KR20200010151A - Changeable Passive Relay, Controlling Server, and Operating Method thereof - Google Patents

Abstract

The present invention discloses a variable passive relay device, and a control server and method related to the operation thereof. The variable passive relay device is realized to be divided into a plurality of pieces to move the plurality of pieces to adjust the shape of s reflective surface, and also to adjust a direction of the reflective surface. The control server receives base station related information from a base station and passive relay device related information from a passive relay device, generates control information for determining a type and direction of the passive relay device based on the base station related information and the passive relay device related information, transmits the control information to the variable passive relay device or a terminal of a designated manager, and optimally adjust the shape and direction of the variable passive relay device.

Description

Variable passive relay device, control server for operating the same and its operation method {Changeable Passive Relay, Controlling Server, and Operating Method}

The present invention relates to a variable passive relay device capable of adjusting a radius of curvature and a reflection angle of a reflective surface in consideration of the positional relationship between a base station and a service area, a control server for operating the same, and a method of operating the same.

The ultra-high frequency (mmWave) band considered in 5G mobile communication system has strong straightness but weak diffraction and excessive path loss. Considering the characteristics of these frequencies, when providing a high frequency service in a city center, there is a problem that a large number of service shadows are generated by buildings and features. Accordingly, there is a need for an efficient solution for effectively improving service shadow areas.

In consideration of the above-mentioned service shadow area elimination, it is possible to consider a method of improving the generated shadow area by using a base station or an active repeater (amplifying received signal and radiating), and the base station or active repeater should be provided with a large number of active elements. In addition, the unit cost is relatively high because power is required for driving, and considering the required number in the 5G mobile communication network, it is difficult to apply because excessive cost is required to build both the base station and the active repeater.

Accordingly, a passive relay has been proposed in consideration of cost efficiency. Passive relays are simply relays that do not have an active element and simply reflect an incident signal at a particular angle of reflection.

Such a passive relay has an advantage of increasing the service area by extending the reflection angle by implementing the reflective surface as a convex surface, and the signal of the ultra-high frequency band to be used in the 5G mobile communication system has a strong straightness, so the effect of reflection is also increased. Since the beam width of the signal radiated from the base station is small enough, since the reflection area of the passive relay may be small, the construction cost of the relay system for eliminating the shadow area may be further reduced.

However, the existing passive relay has a fixed curvature of the reflective surface, which makes it difficult to install and operate the passive relay so that the shadow area and the reflective area to provide a service match.

Korean Patent Publication No. 10-2018-0047392, published May 10, 2018 (name: antenna device)

In order to solve the above-mentioned problem, the present invention provides a variable passive that can provide an improved service area based on an extended reflection angle by applying a curved reflection surface that reflects an incident signal at a predetermined reflection angle without applying active elements. The present invention provides a relay device, a control server for operating the same, and a method of operating the same.

In particular, the present invention can be implemented to adjust the curvature, direction and size of the reflective surface consisting of a curved surface, it can support to derive the optimum effect in consideration of the positional relationship between the base station and the service area to provide services The present invention provides a variable passive relay device, a control server for operating the same, and a method of operating the same.

The control server according to an embodiment of the present invention includes a server communication circuit capable of communicating with a base station and a variable passive relay device for relaying signals transmitted and received between the base station and the service area; And a server processor operatively connected to the server communication circuit.

In this case, the server processor receives base station related information and passive relay device related information from the variable passive relay device from the base station, and reflecting surface of the variable passive relay device based on the base station related information and the passive relay device related information. Generate control information to determine the shape and direction of the.

In addition, the server processor receives the base station related information including at least one of the latitude, longitude, altitude, beam width, output strength, the distance between the base station antenna and the variable passive relay device of the base station antenna, the variable passive relay device Receiving the related information about the passive relay device including at least one of latitude, longitude, altitude, location information of a service area, a distance between a service area and a variable passive relay device, and a size of a service area. Control information including information for adjusting at least one of a curvature, a diameter, and a direction of the slope may be generated.

In addition, the present invention discloses a variable passive relay device as another means for solving the above problems. The variable passive relay device according to the present invention includes a reflection surface assembly in which a plurality of reflection surface pieces are connected to form one reflection surface; A pillar portion fixing the reflective surface assembly; A steering device connected to the pillar portion; Assembly supports supporting the reflective surface assembly; Support adjusters for adjusting the shape of the reflective surface assembly by moving the plurality of reflective surface pieces; And a controller configured to control the steering apparatus and the support adjusting unit, wherein the controller is configured to adjust the support adjusting units according to control information calculated based on installation location information, service area information, and base station related information of the variable passive relay device. May be adjusted to change at least one of the curvature and the diameter of the reflecting surface assembly, or the steering apparatus may be controlled to change the direction the reflecting surface assembly is directed.

In addition, the variable passive relay device includes a communication circuit for receiving the base station related information from a base station; A memory for storing the base station related information; A display of an input device or an input function for receiving the base station related information; It may further include at least one of, and also supported to move to one side of the pillar portion, the support support to which the assembly supports are fixed; And a movement adjusting unit configured to adjust movement of the support moving unit on the pillar unit according to the controller control.

In another embodiment of the present disclosure, the variable passive relay device further includes a communication circuit, and the controller controls the variable passive relay device related information including current location information and service area information based on the communication circuit. And control information from the control server.

In addition, the present invention as another solution to the above problem, the base station-related information and the passive relay device related information for the variable passive relay device to be controlled; Generating control information indicating a form and direction adjustment of the variable passive relay device based on the base station related information and the passive relay device related information; It provides a variable passive relay device operating method comprising the step of transmitting the control information to the variable passive relay device or a designated manager terminal.

In the method, the base station-related information includes at least one of latitude, longitude, altitude, beam width, output strength, the distance between the base station antenna and the variable passive relay device of the base station antenna, the passive relay device related information And at least one of latitude, longitude, altitude, location information of a service area, a distance between a service area and a variable passive relay device, and a size of a service area of the variable passive relay device, wherein the control information is included in the variable passive relay device. It may include information for adjusting at least one of curvature, diameter, and direction for the reflective surface of the.

According to the present invention, at least one of the shape, size, and direction of the antenna curved surface of the passive relay device can be easily adjusted based on a calculated value, so that the passive relay device can be easily installed, and in addition, the passive relay device is installed. Optimizing the area of the service area extended by the variable passive relay device by deriving optimal control information (curvature, direction, size, etc.) of the variable passive relay in consideration of the position, service area, and relationship with the base station Can be easily achieved.

1 is a view showing an example of an operating environment of a variable passive relay device according to an embodiment of the present invention.
2 is a view functionally showing an example of the internal and external configuration of the variable passive relay device 100 according to an embodiment of the present invention, Figure 3 is an appearance of the variable passive relay device 100 according to an embodiment of the present invention It is a figure which shows an example.
4 is a view showing an example of a shape (curvature) deformation of the reflective surface assembly of the variable passive relay device 100 according to an embodiment of the present invention.
5 is a diagram illustrating an example of a first steering state of the variable passive relay device 100 according to an exemplary embodiment of the present invention.
6 is a diagram illustrating an example of a second steering state of the variable passive relay device 100 according to an exemplary embodiment of the present invention.
7 is a diagram illustrating another example of an operating environment of a variable passive relay device according to an exemplary embodiment of the present invention.
8 is a diagram illustrating a configuration example of a control server 200 according to an exemplary embodiment of the present invention.
9 is a diagram illustrating a control process of a variable passive relay device according to an embodiment of the present invention as a signal flow between components.
10 is a diagram illustrating an example of adjusting a service area of a variable antenna according to an exemplary embodiment of the present invention.
11A and 11B are diagrams for describing a principle of calculating control information of a passive relay device according to a relationship between a base station and a variable passive relay device according to an embodiment of the present invention.
12 is a diagram illustrating an example of a control process of a variable passive relay device according to an exemplary embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described with reference to the accompanying drawings. It is to be understood, however, that the intention is not to limit the invention to particular embodiments, but to cover various modifications, equivalents, and / or alternatives to the embodiments of the invention. In connection with the description of the drawings, similar reference numerals may be used for similar components.

1 is a view showing an example of an operating environment of a variable passive relay device according to an embodiment of the present invention.

Referring to FIG. 1, the variable passive relay device operating environment 10 is, for example, a base station 50 disposed on a first facility 11 and a variable passive relay device 100 disposed on a second facility 12. It may include. In the above description, the first facility 11 and the second facility 12 are removed according to the characteristics of the region in which the base station 50 and the variable passive relay device 100 are disposed, or other structures or nature other than the facility. It may be replaced by a feature. In addition, at least one of the base station 50 and the variable passive relay device 100 may be disposed in a predetermined region (for example, a natural feature such as a mountain) without being disposed on the facility.

The base station 50 may transmit or receive a signal related to the mobile communication service support of the user terminal. For example, the base station 50 may be disposed at the top of a certain facility or located at a portion relatively higher than a surrounding area such as a mountain to transmit and receive a signal. The base station 50 according to an embodiment of the present invention may transmit a signal of an ultra high frequency band corresponding to a 5G frequency band or receive a signal output by a user terminal. The base station 50 may be configured to transmit a signal in at least a designated direction or to receive a signal transmitted in a designated direction. Alternatively, the base station 50 may be configured to transmit and receive a signal in all directions.

The variable passive relay device 100 may serve as a passive relay with respect to the base station 50. The passive relay device 100 may be provided to freely set the correct reception direction of the transmission beam (Beam) of the base station 50 and the reflection direction for serving the shadow area according to the separation distance from the base station 50. . In this regard, the passive relay device 100 may include a direction characteristic (eg, position information (latitude, longitude, altitude), azimuth, and elevation angle), azimuth, and elevation angle of the antenna of the base station 50 and a signal output characteristic (eg, Information including the beamwidth, output, etc.) can be received from the base station 50. The passive relay device 100 receives the received direction characteristic and output characteristic information, its location information, the area of the service area, the direction of the service area, the distance from the service area, the received electric field strength to be provided to the service area, and the like. In consideration, at least one of the direction and shape (eg, size, curvature, diameter, shape) of the antenna may be adjusted. In this regard, the passive relay device 100 includes a reflecting surface assembly comprising a plurality of reflecting surface pieces connected to each other, based on modules capable of changing at least one of an appearance of the reflecting surface assembly and a direction of the reflecting surface assembly. The shape (curvature), size (diameter) and direction (vertical angle and horizontal angle) of the reflective surface can be adjusted.

2 is a view functionally showing an example of a configuration of a variable passive relay device 100 according to an embodiment of the present invention, Figure 3 is one of the appearance of the variable passive relay device 100 according to an embodiment of the present invention. An example is shown.

2 and 3, the variable passive relay device 100 according to an embodiment of the present invention includes a passive relay structure 150 having a structure capable of varying the shape, size, and direction of a reflective surface. In addition, it may include a communication circuit 110, a sensor 120, a display 130, a memory 140, a passive relay structure 150, and a controller 160. Additionally, the variable passive relay device 100 may further include a frame 101 surrounding the communication circuit 110, the sensor 120, the display 130, the memory 140, and the controller 160. . The frame 101 supports the passive relay structure 150 and protects internal components such as the communication circuit 110, the sensor 120, the display 130, the memory 140, and the controller 160. Can play a role. In addition, the above The passive relay device 100 may further include a cable that may be connected to a battery or a permanent power source for driving the communication circuit 110, the sensor 120, the display 130, the memory 140, and the controller 160. Can be.

For reference, the communication circuit 110, the sensor 120, the display 130, the memory 140, and the controller 160 may be implemented as an independent device from the passive relay structure 150, and then the variable passive relay ( When adjustment to one of the shape, size and direction of 100 is required, it may be connected to control the passive relay structure 150.

The communication circuit 110 may support a communication function to the variable passive relay device 100. The communication circuit 110 may be connected to the base station 50 or another external device in a wired or wireless manner, for example. In one embodiment of the present invention, the communication circuit 110 may receive the base station-related information from the base station 50 and transfer it to the memory 140 or the controller 160. Alternatively, the communication circuit 110 may receive information about the service area 13 that the variable passive relay device 100 needs to service from the base station 50. As various examples, the communication circuit 110 may support a 3G or 4G communication method that is independent of the communication method supported by the passive relay device 100, and in this case, the communication circuit 110 may be A separate wireless antenna may be additionally arranged to support the communication function. Accordingly, the communication circuit 110 in the passive relay device 100 of the present invention is a communication means capable of communicating with the base station 50 may not be limited in its manner and form.

The sensor 120 may include, for example, a GPS (Global Positioning System) module as a sensor capable of collecting location information. Alternatively, the sensor 120 may include at least one sensor capable of measuring latitude, longitude, and altitude, and a sensor capable of measuring a distance between the service area and the passive relay device 100. The sensor 120 may collect location information (latitude, longitude, altitude), distance information, etc. of the passive relay device 100 in response to the control of the controller 160, and transmit the collected location information to the controller 160. have. As another example, the variable passive relay device 100 may predetermine location information, distance information, and the like at a time point when the variable passive relay device 100 is installed in the second facility 12 or the like. Accordingly, location information related to the variable passive relay device 100 and distance information related to the service area may be input in advance by an administrator who installs the passive relay device 100. In this case, the sensor 120 may be omitted in the configuration of the variable passive relay device 100.

The display 130 may output at least one screen related to the operation of the variable passive relay device 100. For example, the display 130 may output the current location of the variable passive relay device 100, information on a base station, information on a service area, and the like. Alternatively, the display 130 may display current state information of the variable passive relay device 100, for example, direction information indicated by the passive relay structure 150 or current shape information of the reflective surface assembly 159. When the display 130 includes a touch function, the display 130 may operate as an input device. The display 130 may output an operation menu relating to steering or shape adjustment of the reflective surface assembly 159 of the passive relay structure 150. The administrator may manually adjust the direction and shape (eg, size, curvature, diameter, and shape) of the reflective surface assembly 159 through an operation menu output to the display 130.

The memory 140 may store various programs or driving algorithms related to the operation of the variable passive relay device 100. The memory 140 may store specification information related to the variable passive relay device 100. The memory 140 may provide information on the current state of the variable passive relay device 100 (eg, direction information toward the reflective surface assembly 159 and shape (curvature, radius of curvature, diameter, etc.) of the reflective surface assembly 159. Information can be stored. The memory 140 may include base station related information (eg, direction characteristic information of the base station 50, output characteristic information, distance information with the variable passive relay device 100), and information related to the variable passive relay device 100 ( For example, location information, service area related information) can be stored. The memory 140 may store a steering algorithm 152 driving algorithm, support adjuster 154 driving algorithm, and movement control unit 156 driving algorithm included in the passive relay structure 150.

The passive relay structure 150 includes a reflecting surface assembly 159, a pillar 151, a steering device 152, assembly supports 153, support adjustments 154, support movements 155, and movement control. It may include a portion 156.

The reflective surface assembly 159 may be arranged such that a plurality of reflective surface pieces are continuously connected. The reflective surface pieces may include, for example, two hypotenuses having a predetermined angle (eg, an acute angle) and having the same length and an arc connecting both ends of the hypotenuse, and the hypotenuse may be provided with a constant curvature. The hypotenuses forming the constant curvature may be connected to other adjacent reflecting surface pieces to form a part of a sphere, and the vertices of each reflecting surface piece may be disposed at the same point. Accordingly, the reflective surface assembly 159 may be in the form of a semi-spherical shape or a portion of the sphere is cut off. The same point where the reflecting surface pieces are disposed may correspond to the center point of the reflecting surface assembly 159. Of course, the shape of the reflective surface piece and the reflective surface assembly 159 may be variously modified without being limited thereto.

The pillar portion 151 may be provided in a cylindrical or polygonal pipe shape, one side may be fixed to a center point of the reflective surface assembly 159, and the other side may be fixed to the steering device 152. The length of the pillar portion 151 may be formed to have a length greater than or equal to the radius of the reflective surface assembly 159. The pillar part 151 may serve to fix a central portion of the reflective surface assembly 159.

The steering device 152 may adjust the direction in which the pillar portion 151 is directed. One side of the steering device 152 is fixed to the pillar portion 151, the pillar portion 151 is a first direction (for example horizontal direction or left and right direction) and a second direction (for example vertical direction or vertical direction) It may be provided to move in at least one of the direction. The steering apparatus 152 may include, for example, a fixed shaft to which the pillar part 151 is fixed, a rack gear capable of moving the fixed shaft in a first direction, and a curved bevel gear that can move the fixed shaft in a second direction. And the like. Alternatively, the steering device 152 may include various types of gears such as a sprocket and a straight bevel gear.

The assembly supports 153 may be connected and fixed to one end of each of the reflective surface pieces constituting the reflective surface assembly 159, and the other side may be connected and fixed to the support moving part 155. The assembly supports 153 may include, for example, an upper portion connected to the reflective surface assembly 159 and a lower portion connected to the support moving part 155. Support adjusters 154 may be disposed between the upper and lower portions of the assembly supports 153. The assembly supports 153 may be changed in position by the length variation of the support adjusting units 154.

The support adjusters 154 may be disposed between the assembly supports 153 and may vary in length in response to the control of the controller 160. For example, the assembly supports 153 may include a first screw portion that engages with the upper portion of the assembly supports 153 and a second screw portion that engages with the lower portion of the assembly supports 153 and the first screw portion. And an actuator disposed between the second screw part to adjust rotation of the first screw part and the second screw part. According to the adjustment of the actuator, as the overlapping area of the first screw portion and the second screw portion is changed, the overall length of the support adjusting portions 154 is changed, and thus, the center points of the assembly supports 153 are changed. As a reference, the separation distance between the upper and lower portions of the assembly supports 153 may be increased or decreased.

The support moving part 155 may be provided in a ring shape to surround the pillar part 151. One side of the support members 153 is fixed to the support moving part 153, and the position on the pillar part 151 may be adjusted according to the control of the movement adjusting part 156. A screw thread is provided inside the support moving part 155, and gears are provided at one side of the pillar part 151 to adjust the position on the pillar part 151 under the control of the movement adjusting part 156. For example, the support moving part 155 and the pillar part 151 are provided in the shape of a male thread and a female thread (or bolt and nut shape), and the support moving part 155 under the control of the movement adjusting unit 156. While rotating, the position on the pillar portion 151 may be adjusted.

The movement adjusting part 156 may adjust the position of the support moving part 155 on the pillar part 151. For example, when the support moving part 155 is provided in the shape of a nut, the movement adjusting part 156 includes a rotating actuator capable of rotating the support moving part 155, and under the control of the controller 160. The position of the support moving unit 155 may be shifted. Alternatively, the movement adjusting part 156 is fixed to one side of the support moving part 155 which may push the support moving part 155 toward the center point of the reflective surface assembly 159 or pull toward the steering device 152. And a gear structure or an actuator capable of adjusting the length of the adjuster to adjust the position on the pillar portion 151 of the support moving part 155.

In one embodiment of the present invention, the passive relay structure 150 configured as described above, the manager manipulates the movement control unit 156 and the steering device 152 by hand, the shape (size, curvature, Diameter, shape, etc.). At this time, the manager can manipulate the passive relay structure 150 with reference to the control information provided by the method according to the invention.

Meanwhile, in another embodiment of the present invention, the passive relay structure 150 may be automatically controlled by the controller 160.

To this end, the controller 160, through the communication circuit 110, the relevant information of the base station 50 (for example, direction characteristic information, output characteristic information, the distance information between the variable passive relay device 100 and the base station 50) Etc.) can be obtained. Alternatively, the controller 160 may obtain base station related information previously stored in the memory 140. Alternatively, when the variable passive relay device 100 further includes an input device, the controller 160 may obtain base station related information input by an administrator based on the input device or the display 130 of the input function. . The controller 160 may obtain location information and / or service area related information of the variable passive relay device 100 through the memory 140 or through an input device. Alternatively, the controller 160 may obtain location information or service area related information of the passive relay device 100 using the sensor 120 described above.

When the controller 160 obtains the base station related information and the passive relay device related information, the controller 160 may determine the shape (eg, size, curvature, diameter, shape) and the direction (horizontal angle and shape) of the variable passive relay device 100 based on the information. Control information for determining the vertical angle, etc.). For example, the controller 160 determines the direction in which the passive relay device 100 should face the base station 50 based on the location information of the base station 50 and the location information of the passive relay device 100. Can be generated. In addition, the controller 160 determines the direction in which the passive relay device 100 can reflect the signal transmitted from the base station 50 to the service area based on the location information of the base station 50 and the information on the service area. Control information can be generated. The controller 160 may generate control information for determining the unfolding size of the reflective surface assembly 159 of the passive relay device 100 according to the size of the service area. Alternatively, the controller 160 may use a reflection surface assembly capable of achieving a received electric field strength to be provided to the service area based on the output characteristics of the base station 50 and the distance information between the service area and the passive relay device 100. Control information for determining a shape (eg, size, curvature, diameter, shape) and a direction of the display device 159 may be generated. The passive relay device 100 may store and manage a lookup table including direction and shape information of the passive relay device 100 corresponding to each condition in the memory 140. In this case, the controller 160 checks the lookup table stored in the memory 140 to obtain control information including a direction and a shape corresponding to the base station related information and the passive relay device related information, and obtains the obtained direction and shape. According to the control information to be included, it is possible to determine the direction (eg, size, curvature, diameter, shape) of the reflective surface assembly 159 and the direction in which the variable passive relay device 100 will face. The control information may include at least one of the separation distance from the base station, the beam width of the base station, the output of the base station, the separation distance from the service area, the size of the service area, and the received field strength to be provided to the service area (or the above factors may be combined. Information to adjust the direction and shape of the reflective surface assembly 159 according to the optimized value).

When the controller 160 obtains direction and shape information of the variable passive relay device 100, the controller 160 may control the passive relay structure 150 to adjust the direction and shape of the reflective surface assembly 159. For example, the controller 160 may adjust the directing direction of the reflective surface assembly 159 to correspond to the directing direction information obtained by controlling the steering apparatus 152. In addition, the controller 160 may adjust the shape of the reflective surface assembly 159 using the support adjusters 154 and the movement adjuster 156.

As described above, the variable passive relay device 100 of the present invention reflects a signal of the base station 50 to a service area without a separate active element, and thus, an installation position, a service providing area, and a base station of the passive relay device 100. The direction and shape can be optimized according to the distance from the (50) and the service providing area.

As described above, the variable-type passive relay device 100 may have a structure such as a flat fan by dividing the circular reflector at predetermined intervals, and may adjust a radius of curvature of the circular reflector to form a desired curved reflection area.

In the above description, the controller 160 of the variable passive relay device 100 calculates the shape and direction of the variable passive relay device 100, but the present invention is not limited thereto. For example, after acquiring passive relay device related information from a base station control device (not shown) included in the base station 50, the passive relay device 100 may be calculated by calculating the shape and direction information of the variable passive relay device 100. Can also be provided to. In this case, the controller 160 included in the variable passive relay device 100 may perform shape adjustment and direction adjustment of the reflective surface assembly 159 according to the received shape and direction information.

4 is a view showing an example of a state variation of the reflective surface assembly 159 of the variable passive relay device 100 according to an embodiment of the present invention.

Referring to FIG. 4, the variable passive relay device 100 according to an exemplary embodiment of the present invention may include a frame 101 in which the controller 160 is embedded, a steering device 152 connected to the frame 101, and a steering device ( A pillar portion 151 connected to the 152, a reflective surface assembly 159 fixed to the end of the pillar portion 151, the assembly supports 153 and the support adjusters for adjusting the shape of the reflective surface assembly 159 154 may include.

For example, when the controller 160 of the passive relay device 100 obtains information determined that the reflective surface assembly 159 has a relatively wider reflective surface than the previous state, the controller 160 adjusts the support adjusters 154. It can be controlled to increase the overall length of the assembly supports 153 and the support adjustments 154. For example, the controller 160 controls the length of the support adjusters 154 to be extended so that the distance between the end of the reflecting surface assembly 159 and the pillar 151 relative to the support mover 155 is increased. You can go far. At this time, since the central portion of the reflective surface assembly 159 is fixed to the end of the pillar portion 151, the reflective surface assembly 159 is wider than the previous state in response to the elongation of the support adjusting portions 154. Can have state. For example, the curvature of the reflective surface assembly 159 can be small. Alternatively, the curvature from the center to the edge of the reflective surface assembly 159 may be changed more gently than in the previous state. When one surface angle formed by the vertex of the curved surface of the reflective surface assembly 159 of FIG. 2 is formed at an angle based on the illustrated figure, the reflective surface assembly 159 of FIG. The angle at one surface of the vertex of the curved surface may be formed at a b angle greater than the a angle.

Meanwhile, in the above description, the length of the support adjusting units 154 is changed to change the shape of the reflecting surface assembly 159 in the case where the support adjusting units 154 are implemented as a structure that can be expanded or reduced. However, the present invention is not limited thereto. For example, the passive relay structure 150 may include support holders 155 and support holders 154 to which separate support holders 154 may be removed, and assembly supporters 153 and the assembly supporters 153 may be fixed. It may also include only the movement control unit 156 to move the 155. In this case, the controller 160 may control the movement adjusting unit 156 to adjust the position of the support moving unit 155 on the pillar part 151. For example, the controller 160 may adjust the position of the support moving unit 155 to change the curvature of the reflective surface assembly 159. In order to increase the curvature of the reflective surface assembly 159 than before, the controller 160 moves the support moving part 155 to the direction in which the pillar 151 and the center point of the reflective surface assembly 159 are combined (or the reflective surface). In the direction of the center point of the assembly 159, or in the direction of the -X axis. The controller 160 may move the support moving part 155 in a direction away from the center point of the reflecting surface assembly 159 (for example, in the X-axis direction) to make the curvature of the reflecting surface assembly 159 larger than before. have. The extension length or reduction length of the support adjusting portions 154, the position on the pillar portion 151 of the support moving portion 155 may be determined according to the magnitude of curvature that the reflective surface assembly 159 should have. . The length of the support adjusting units 154 or the position information of the support moving unit 155 may be pre-stored in the memory 140 according to the curvature of the reflecting surface assembly 159. Accordingly, when the curvature of the reflecting surface assembly 159 is determined, the controller 160 determines the length of the support adjusting units 154 and the length of the support moving unit 155 based on information previously stored in the memory 140. At least one of the positions can be adjusted. In some cases, the controller 160 may simultaneously adjust the length of the support adjusting units 154 and the position of the support moving unit 155.

5 and 6 are views for explaining a direction control state of the variable passive relay device 100 according to an embodiment of the present invention.

5 is a diagram illustrating an example of a first steering state of the passive relay device 100 according to an embodiment of the present invention.

Referring to FIG. 5, the passive relay device 100 according to an embodiment of the present invention may include a frame 101, a steering device 152 connected to the frame 101, a pillar portion 151 connected to the steering device 152, and It may include a passive relay structure 150 connected to the pillar portion 151.

If the direction of the passive relay device 100 is determined, the controller 160 embedded in the frame 101 may control the steering device 152 to have a first steering state. For example, the controller 160 controls the steering device 152 so that the passive relay structure 150 of the passive relay device 100 moves in the vertical direction (or Z-axis or -Z-axis direction) with respect to the ground. It can be controlled to rotate. In the figure, the controller 160 controls the steering device 152 to control the passive relay structure 150 to face in a direction forming a predetermined angle with the ground.

Even in this state, as described above with reference to FIG. 4, the controller 160 may adjust the shape (eg, size, curvature, diameter, and shape) of the reflective surface assembly of the passive relay structure 150.

6 is a diagram illustrating an example of a second steering state of the variable passive relay device 100 according to an exemplary embodiment of the present invention.

Referring to FIG. 6, the variable passive relay device 100 according to an exemplary embodiment may include a frame 101, a steering device 152 connected to the frame 101, and a pillar 151 connected to the steering device 152. It may include a passive relay structure 150 connected to the pillar portion 151.

When the direction of the passive relay device 100 is determined, the controller 160 embedded in the frame 101 may control the steering device 152 to have a second steering state. For example, the controller 160 controls the steering device 152 so that the passive relay structure 150 of the passive relay device 100 is in a left-right direction (or Y-axis direction or -Y-axis direction) based on a vertical plane. It can be controlled to rotate. In the drawing, the controller 160 controls the steering device 152 to show the passive relay structure 150 rotated by a predetermined angle in the right direction with respect to the vertical plane. Even in this state, as described above with reference to FIG. 4, the controller 160 may adjust the reflection surface assembly shape of the passive relay structure 150.

As described above with reference to FIGS. 5 and 6, the passive relay device 100 controls the steering device 152 to which the pillar part 151 is fixed so that the passive relay structure 150 has a predetermined angle (vertical direction). Angle) and control the steering device 152 so that the passive relay structure 150 is in one direction having a predetermined angle (horizontal angle) in left and right directions. Can be controlled to be directed. Accordingly, when the location and the service area of the base station 50 are determined, the passive relay device 100 can be easily adjusted to face the direction in which the passive relay device 100 should be directed. In addition, the passive relay device 100 of the present invention can change the curvature of the reflective surface assembly 159, thereby the size of the service area and the distance from the base station, the output characteristics of the base station 50, the distance from the service area, It is possible to provide a reflecting surface assembly state having a curvature optimized for a received electric field strength to be provided to the service area.

7 is a view showing another example of the operating environment of the variable passive relay device 100 according to an embodiment of the present invention.

Referring to FIG. 7, the variable passive relay operating environment 20 according to another embodiment of the present invention is disposed on, for example, the base station 50 and the second facility 22 disposed on the first facility 21. The variable passive relay device 100, the control server 200 may be included. In the above description, the first facility 21 and the second facility 22 may correspond to the first facility and the second facility described above with reference to FIG. 1.

As described above with reference to FIG. 1, the base station 50 may be disposed in the first facility 21 or the like and transmit or receive a communication service related signal in one direction or omnidirectional. The base station 50 may transmit / receive an ultra high frequency signal according to, for example, a 5G communication method. The base station 50 may transmit a communication signal, for example, in a direction in which the variable passive relay device 100 is disposed. The base station 50 according to another embodiment of the present invention may be connected to the control server 200. For example, the base station 50 may be connected to the control server 200 through at least one of a wired communication cable or a wireless communication method. The base station 50 may transmit base station related information to the control server 200. When the direction characteristic or the output characteristic is changed, the base station 50 may transmit the changed base station related information to the control server 200 in real time.

The variable passive relay device 100 may include a frame, a steering device, a pillar portion, and a passive relay structure as described above with reference to FIGS. 2 and 3. The passive relay device 100 may include a communication circuit and may be connected to the control server 200. The variable passive relay device 100 may transmit related information, for example, location information of the variable passive relay device 100, service area 23 information, and the like to the control server 200. The variable passive relay device 100 may receive control information regarding a direction and a form from the control server 200. Such passive relay device-related information may be controlled according to a manager operation or scheduled information and control of the controller 160 at the time when the passive relay device 100 is first connected to the control server 200 after being installed on the second facility 22. According to the control server 200 can be delivered. When the variable passive relay device 100 receives the control information regarding the direction and the form from the control server 200, the passive relay structure 150 is directed while pointing the designated direction according to the received control information about the direction and the form. It may be adjusted to have a shape (eg, size, curvature, diameter, shape) (or the reflecting surface assembly 159 may be adjusted to have a specified curvature or diameter). For example, the control information may include information for increasing (or decreasing) the curvature of the reflective surface assembly or setting the radius of curvature (or larger) as the service area is larger (or smaller). Alternatively, the information may include setting (or setting) at least one of a curvature and a diameter of the reflective surface assembly to maintain the received electric field strength of the target service area. For example, assuming that the strength of the signal transmitted from the base station 50 is constant, the signal arriving from the base station 50 to the service area 23 through the variable passive relay device 100 is proportional to the transmission distance thereof. It becomes smaller. In addition, as the reflection angle in the variable passive relay device 100 increases, that is, as the curvature increases, the size of the service area 23 through which the reflected signal arrives increases, and at this time, toward the edge of the service area 23. The longer the transmission distance of the signal, the more the signal size can be attenuated. Accordingly, the size of the service area 23 may be further determined to receive a signal having a proper size in consideration of the strength of the signal transmitted from the base station 50 and the transmission distance of the signal.

As another example, the control information may increase the curvature of the reflective surface assembly as the distance between the passive relay device 100 and the service area or the separation distance between the base station 50 and the passive relay device 100 increases. It may include setting information for reducing the curvature of the assembly. The control information may include at least one of a size of the service area and a target received electric field strength, a distance between the base station 50 and the passive relay device 100, and a distance between the passive relay device 100 and the service area. As such, information optimized by applying a trade-off of the shape (or size, shape, curvature or radius of curvature, etc.) of the reflective surface assembly may be included.

The control server 200 may establish a communication channel with the base station 50 and the passive relay device 100. For example, the control server 200 may be connected to the base station 50 and the passive relay device 100 in at least one of wired and wireless communication methods. The control server 200 from the base station 50, the base station-related information (for example, direction characteristic information of the base station (location information (latitude, longitude, altitude) of the base station 50), antenna direction information of the base station 50) Output characteristic information (beam width, output, etc.) of the base station 50 can be received. In addition, the control server 200 may collect variable antenna-related information (eg, position information (latitude, longitude, altitude) of the variable antenna, position and shape information of the service area 23) from the passive relay device 100. Can be. The control server 200 may generate control information for determining the direction and the shape of the passive relay device 100 based on the collected information, and transmit the generated control information to the passive relay device 100. The control server 200 may include a configuration as shown in FIG.

8 is a diagram illustrating an example of a control server 200 according to an exemplary embodiment of the present invention.

Referring to FIG. 8, the control server 200 of the present invention may include a server communication circuit 210, a server memory 240, and a server processor 260.

The server communication circuit 210 may form a communication channel with the base station 50 and the passive relay device 100. The server communication circuit 210 may form a communication channel with the base station 50 based on a communication method operated by the base station 50 and the variable passive relay device 100, for example, a 5G communication method. Alternatively, the server communication circuit 210 may be a base station 50 or a passive relay based on another communication method installed in the base station 50 or the variable passive relay device 100, for example, a wired communication method or a communication method such as 3G or 4G. A communication channel can also be established with the device 100. The server communication circuit 210 may receive base station related information from the base station 50 under the control of the server processor 260, and receive passive relay device related information from the variable passive relay device 100. As another example, the server communication circuit 210 may provide a virtual web page operated by the control server 200 to the manager terminal. The virtual web page may provide an input user interface (UI) for inputting information related to the base station 50 and the variable passive relay device 100. Accordingly, the manager may access the control server 200 through the manager terminal and process information input related to the base station 50 and the variable passive relay device 100 through the virtual web page. The server communication circuit 210 may temporarily or semi-permanently store the received information related to the base station 50 and the variable passive relay device 100 in the server memory 240.

The server memory 240 may store at least one program, operating system, data, etc. related to the operation of the control server 200. For example, the server memory 240 may store the base station related information received from the base station 50 and the passive relay device related information received from the passive relay device 100. In addition, the server memory 240 may store the passive relay device control information generated based on the base station related information and the passive relay device related information. As another example, the server memory 240 may store the virtual web page information and store base station related information and passive relay device related information according to an administrator input. The server memory 240 may store various algorithms for calculating optimized control information based on base station related information and passive relay device related information. For example, the server memory 240 should be directed by the passive relay device 100 based on the location information of the base station 50, the location information of the passive relay device 100, the service area size and location information of the passive relay device 100, and the like. Algorithms for calculating the direction to the direction and algorithms for calculating the shape of the reflective surface assembly 159 may be stored. Alternatively, the server memory 240 may be directed by the passive relay device 100 according to location information of the base station 50, location information of the passive relay device 100, service area size and location information of the passive relay device 100. It may include a database that includes the orientation information and the shape information of the reflective surface assembly 159.

The server processor 260 may control the server communication circuit 210 to form a communication channel with the base station 50 and the passive relay device 100 in response to the designated scheduling information. For example, when the new base station 50 is installed, the server processor 260 establishes a communication channel with the base station 50 according to the request of the base station 50 or under the control of the administrator of the control server 200, and provides the base station related information. You can request In addition, the server processor 260 may obtain base station-related information about the base stations 50 registered at regular intervals and check and update the changed information. In addition, when the passive relay device 100 is installed, the server processor 260 forms a communication channel with the passive relay device 100 according to the request of the passive relay device 100 or under administrator control, and the passive relay device related information. Can be obtained.

The server processor 260 may generate control information of the passive relay device 100 based on the base station related information and the passive relay device related information stored in the server memory 240. The control information includes, for example, direction information to be directed by the passive relay device 100 and shape information (eg, size, curvature, radius of curvature, and shape information) of the reflective surface assembly 159 of the passive relay device 100. can do. When generating the control information, the server processor 260 generates control information of the passive relay device 100 using a calculation algorithm stored in the server memory 240 or controls mapped to base station related information and passive relay device related information. One of the information may be selected as control information to be provided to the passive relay device 100. For example, in the process of determining the direction and shape adjustment of the passive relay device 100, the server processor 260 may determine a distance between the passive relay device 100 and the base station 50, and position information of the base station or base station antenna ( Latitude, longitude, altitude), base station-related information including the azimuth angle of the base station 50, the altitude angle of the base station 50, the beamwidth of the base station 50, the output of the base station 50, and the like, and the passive relay device 100. The radius of curvature and diameter of the passive relay device 100 is calculated in consideration of the position information (latitude, longitude, altitude) of the device, the distance from the passive relay device 100 to the service area, the received electric field strength to be provided to the service area, and the like. In addition, the control area may be generated by calculating the service area area and deriving an optimal signal (eg, a relay signal) incident direction and a reflection direction. When the control information is generated, the server processor 260 may transfer the generated control information to the passive relay device 100 in a wireless or wired manner. Alternatively, the server processor 260 may provide the control terminal with the request for the control information. In this case, the manager may manually adjust the direction and shape of the passive relay device 100 based on the control information received by the manager terminal. Alternatively, the manager terminal transmits the received control information to the passive relay device 100 in a wired or wireless manner, and the controller 160 of the passive relay device 100 automatically reflects the reflective surface assembly 159 based on the received control information. ) Can be adjusted the direction and shape of the.

9 is a diagram illustrating an example of a signal flow between components of a passive relay device operating system according to an exemplary embodiment of the present invention.

Referring to FIG. 9, in operation 901, the base station 50 may transmit base station related information to the control server 200 in relation to the operation of the passive relay device operating system. In addition, the passive relay device 100 may transmit the passive relay device related information to the control server 200. Here, the time points at which the base station 50 and the variable passive relay device 100 transmit information to the control server 200 may be the same or different. For example, when the base station 50 and the variable passive relay device 100 are installed, the base station 50 and the variable passive relay device 100 may transmit the base station related information or the variable passive relay device related information to the control server 200. Since the installation time points of the base station 50 and the variable passive relay device 100 may be the same or different, the transmission time of the related information may also be the same or different. The base station related information may include location information (latitude, longitude, altitude), azimuth, altitude, beamwidth, output, and the like of the base station antenna. The passive relay device related information may include information such as location information (latitude, longitude, altitude) of the passive relay structure 150, a distance to a service area, and a received electric field strength to be provided.

In operation 903, the control server 200 may generate control information related to the adjustment of the passive relay structure 150 of the passive relay device 100 based on the received base station related information and the passive relay device related information. For example, the control server 200 calculates the radius of curvature and the radius of the passive relay structure 150 (or passive relay device) that can be optimized for the received electric field strength and the service area area of the service area, the passive relay structure 150 The incidence angle and the reflection angle of the passive relay signal with respect to can be calculated. As the control information calculation condition, the reception field strength of the service area may be set to the highest condition, and the service area area may be set to the widest possible condition.

In operation 905, the control server 200 may provide control information (eg, curvature information and diameter information of the passive relay device 100, incident angle and reflection angle information, etc.) to the passive relay device 100. In operation 907, the passive relay device 100 controls at least one of a curvature / curvature radius, a diameter, a size, and a shape of the reflective surface assembly 159 according to the received control information to form the reflective surface assembly 159. Control the steering device 152 to adjust the direction of the reflection surface assembly 159 that satisfies the incident angle and the reflection angle of the relay signal.

The variable passive relay device 100 of the present invention as described above may have a reflective structure composed of a plurality of flat surfaces having a fan shape for adjusting a curved reflective area. As various examples, location information (latitude, longitude, altitude) of the base station, azimuth, altitude, beam width, output, etc., location information (latitude, longitude, altitude) of the variable passive relay device 100, distance information to a service area Etc. may be collected by at least one of the variable passive relay device 100 or the base station 50 as well as the control server 200, and may use the collected information to calculate an optimal area of the service area and a received electric field strength. . The control server 200 and the base station 50 include calculating the curvature radius, the diameter of the reflective surface assembly 159 and the control information including the signal incidence direction and the signal reflection direction information to match the calculated service area optimum area and the received electric field strength. ) Or the passive relay device 100, and based on the control information, the form (eg, at least one of size, curvature, diameter, and shape) and the direction of the variable passive relay device 100 may be controlled. have.

10 is a diagram illustrating an example of a modification of a service area of a variable antenna according to an exemplary embodiment of the present invention.

Referring to FIG. 10, referring to a state 1001, the passive relay device 100 may be configured such that the reflective surface assembly 159 has a first shape (eg, a first curvature, a first diameter, and a first service area 1010). It may have a size that can take charge of the size, and may be adjusted to face a first direction (eg, a direction toward the first service area 1010). The first shape and the first direction of the variable passive relay device 100 may be calculated by the installation position and the size and direction of the first service area 1010 at the installation position of the passive relay device 100.

Referring to the 1003 state, the passive relay device 100 has a second shape (eg, a second curvature smaller than the first curvature) in which the reflective surface assembly 159 is different from the first shape, and the second direction (Eg, the direction in which the second service area 1020 is directed).

When the beam width of the signal transmitted from the base station 50 is constant, the smaller the curvature, the smaller the size of the service area 1020 as in the 1003 state.

The second form and the second direction of the variable passive relay device 100 may be calculated by the installation position and the distance and distance of the second service area 1020 at the installation position of the variable passive relay device 100.

As described above, the variable passive relay device 100 according to the embodiment of the present invention may cover a signal transmitted by the base station 50 or transmitted by user terminals through the shape and direction adjustment of the passive relay structure 150. It can be provided to easily or automatically adjust the direction and size of the service area can be manually or manually. The present invention can effectively improve the shaded area in an environment where a plurality of service shadowed areas by a building or a feature may occur when providing a communication service through a plurality of base stations in a city center based on a signal of an ultra-high frequency band. While providing the variable passive relay device 100 is provided, it is possible to calculate the required radius of curvature and direction of the variable passive relay device 100 to be variable, and also to calculate the incident direction and the reflection direction of the signal sent to the base station It supports to change the form and direction of the variable passive relay device 100 automatically or manually. The present invention can automatically perform the setting of the variable passive relay device 100 can be a very useful and efficient way to optimize the installation and operation.

11A and 11B are diagrams for describing an example of calculating control information of a variable relay device according to a relationship between a base station and a variable passive relay device according to an embodiment of the present invention.

11A and 11B, the illustrated environment is, for example, a distance of 140m from the base station to the passive relay device, a distance of 80m from the center point of the passive relay device to the service point, and the base station effective isotropic radiated power (EIRP) is 56 dBm, the passive relay. If the curvature radius of the device is set to 1.569m, the received power per m squared of service area is -103.6dBm, and the received power of the service diameter (approximately 25.82m) is -76.4dBm (service area is 3.14 * (25.82) /2)^2=523.338 sq m), passive relay device reflection loss is 5dB, the difference between passive relay device angle of incidence and base station beamwidth is 16.9dB, pathloss is 110.5dB by total distance, and total loss is 132.4 when passive reflector is applied. can be dB. Here, the frequency band is 28 GHz, the horizontal beam width of one base station equipment beam may be set to 10 degrees. And, if the variable passive relay device diameter is 0.5m, the passive relay device curvature radius is 1.569m, the angle a is 0.1 degrees, the distance b is 140.74m, the angle d is 80.83 degrees, the variable passive relay device reflection angle may be 18.34 degrees. . If the distance from the center of the passive relay device to the service area is 80 m and the angle g is 9.17 degrees, the service diameter i may be 25.82 m. Accordingly, the service area may be 523.338 square meters as described above.

On the contrary, the service diameter, the received power per unit area, the distance from the base station to the passive relay device, the distance from the center point of the passive relay device to the service point may be determined, and the reflection angle and curvature radius of the passive relay device may be calculated.

Among the various conditions for installing the variable passive relay device, for example, the location of the base station, the location of the variable passive relay device, the distance between the base station and the passive relay device, the height of the variable passive relay device (or the distance from the passive relay device to the service area) ), The beam width, and the beam intensity may be fixed values. Accordingly, the area, incident angle and reflection angle (angle (horizontal angle and vertical angle) of the variable passive relay device) and curvature (or radius of curvature) of the service area among the various conditions for installing the passive relay device can be adjusted. With regard to the shape and direction of the passive relay device, the control server can determine the variable service coverage area, angle of incidence and angle of reflection and curvature (or radius of curvature), and correspondingly determine the angle of the passive relay device.

The control server 200 may adjust the curvature and the direction of the reflective surface such that the larger the desired service area, the larger the reflection angle, and the smaller the service area, the smaller the reflection angle, in relation to the control of the variable passive relay device 100. . In addition, by adjusting the curvature and the direction of the reflective surface such that the smaller the distance between the variable passive relay device 100 and the service area when the desired service area size is the same, the larger the reflection angle, the smaller the reflection angle, The variable passive relay device 100 may be installed to optimize the desired service area.

In addition, when the beam width transmitted from the base station 50 is fixed, the control server 200 greatly increases the reflection angle of the variable passive relay device 100 according to the distance between the base station 50 and the variable passive relay device 100. It is possible to control the radius of curvature and the direction of the reflecting surface so as to (or small).

In addition, since the beam output of the base station affects the strength of the signal reaching the service area, the control server adjusts the reflection angle of the passive relay device according to the size of the beam output or the beam of the base station according to the reflection angle of the passive relay device. The output can be adjusted. When the beam output is fixed, the reflection angle of the passive relay device may be adjusted according to the strength of the signal reaching the actual service area (for example, the strength set to fall within an appropriate range).

As described above, the shape and direction control of the variable passive relay device 100 may be performed by the control server 200, and may be transferred to the variable passive relay device 100 to be automatically performed. Alternatively, the control server 200 may transmit control information related to the shape and direction control of the variable passive relay device 100 to a designated manager terminal (not shown). In this case, the administrator may manually adjust the shape and direction of the passive relay device according to the shape of the variable passive relay device 100 (reflection angle of the passive relay device) and the direction control information displayed on the terminal.

12 is a diagram illustrating an example of a method of controlling a variable passive relay device according to an exemplary embodiment of the present invention.

Referring to FIG. 12, in step 1201, a control server 200 (or a base station 50 or a variable passive relay device 100, including a memory and a processor) may be collected and base station related information and passive relay device related information may be collected. The device may collect base station related information and passive relay device related information.

In operation 1203, the control server 200 may generate control information instructing the shape and direction adjustment of the variable passive relay device 100 based on the base station related information and the passive relay device related information. For example, the control server 200 sets a larger reflection angle of the passive relay device 100 as the distance between the base station and the variable passive relay device 100 increases, and increases the distance between the variable passive relay device 100 and the service area. The farther the reflection angle of the variable passive relay device is set, the greater the size of the service area, and the control information (grain, diameter, direction (horizontal direction angle / vertical direction angle)) may be set so that the reflection angle of the passive relay device becomes larger.

In step 1205, the control server transmits the control information to the variable passive relay device 100 to control to automatically adjust the shape and direction of the passive relay device, or transmits the control information to an administrator terminal (not shown) By doing so, it is possible to control to manually adjust the shape and direction of the variable passive relay device 100.

Embodiments disclosed in the above-described document are presented for the purpose of explanation and understanding of the disclosed, technical contents, and do not limit the scope of the present invention. Therefore, the scope of the present disclosure should be construed to include all changes or various other embodiments based on the technical spirit of the present disclosure.

FIELD OF THE INVENTION The present invention applies to the field of communications and, in particular, relates to antenna devices that perform passive relay devices on base station signals.

In particular, the present invention enables to automatically or manually adjust the shape and direction of the reflective surface assembly of the passive relay device, thereby easily and quickly optimizing the shape and direction of the passive relay structure with respect to the size of the target service area and the received field strength. can do.

50: base station
100: passive relay device
110: communication circuit
120: sensor
130: display
140: memory
150: passive relay structure
151: pillar
152: steering device
153: assembly supports
154: support adjustments
155: support moving part
156: movement control unit
159: reflective surface assembly
160: controller
200: control server
210: server communication circuit
240: server memory
260: server processor

Claims (10)

Server communication circuitry capable of communicating with a base station and a variable passive relay device for relaying signals transmitted and received between the base station and a service area;
A server processor operatively connected to the server communication circuitry;
The server processor
Receiving base station related information and passive relay device related information from the variable passive relay device from the base station,
And control information for determining at least one of a shape and a direction of a reflection surface of the variable passive relay device based on the base station related information, the passive relay device related information, and the service area information. The method of claim 1,
The server processor
Receiving the base station related information including at least one of latitude, longitude, altitude, beam width, output strength, and the distance between the base station antenna and the variable passive relay device of the base station antenna,
A control server configured to receive the passive relay device related information including at least one of latitude, longitude, altitude, location information of a service area, a distance between a service area and a variable passive relay device, and a size of a service area of the variable passive relay device; . The method of claim 1,
And the control information includes information for adjusting at least one of curvature, diameter, and direction of a reflective surface of the variable passive relay device. A reflection surface assembly in which a plurality of reflection surface pieces are connected to form one reflection surface;
A pillar portion fixing the reflective surface assembly;
A steering device connected to the pillar portion;
Assembly supports supporting the reflective surface assembly;
Support adjusters for adjusting the shape of the reflective surface assembly by moving the plurality of reflective surface pieces;
And a controller for controlling the steering device and the support adjusters.
The controller
Variable passive relay device for changing at least one of the shape and the direction of the reflection surface assembly by adjusting the support adjusters according to the control information calculated based on the installation location information, the service area information, the base station related information of the variable passive relay device . The method of claim 4, wherein
Communication circuitry for receiving the base station related information from a base station;
A memory for storing the base station related information;
A display of an input device or an input function for receiving the base station related information; Variable passive relay device further comprising at least one of. The method of claim 4, wherein
A support moving part connected to the pillar part so as to be movable and to which the assembly supports are fixed;
The variable passive relay device further comprises; a movement adjusting unit for adjusting the movement of the support moving unit on the pillar portion in accordance with the controller control. The method of claim 4, wherein
It further comprises a communication circuit,
The controller
Transmits variable passive relay device related information including current location information and service area information to the control server based on the communication circuit,
Variable passive relay device configured to receive the control information from the control server. Collecting base station related information and passive relay device related information for a variable passive relay device as a control object;
Generating control information indicating adjustment of at least one of a shape and a direction of the variable passive relay device based on the base station related information, the passive relay device related information, and the service area information;
Transmitting the control information to the variable passive relay device or a designated manager terminal;
Variable passive relay device operating method comprising a. The method of claim 8,
The base station-related information includes at least one of latitude, longitude, altitude, beam width, output strength, distance between the base station antenna and the variable passive relay device of the base station antenna,
The passive relay device related information may include at least one of latitude, longitude, altitude, location information of a service area, a distance between a service area and a variable passive relay device, and a size of a service area of the variable passive relay device. How to operate a passive relay device. The method of claim 8,
And the control information includes information for adjusting at least one of curvature, diameter, and direction of the reflective surface of the variable passive relay device.

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