δh ymax (41)
h _zref −Δh _zmax ≦h _zj ⁽⁻⁾ ≦h _zref +Δh _zmax (42)
h _xref −Δh _xmax ≦h _xj ⁽⁺⁾ ≦h _xref +Δh _xmax (43)
^{_{h yref -Δh ymax ≦ h yj (}} +) ≦ h yref + Δh ymax (44)
h _zref −Δh _zmax ≦h _zj ⁽⁺⁾ ≦h _zref +Δh _zmax (45)

As described above, according to the spacecraft control device 1 according to the second embodiment, the angular momentum is within the defined range at least immediately before or immediately after the injection in each of the plurality of injection sections. Is set as the third constraint condition of the nonlinear programming problem, the angular momentum of the geostationary satellite 10 can be maintained within the holding range. Therefore, it is possible to perform trajectory holding control and unload the angular momentum without saturating the angular momentum of the attitude control actuator.

Next, the hardware configuration of this embodiment will be described. FIG. 10 is a diagram illustrating an example of the hardware configuration. FIG. 10 shows an example in which the spacecraft control device 1 is realized by the processing circuit 101. As shown in FIG. 10, the geostationary satellite 10 includes a sensor 110 for observing the position, velocity, attitude angle, and angular velocity of the satellite, a spacecraft controller 1, thrusters 21, 22, 23, 24, and gimbal mechanisms 31, 32, 33. , 34.

When the processing circuit 101 is dedicated hardware, the processing circuit 101 is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), or an FPGA (Field Programmable). Gate Array) or a combination of these. The functions of each of the trajectory determining unit 11, the angular momentum calculating unit 12, the command value calculating unit 13, the thruster control unit 14, and the gimbal control unit 15 may be realized by the processing circuit 101, or the functions of each unit may be combined. It may be realized by the processing circuit 101.

FIG. 11 is a diagram showing another example of the hardware configuration of the present embodiment. FIG. 11 shows an example in which the spacecraft control device 1 is realized by a processor (CPU: Central Processing Unit) 102 and a memory 103. The processor 102 and the memory 103 in FIG. 11 correspond to the processing circuit 101 in FIG.

When the spacecraft control device 1 is realized by the processor 102 and the memory 103, the functions of the orbit determination unit 11, the angular momentum calculation unit 12, the command value calculation unit 13, the thruster control unit 14, and the gimbal control unit 15 are software, It is realized by firmware or a combination of software and firmware. Software and firmware are described as a program and stored in the memory 103. The processor 102 realizes the function of each unit by reading and executing the program stored in the memory 103. That is, the memory 103 stores a program for executing the processes of the trajectory determination unit 11, the angular momentum calculation unit 12, the command value calculation unit 13, the thruster control unit 14, and the gimbal control unit 15. The memory 103 is non-volatile, such as RAM (Random Access Memory), ROM (Read-Only Memory), flash memory, EPROM (Erasable Programmable Read Only Memory), or EEPROM (Electrically Erasable and Programmable Read-Only Memory). It includes volatile semiconductor memory, magnetic disk, flexible disk, optical disk, compact disk, mini disk, DVD (Digital Versatile Disc), and the like.

In addition to the above program, the memory 103 stores the orbit determination value determined by the orbit determination unit 11, the satellite angular momentum value set by the angular momentum calculation unit 12, the thruster command value calculated by the command value calculation unit 13, and the gimbal. The angle command value is stored. The information stored in the memory 103 described above is read out as appropriate and used for the processing of the trajectory determination unit 11, the angular momentum calculation unit 12, the command value calculation unit 13, the thruster control unit 14, and the gimbal control unit 15, and is corrected. To be done.

It should be noted that some of the functions of the trajectory determination unit 11, the angular momentum calculation unit 12, the command value calculation unit 13, the thruster control unit 14, and the gimbal control unit 15 are realized by dedicated hardware and some of them are performed by software or You may make it implement|achieve by firmware. For example, the orbit determination unit 11 realizes its function by the processing circuit 101 as a dedicated hardware, and the command value calculation unit 13 causes the processor 102 to read and execute the program stored in the memory 103 to execute the function. It is possible to realize the function.

The embodiment of the present invention is not limited to the above embodiment. The spacecraft is not limited to the geostationary satellite 10, but is any flying body that orbits around the celestial body. Examples of flying bodies are earth observation satellites, spacecraft, and the like. The number of thrusters 21, 22, 23, 24 is arbitrary, and the number and combination of thrusters 21, 22, 23, 24 to be jetted in each jetting section are also arbitrary. The degree of freedom of the gimbal mechanism 31, 32, 33, 34 may be one. When the degree of freedom of the gimbal mechanism 31, 32, 33, 34 is 1, β=0 in the above equation, so that the first function of the variables F _j , ξ _j , λ _avgj , α _aj , α _bj Is a function. When β=0, similarly to the first function, h _j ⁽⁻⁾ and h _j ⁽⁺⁾ are functions of variables F _j , ξ _j , λ _avgj , α _aj , and α _bj . In the example of FIG. 1, the thrusters 21, 22, 23, 24 are attached to the structure 5 of the spacecraft, but the number of thrusters 21, 22, 23, 24 attached to the structure 5 of the spacecraft is arbitrary. .. The angles ψ and γ of the thrusters 21, 22, 23 and 24 may be the same or different.

The latitude and longitude ranges and the latitude and longitude holding accuracy are not limited to the above examples, and can be arbitrarily determined. As described above, the second function calculation unit 132 may calculate the time change rate of the average trajectory element instead of the trajectory determination unit 11 calculating the time change rate of the average trajectory element. The trajectory determination unit 11 may acquire the activation element from an external device instead of calculating the trajectory element. The trajectory determination unit 11 may send the instantaneous values of the trajectory elements to the command value calculation unit 13. The second function calculation unit 132 calculates the control amount Δe _c of the average eccentricity vector, the average tilt angle vector Δi _c , the control amount Δλ _c of the average direct point longitude, and the angular momentum shown in FIG. The control amount Δh _c may be calculated sequentially.

The solution finding unit 135 may calculate the thruster command value and the gimbal command value by finding a solution of the nonlinear programming problem under the first constraint condition. Alternatively, the solution finding unit 135 may find the solution of the nonlinear programming problem under the first constraint condition and the third constraint condition. Further, the solution finding unit 135 may calculate the thrust command value and the gimbal command value by finding a suboptimal solution that reduces the objective function under the first constraint condition.

The present invention allows various embodiments and modifications without departing from the broad spirit and scope of the present invention. Further, the above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the scope of the claims. Various modifications made within the scope of the claims and within the scope of the meaning of the invention equivalent thereto are regarded as within the scope of the present invention.

This application is based on Japanese Patent Application No. 2017-168649 filed on Sep. 1, 2017. The specification, claims, and the entire drawing of Japanese Patent Application No. 2017-168649 are incorporated herein by reference.

1 spacecraft control device, 4 earth, 5 structure, 10 geostationary satellite, 11 orbit determination unit, 12 angular momentum calculation unit, 13, 16 command value calculation unit, 14 thruster control unit, 15 gimbal control unit 21, 22, 22, 23 , 24 thruster, 31, 32, 33, 34 gimbal mechanism, 50, 51 surface, 101 processing circuit, 102 processor, 103 memory, 110 sensor, 131 first function calculating section, 132 second function calculating section, 133 first constraint Condition setting part, 134 2nd constraint condition setting part, 135 Solving part, 136 3rd constraint condition setting part.

Claims (14)

An angular momentum calculation unit that calculates the angular momentum of the spacecraft that orbits around the celestial body,
A thruster command value for instructing the ejection of at least one thruster among a plurality of thrusters attached to the structure of the spacecraft via a gimbal mechanism, and an angle of the gimbal mechanism at the time of ejecting the thruster. A command value calculation unit that calculates the commanded angle command value,
A thruster control unit that controls the thruster based on the thruster command value;
A gimbal control unit that controls the gimbal mechanism based on the angle command value,
Equipped with
The command value calculation unit uses the thruster command value and the angle command value in a plurality of injection sections in the trajectory as arguments, the thruster is controlled based on the thruster command value, and the thruster command value is calculated based on the angle command value. A first function that outputs a change amount of an orbital element representing the orbit of the spacecraft and a change amount of the angular momentum while the spacecraft goes around the orbit when the gimbal mechanism is controlled, and Outputting the control amount of the orbital element and the control amount of the angular momentum while the spacecraft goes around the orbit with the orbital element, the time change rate of the orbital element, and the angular momentum as arguments. Under the first constraint condition in which the change amount of the trajectory element and the control amount of the trajectory element match, and the change amount of the angular momentum and the control amount of the angular momentum match based on the function of 2. Then, the solution of the nonlinear programming problem in which the sum of the injection amounts of the thrusters in the plurality of injection sections is an objective function is calculated, and the thruster command value and the angle command value of each of the plurality of injection sections are calculated. ,
Spacecraft control device. The command value calculation unit calculates the thruster command value and the angle command value of each of the plurality of injection sections by obtaining a solution of the nonlinear programming problem that minimizes the objective function.
The spacecraft control device according to claim 1. The command value calculation unit obtains a solution of the nonlinear programming problem under a second constraint condition in which an angle of the gimbal mechanism is within a predetermined range, and thereby the thruster of each of the plurality of injection sections is obtained. Calculate a command value and the angle command value,
The spacecraft control device according to claim 1. The command value calculation unit is configured such that the angular momentum is at least one of a second constraint condition in which an angle of the gimbal mechanism is within a predetermined range, and at least one of immediately before injection and immediately after injection of each of the plurality of injection sections. By calculating a solution of the nonlinear programming problem under a third constraint condition within a defined range, the thruster command value and the angle command value of each of the plurality of injection sections are calculated.
The spacecraft control device according to claim 1. The control amount of the orbital element calculated by the second function is a feedforward control amount that corrects the fluctuation of the orbital element caused by the perturbation acting on the spacecraft while the spacecraft makes one revolution in the orbit. And a feedback control amount based on the trajectory element and a target value of the trajectory element,
The spacecraft control device according to any one of claims 1 to 4. The control amount of the angular momentum calculated by the second function is a feedforward control amount that corrects the fluctuation of the angular momentum caused by the perturbation torque that acts on the spacecraft while the spacecraft makes a turn around the orbit. And a feedback control amount based on the angular momentum and a target value of the angular momentum,
The spacecraft control device according to any one of claims 1 to 5. The orbital element includes an eccentricity vector, a tilt angle vector, and a direct point longitude,
The spacecraft control device according to any one of claims 1 to 6. The second function is a control amount for any one of the annual average tilt angle vector, the monthly average tilt angle vector, and the daily average tilt angle vector according to the latitude holding accuracy obtained in the orbit holding control of the spacecraft. Outputting the controlled variable of the orbital element including
The spacecraft control device according to claim 7. One of the outer surfaces of the structure is always facing the celestial body,
The plurality of thrusters are attached to a surface of the outer surface of the structure that is located on the opposite side of the surface that is always facing the celestial body, with the ejection directions different from each other.
The spacecraft control device according to any one of claims 1 to 8. The gimbal mechanism has two degrees of freedom,
The number of the plurality of thrusters is four,
The thruster extends in a direction away from the center of mass of the spacecraft,
Of the four thrusters, two of the thrusters are fired in the firing section.
The spacecraft control device according to any one of claims 1 to 9. The angle of the gimbal mechanism is a value within a range in which the torque acting on the spacecraft by the thruster injection is equal to or less than the upper limit value of the disturbance torque that can be compensated by the attitude control system of the spacecraft.
The spacecraft control device according to any one of claims 1 to 10. The thruster command value is the ejection phase of the thruster, the sum of the ejection amounts of the plurality of thrusters, and the ratio of the ejection amount of the thruster instructed to be ejected by the thruster command value in the total.
The spacecraft control device according to any one of claims 1 to 11. When the thruster command value and the angle command value in a plurality of injection sections in the orbit are used as arguments, the thruster is controlled based on the thruster command value, and the gimbal mechanism is controlled based on the angle command value. A first function that outputs a change amount and a change amount of the angular momentum, and a control amount of the orbital element and a control amount of the angular momentum with the orbital element, the time change rate of the orbital element, and the angular momentum as arguments. Based on a second function for outputting a solution of the objective function for a nonlinear programming problem in which the sum of the injection amounts of the thrusters in the plurality of injection sections is the objective function while satisfying a predetermined constraint condition. Then, the thruster command value and the angle command value of each of the plurality of injection sections are calculated,
Spacecraft control method. Computer,
An angular momentum calculator that calculates the angular momentum of a spacecraft that orbits the celestial body,
A thruster command value for instructing the ejection of at least one thruster among a plurality of thrusters attached to the structure of the spacecraft via a gimbal mechanism, and an angle of the gimbal mechanism at the time of ejecting the thruster. A command value calculation unit that calculates the commanded angle command value,
A thruster controller that controls the thruster based on the thruster command value; and
A gimbal control unit that controls the gimbal mechanism based on the angle command value,
It is a program to function as
The command value calculation unit uses the thruster command value and the angle command value in a plurality of injection sections in the trajectory as arguments, the thruster is controlled based on the thruster command value, and the thruster command value is calculated based on the angle command value. A first function that outputs a change amount of an orbital element representing the orbit of the spacecraft and a change amount of the angular momentum while the spacecraft goes around the orbit when the gimbal mechanism is controlled, and Outputting the control amount of the orbital element and the control amount of the angular momentum while the spacecraft goes around the orbit with the orbital element, the time change rate of the orbital element, and the angular momentum as arguments. Under the first constraint condition in which the change amount of the trajectory element and the control amount of the trajectory element match, and the change amount of the angular momentum and the control amount of the angular momentum match based on the function of 2. Then, the solution of the nonlinear programming problem in which the sum of the injection amounts of the thrusters in the plurality of injection sections is an objective function is calculated, and the thruster command value and the angle command value of each of the plurality of injection sections are calculated. ,
program.

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