阅读说明：本技术 人造卫星经过雷达探测范围的预报方法、系统、介质及设备 (Method, system, medium, and apparatus for forecasting passing of artificial satellite through radar detection range ) 是由 张艳 王志辉 于 2020-06-30 设计创作，主要内容包括：本发明涉及一种人造卫星经过雷达探测范围的预报方法、系统、介质及设备,方法包括：获取卫星两行根数信息；剔除不可能进入雷达探测范围的卫星；建立卫星轨道预报模型；粗略筛选卫星能够进入探测范围的时间区间；精确计算卫星进入探测范围时间区间及进入时的视角。本发明实施例采用剔除不可能进入雷达探测范围的卫星和两次筛选相结合的方法,能够精确快速地预报人造卫星经过雷达探测范围的时间和进入时的视角,运算量小,耗时短,操作员能够根据本方法提供的结果快速地对雷达进行任务规划,更有效地执行跟踪任务。(The invention relates to a method, a system, a medium and equipment for forecasting artificial satellites passing through a radar detection range, wherein the method comprises the following steps: acquiring two-line root information of a satellite; rejecting satellites which cannot enter a radar detection range; establishing a satellite orbit forecasting model; roughly screening a time interval in which the satellite can enter a detection range; and accurately calculating the time interval when the satellite enters the detection range and the view angle when the satellite enters the detection range. According to the embodiment of the invention, the method of eliminating the satellite which cannot enter the radar detection range and the method of combining the two screening can be adopted, so that the time when the artificial satellite passes through the radar detection range and the view angle when the artificial satellite enters can be accurately and quickly forecasted, the calculation amount is small, the time consumption is short, an operator can quickly plan the task of the radar according to the result provided by the method, and the tracking task can be more effectively executed.)

1. The method for forecasting the artificial satellite passing through the radar detection range is characterized by comprising the following steps:

acquiring two-row root information of a satellite, and analyzing orbit parameter information according to the two-row root information of the satellite;

according to the orbit parameter information and the envelope area information of the radar detection range, eliminating satellites which cannot enter the radar detection range;

establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range and a rough time interval passing through the detection range in a specified time period by using the satellite orbit prediction model and a preset pitch angle transit threshold;

and determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope area information of the radar detection range.

2. The method according to claim 1, wherein the rejecting satellites that are unlikely to enter a radar-specific detection area according to the orbit parameter information and envelope area information of the radar-specific detection area comprises:

determining the minimum pitch angle of the envelope area according to the envelope area information of the radar specified detection range; and determining an orbit inclination angle in the orbit parameter information, and rejecting the satellite when the orbit inclination angle of the satellite is smaller than the minimum pitch angle of the envelope area.

3. The method of claim 2, wherein determining a minimum pitch angle of an envelope region from envelope region information of the radar detection range comprises:

determining five vertexes P of envelope area by taking radar site as center_n(n is 0,1,2,3,4) and the coordinate in the radar earth coordinate system is P_n(R_n,A_n,E_n) (ii) a Wherein R is_nIs a distance, A_nIs an azimuth angle, E_nIs a pitch angle;

calculating the coordinate P of the five vertexes under the rectangular coordinate system of the geocentric space through coordinate change_n(X0_n,Y0_n,Z0_n) Counterclockwise rotation of the sidereal hour angle α along the Z-axis_GRotating the X axis to point to the connection line of the earth mass center and the spring minute point to obtain a coordinate P under the coordinate system_n(X1_n,Y1_n,Z1_n) Then converting the coordinate in the coordinate system into a polar coordinate P_n(R2_n,A2_n,E2_n) So as to obtain the pitch angle E2 of each vertex_nDetermining minimum pitch angle E2 in five vertexes_AreaMinThe minimum pitch angle of the envelope region.

4. The method of claim 3, wherein the five vertices P_n(n is 0,1,2,3,4) and the coordinate in the radar earth coordinate system is P_n(R_n,A_n,E_n) Respectively as follows: p₀(0,0,0)、P₁(R_LimitH,A_LimitL,E_LimitL)、P₂(R_LimitH,A_LimitL,E_LimitH)、P₃(R_LimitH,A_LimitH,E_LimitL)、P₄(R_LimitH,A_LimitH,E_LimitH) Wherein R is_LimitHFor the maximum power distance of the radar, A_LimitLAt the lower limit of orientation, A_LimitHIs an upper limit of azimuth, E_LimitLTo a lower limit of pitch, E_LimitHIs the upper limit of pitch.

5. The method according to any one of claims 1 to 4, wherein the predicting, using the satellite orbit prediction model and a preset pitch angle transit threshold, satellites likely to enter a radar detection range and a rough time interval passing the detection range within a specified time period comprises:

starting from the initial time of the designated time period until the end time, according to a first time interval T_GPerforming skip point calculation to obtain time sequences T (1), T (2), …, T (N), wherein T (n) is T (1) + (n-1) T_G,n＝1,2,...,N；

Calculating the position coordinate S of the satellite in the radar earth coordinate system at the moment t (n) by using the satellite orbit prediction model_n(R_n,A_n,E_n) Wherein R is_nIs a distance, A_nIs an azimuth angle, E_nIs a pitch angle;

elevation angle E of satellite_nGreater than or equal to a preset pitch angle crossing threshold E_DoorDetermining that the satellite is likely to enter a radar detection range within a specified time period; wherein, a pitch angle crossing threshold E is preset_DoorLess than the lower pitch limit E of the envelope region_LimitLI.e. 0. ltoreq.E_Door≤E_LimitL；

Sequentially jumping to inquire whether the satellite meets the conditions from the initial time to the end time of the specified time period, recording a first initial time and a first end time when the satellite meets the conditions, and determining at least one rough time interval passing through the detection range according to the first initial time and the first end time;

the first start time of each coarse time interval is a previous hop time of a first hop time satisfying the condition, and the first end time of each coarse time interval is a next hop time of a last hop time satisfying the condition or an end time of the designated time period when the condition is continuously satisfied from the first start time.

6. The method according to claim 5, wherein the determining the position coordinates of the satellites in the coarse time interval by using the satellite orbit prediction model, and the determining the satellites capable of entering the radar detection range and the precise time interval passing the detection range and the view angle when entering according to the position coordinates of the satellites and the envelope region information of the radar detection range comprises:

starting from the initial time of the coarse time interval until the end time, according to a second time interval T_QPerforming skip point calculation to obtain a time sequence tm (1), tm (2), …, tm (K), wherein tm (k) is tm (1) + (k-1) × T_QK is 1,2,. K; a second time interval T_QLess than said first time interval T_G；

Calculating the position coordinate Sm of the satellite at the moment tm (k) in the radar earth coordinate system by using the satellite orbit prediction model_k(Rm_k,Am_k,Em_k) Wherein Rm_kIs a distance, Am_kIs the azimuth angle, Em_kIs a pitch angle;

when the position coordinate Sm_k(Rm_k,Am_k,Em_k) When the satellite is located in the range of the envelope area, determining that the satellite can enter a radar detection range;

sequentially jumping to inquire whether the satellite meets the conditions from the initial time of the rough time interval to the end time, recording a second initial time and a second end time when the satellite meets the conditions, and determining the precise time interval passing through the detection range according to the second initial time and the second end time;

the second starting time is the first jumping point time meeting the above conditions in the coarse time interval, and the second ending time is the last jumping point time meeting the above conditions in the coarse time interval;

and forecasting the satellite position according to the accurate time interval to obtain the visual angle when the satellite enters the radar detection range.

7. The method of claim 6, wherein the position coordinates Sm are when_k(Rm_k,Am_k,Em_k) When the satellite is located in the range of the envelope area, determining that the satellite can enter a radar detection range, wherein the method comprises the following steps: when the position coordinates satisfy the following conditionsAnd determining that the satellite can enter a radar detection range:

Rm_k≤R_LimitH

A_LimitL≤Am_k≤A_LimitH

E_LimitL≤Em_k≤E_LimitH

wherein R is_LimitHFor the maximum power distance of the radar, A_LimitLAt the lower limit of orientation, A_LimitHIs an upper limit of azimuth, E_LimitLTo a lower limit of pitch, E_LimitHIs the upper limit of pitch.

8. A system for forecasting the passage of a satellite through a radar detection range, comprising:

the orbit parameter acquisition module is used for acquiring the two-line root information of the satellite and analyzing the orbit parameter information according to the two-line root information of the satellite;

the pre-screening module is used for eliminating satellites which cannot enter a radar detection range according to the orbit parameter information and the envelope area information of the radar detection range;

the rough screening module is used for establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range within a specified time period and a rough time interval passing the detection range by using the satellite orbit prediction model and a preset pitch angle transit threshold;

and the precise calculation module is used for determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope area information of the radar detection range.

9. A computer-readable storage medium comprising instructions that, when executed on a computer, cause the computer to perform a method of forecasting of the passage of a satellite through a radar detection range according to any one of claims 1-7.

10. A computer arrangement comprising a memory, a processor and a computer program stored on the memory and executable on the processor, characterized in that the processor, when executing the program, implements a method for the prediction of the passage of a satellite through a radar detection range according to any one of claims 1-7.

Technical Field

The invention relates to the technical field of satellite transit forecasting, in particular to a method, a system, a medium and equipment for forecasting an artificial satellite passing through a radar detection range.

Background

When the artificial satellite runs in the space orbit, the radar can track the artificial satellite through the detection range of the radar.

However, in the prior art, there is no effective scheme for predicting that the artificial satellite passes through the radar detection range, the time when the artificial satellite passes through the radar detection range and the view angle when the artificial satellite enters cannot be accurately and quickly predicted, a radar operator cannot plan a task for the radar in advance, and the radar cannot effectively execute a tracking task.

Disclosure of Invention

The invention aims to solve the technical problem in the prior art and provides a method, a system, a medium and equipment for forecasting the artificial satellite passing through a radar detection range.

In order to solve the above technical problem, an embodiment of the present invention provides a method for forecasting an artificial satellite passing through a radar detection range, including:

acquiring two-row root information of a satellite, and analyzing orbit parameter information according to the two-row root information of the satellite;

according to the orbit parameter information and the envelope area information of the radar detection range, eliminating satellites which cannot enter the radar detection range;

establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range and a rough time interval passing through the detection range in a specified time period by using the satellite orbit prediction model and a preset pitch angle transit threshold;

and determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope area information of the radar detection range.

In order to solve the above technical problem, an embodiment of the present invention further provides a system for forecasting an artificial satellite passing through a radar detection range, including:

the orbit parameter acquisition module is used for acquiring the two-line root information of the satellite and analyzing the orbit parameter information according to the two-line root information of the satellite;

the pre-screening module is used for eliminating satellites which cannot enter a radar detection range according to the orbit parameter information and the envelope area information of the radar detection range;

the rough screening module is used for establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range within a specified time period and a rough time interval passing the detection range by using the satellite orbit prediction model and a preset pitch angle transit threshold;

and the precise calculation module is used for determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope area information of the radar detection range.

In order to solve the above technical problem, an embodiment of the present invention further provides a computer-readable storage medium, which includes instructions that, when executed on a computer, cause the computer to execute the method for forecasting that an artificial satellite passes through a radar detection range according to the above aspect.

In order to solve the above technical problem, an embodiment of the present invention further provides a computer device, which includes a memory, a processor, and a computer program stored in the memory and executable on the processor, where the processor implements the method for forecasting the passing of the artificial satellite through the radar detection range according to the above aspect when executing the program.

The invention has the beneficial effects that: according to the embodiment of the invention, the method of eliminating the satellite which cannot enter the radar detection range and the method of combining the two screening can be adopted, so that the time when the artificial satellite passes through the radar detection range and the view angle when the artificial satellite enters can be accurately and quickly forecasted, the calculation amount is small, the time consumption is short, an operator can quickly plan the task of the radar according to the result provided by the method, and the tracking task can be more effectively executed.

Additional aspects of the invention and its advantages will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

FIG. 1 is a flow chart of a method for forecasting a passing of a satellite through a radar detection range according to an embodiment of the present invention;

fig. 2 is a block diagram of a system for forecasting the passing of artificial satellites through a radar detection range according to an embodiment of the present invention.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the invention.

Fig. 1 is a flowchart of a method for forecasting passing of a radar detection range by an artificial satellite according to an embodiment of the present invention. As shown in fig. 1, the method includes:

s10, acquiring two-line root information of a satellite, and analyzing orbit parameter information according to the two-line root information of the satellite;

specifically, the orbit parameters including the NORAD satellite number, TLE root epoch Time, orbit inclination i, ascent intersection right ascension Ω, orbit eccentricity e, perigee argument ω, mean perigee angle M0, and daily number of earth revolutions L may be analyzed from the two-line element orbit data (TLE) of the satellite desired, which is downloaded from the north american air defense commander (NORAD) website.

S20, eliminating satellites which cannot enter a radar detection range according to the orbit parameter information and the envelope region information of the radar detection range;

s30, establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range and a rough time interval passing through the detection range in a specified time period by using the satellite orbit prediction model and a preset pitch angle transit threshold;

and S40, determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope region information of the radar detection range.

In the embodiment, two lines of root information of the satellite is obtained, the satellite which cannot enter a radar detection range is removed, a satellite orbit prediction model is established, a time interval during which the satellite can enter the detection range is roughly screened, and then the time interval during which the satellite enters the detection range is accurately calculated; by adopting the method of combining the satellite which cannot enter the radar detection range with the twice screening, the time of the artificial satellite passing through the radar detection range and the view angle when the artificial satellite enters can be accurately and quickly forecasted, the calculation amount is small, the time consumption is short, an operator can quickly plan a task for the radar according to the result provided by the method, and the tracking task can be more effectively executed.

Optionally, in an embodiment, the rejecting satellites that are unlikely to enter the radar detection range according to the orbit parameter information and the envelope region information of the radar detection range includes: determining the minimum pitch angle of the envelope region according to the envelope region information of the radar detection range; and determining an orbit inclination angle in the orbit parameter information, and rejecting the satellite when the orbit inclination angle of the satellite is smaller than the minimum pitch angle of the envelope area.

Specifically, the radar is set to a longitude L₀Latitude B₀Height H₀. The specified detection range of the radar is as follows: with radar site O (L)₀,B₀,H₀) As a center, the maximum power distance R of the radar_LimitHLower limit of azimuth A_LimitLUpper limit of azimuth A_LimitHLower limit of pitch E_LimitLUpper limit of pitch E_LimitH. The above limits form an envelope region of the detection range of the radar, which can detect satellites whose orbit enters the envelope region.

The envelope region has five vertices, and the coordinates in the radar earth coordinate system are expressed in the form of (distance, azimuth, elevation), and the radar station is taken as the center P₀(0,0,0), vertex 1P₁(R_LimitH,A_LimitL,E_LimitL) Vertex 2P₂(R_LimitH,A_LimitL,E_LimitH) Vertex 3P₃(R_LimitH,A_LimitH,E_LimitL) Vertex 4P₄(R_LimitH,A_LimitH,E_LimitH)。

Five vertices P_n(n is 0,1,2,3,4) and the coordinate in the radar earth coordinate system is P_n(R_n,A_n,E_n) (ii) a Calculating the coordinate P of the five vertexes under the rectangular coordinate system of the geocentric space through coordinate change_n(X0_n,Y0_n,Z0_n) Counterclockwise rotation of the sidereal hour angle α along the Z-axis_GRotating the X axis to point to the connection line of the earth mass center and the spring minute point to obtain a coordinate P under the coordinate system_n(X1_n,Y1_n,Z1_n) Then converting the coordinate in the coordinate system into a polar coordinate P_n(R2_n,A2_n,E2_n) So as to obtain the pitch angle E2 of each vertex_nDetermining minimum pitch angle E2 in five vertexes_AreaMinThe minimum pitch angle of the envelope region.

Judging the minimum pitch angle E2 between the satellite orbit inclination angle i and the envelope area_AreaMinIf the following formula is satisfied, the artificial satellite is considered to be unable to enter the radar detection range, and the satellite is rejected.

i＜E2_AreaMin

In the embodiment, the minimum pitch angle of the envelope region is determined according to the envelope region information of the radar detection range; and then according to the relationship between the satellite orbit inclination angle and the minimum pitch angle of the envelope area, removing satellites which cannot enter the specified detection range of the satellite. The removed satellite cannot enter a radar detection range, and does not participate in subsequent calculation steps, so that the calculation amount and the calculation time are greatly reduced, and an operator can quickly acquire the satellite transit information.

The satellite orbit prediction model calculates the position of the satellite at any moment by using the orbit parameters analyzed in the first step. In this embodiment, the satellite orbit prediction models may include NORAD SGP4 (simplified conventional perturbation model) and SDP4 (simplified deep space perturbation model) satellite orbit models, where SGP4 applies to near earth objects (near earth targets) with an orbit period less than 225 minutes, and SDP4 applies to objects (deep space targets) away from the earth or with an orbit period greater than 225 minutes.

The satellite position calculated by the satellite orbit prediction model is converted into a radar station address O (L) after coordinate conversion₀,B₀,H₀) Outputting a distance azimuth pitch coordinate S under a radar geodetic coordinate system as a center_n(R_n,A_n,E_n)。

Optionally, in an embodiment, the predicting, by using the satellite orbit prediction model and a preset pitch angle transit threshold, satellites that may enter a radar detection range and a rough time interval that passes the detection range in a specified time period includes:

starting from the initial time of the designated time period until the end time, according to a first time interval T_GPerforming skip point calculation to obtain time sequences T (1), T (2), …, T (N), wherein T (n) is T (1) + (n-1) T_GN is 1,2,. cndot.n; first time interval T_GGenerally more than 1 minute is selected;

calculating the position coordinate S of the satellite in the radar earth coordinate system at the moment t (n) by using the satellite orbit prediction model_n(R_n,A_n,E_n) Wherein R is_nIs a distance, A_nIs an azimuth angle, E_nIs a pitch angle;

elevation angle E of satellite_nGreater than or equal to a preset pitch angle crossing threshold E_DoorDetermining that the satellite is likely to enter a radar detection range within a specified time period; wherein, a pitch angle crossing threshold E is preset_DoorLess than the lower pitch limit E of the envelope region_LimitLI.e. 0. ltoreq.E_Door≤E_LimitL；

And sequentially jumping to inquire whether the satellite meets the condition from the initial time to the end time of the specified time period, if the satellite does not meet the condition from the time t (k), the satellite meets the condition from the jumping point to the next time t (k +1), and the satellite does not meet the condition until the time t (m), wherein the value ranges of m and k are 1-N. At the moment, the starting time T of the possible entering of the satellite into the detection range is recorded_1StartT (k), end time T_1EndT (m). Since the starting time of the satellite entering the detection range accurately is between the time t (k) and the time t (k +1), the starting time is taken as t (k), so that the time of the satellite entering the detection range can be calculated more accurately in the next step. From the initial moment, jumping point inquiry to the termination moment in sequence, recording the time intervals of all satellites possibly passing through the radar detection range, wherein the time intervals are [ T ] in sequence_1Start,T_1End]，[T_2Start,T_2End]，…，[T_MStart,T_MEnd]. The starting time of the last time that the satellite possibly enters the radar detection range is T_MStartIf the satellite is still at time t (N)If the above condition is satisfied, the recording end time T is recorded_MEnd＝t(N)。

In the embodiment, the time sequences are acquired by selecting larger time intervals in the appointed time period, the satellite position coordinates of each time sequence are calculated by using the satellite orbit prediction model, satellites which possibly enter a radar detection range and a rough time interval which passes through the radar detection range are roughly screened according to the relation between the satellite position coordinates and the preset pitch angle transit threshold, the calculated amount is small, the consumed time is short, and an operator can conveniently and quickly acquire transit information of the satellites.

Optionally, in an embodiment, the determining, by using the satellite orbit prediction model, position coordinates of satellites in the coarse time interval, and determining, according to the position coordinates of the satellites and the envelope area information of the radar detection range, satellites that can enter the radar detection range and a precise time interval that passes through the detection range includes:

starting from the initial time of the coarse time interval until the end time, according to a second time interval T_QPerforming skip point calculation to obtain a time sequence tm (1), tm (2), …, tm (K), wherein tm (k) is tm (1) + (k-1) × T_QK is 1,2,. K; a second time interval T_QLess than said first time interval T_G(ii) a A second time interval T_QIt may be chosen to be a few seconds, for example 1 second;

calculating the position coordinate Sm of the satellite at the moment tm (k) in the radar earth coordinate system by using the satellite orbit prediction model_k(Rm_k,Am_k,Em_k) Wherein Rm_kIs a distance, Am_kIs the azimuth angle, Em_kIs a pitch angle;

when the position coordinate Sm_k(Rm_k,Am_k,Em_k) When the satellite is located in the range of the envelope area, determining that the satellite can enter a radar detection range; determining that the satellite will enter a radar detection range when the position coordinates satisfy the following condition:

Rm_k≤R_LimitH

A_LimitL≤Am_k≤A_LimitH

E_LimitL≤Em_k≤E_LimitH

wherein R is_LimitHFor the maximum power distance of the radar, A_LimitLAt the lower limit of orientation, A_LimitHIs an upper limit of azimuth, E_LimitLTo a lower limit of pitch, E_LimitHIs the upper limit of pitch;

and sequentially jumping to inquire whether the satellite meets the conditions from the initial time of the rough time interval to the end time, wherein the first jumping point time meeting the conditions is a second initial time, the last jumping point time meeting the conditions is a second termination time, and the precise time interval passing through the detection range is determined according to the second initial time and the second termination time of the satellite. And meanwhile, the view angle of the satellite entering the detection range can be obtained.

In the above embodiment, after rough screening, in each rough time interval, the time sequence is acquired by selecting a smaller time interval, the satellite position coordinates of each time sequence are calculated by using the satellite orbit prediction model, the satellite which can enter the radar detection range and the precise time interval which passes through the radar detection range are determined according to the satellite position coordinates and the envelope area information, the calculation amount is small, the consumed time is short, and an operator can quickly acquire the transit information of the satellite.

The method for forecasting the passing of the artificial satellite through the radar detection range provided by the embodiment of the invention is described in detail in the above with reference to fig. 1. The system for forecasting the passing of artificial satellites through the radar detection range provided by the embodiment of the invention is described in detail below with reference to fig. 2.

As shown in fig. 2, an embodiment of the present invention further provides a system for forecasting passing of a radar detection range by an artificial satellite, including: the system comprises a track parameter acquisition module, a pre-screening module, a rough screening module and a precise calculation module;

the orbit parameter acquisition module is used for acquiring the two-line root information of the satellite and analyzing the orbit parameter information according to the two-line root information of the satellite; the pre-screening module is used for eliminating satellites which cannot enter a radar detection range according to the orbit parameter information and the envelope area information of the radar detection range; the rough screening module is used for establishing a satellite orbit prediction model, and predicting satellites which possibly enter a radar detection range within a specified time period and a rough time interval passing the detection range by using the satellite orbit prediction model and a preset pitch angle transit threshold; and the precise calculation module is used for determining the position coordinates of the satellite in the rough time interval by using the satellite orbit prediction model, and determining the satellite which can enter the radar detection range, the precise time interval passing the detection range and the entering visual angle according to the position coordinates of the satellite and the envelope area information of the radar detection range.

In the embodiment, two lines of root information of the satellite is obtained, the satellite which cannot enter a radar detection range is removed, a satellite orbit prediction model is established, a time interval during which the satellite can enter the detection range is roughly screened, and then the time interval during which the satellite enters the detection range is accurately calculated; by adopting the method of combining the satellite which cannot enter the radar detection range with the twice screening, the time of the artificial satellite passing through the radar detection range and the view angle when the artificial satellite enters can be accurately and quickly forecasted, the calculation amount is small, the time consumption is short, an operator can quickly plan a task for the radar according to the result provided by the method, and the tracking task can be more effectively executed.

The embodiment of the invention also provides a computer-readable storage medium, which comprises instructions, and when the instructions are run on a computer, the instructions cause the computer to execute the method for forecasting the artificial satellite passing through the radar detection range, which is provided by the embodiment.

The embodiment of the invention also provides computer equipment which comprises a memory, a processor and a computer program which is stored on the memory and can run on the processor, wherein when the processor executes the program, the method for forecasting the artificial satellite passing through the radar detection range is realized.

It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described apparatuses and units may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, a division of a unit is merely a logical division, and an actual implementation may have another division, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed.

Units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment of the present invention.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, and can also be realized in a form of a software functional unit.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention essentially or partially contributes to the prior art, or all or part of the technical solution can be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.