KR101503346B1 - Digital radio frequency refeater - Google Patents

Abstract

A digital radio frequency repeater is provided. The purpose of the present invention is to provide a digital radio frequency repeater which precisely understand a location of lighting and protects equipment by effectively and reliably cutting off the lightning current. A digital radio frequency repeater of an embodiment of the present invention in a digital radio frequency repeater which wirelessly repeats signals between first and second radio frequency terminals includes: an antenna unit; a digital radio frequency repeating unit for receiving signals transmitted from the first radio frequency terminal and performing wireless repeating which relays signals digitally signal-processed with respect to the second radio frequency terminal by digitally signal-processing the signals; a coaxial selector unit which includes a first connector connected by the digital radio frequency repeating unit and a first coaxial cable and a second connector connected by the antenna unit and a second coaxial cable for selectively switching between first signal path, which connects the first and second connectors, and second signal path which connects the second connector and ground using a plunger moving by magnetization of a solenoid; a lightning detection unit for detecting the location of lightning; and a control unit for controlling wireless repeating by controlling the digital radio frequency repeating unit, detecting a location of the lightning through the lightning detection unit during the wireless repeating operation, and switching a signal path of the coaxial selector unit to the second signal path by supplying power to the solenoid of the coaxial selector unit and moving the plunger if the detected location of the lightning is in a predetermined range.

Description

[0001] DIGITAL RADIO FREQUENCY REFEATER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital wireless repeater, and more particularly, to a digital wireless repeater provided in a high-rise building or a mountainous area to relay a wireless signal of a wireless terminal so as to increase a communication distance between wireless terminals.

In general, a wireless repeater is installed in a high-rise building or a mountainous area in order to prevent a communication shadow area from occurring due to insufficient communication distance only by a portable terminal such as a walkie-talkie or a vehicle terminal. A wireless repeater is a device for extending the communication distance of a wireless terminal to expand the communication capability of a user.

This wireless repeater is installed at a relatively high altitude like a mountain top. Accordingly, the wireless repeater is installed with a lightning protection facility to minimize the lightning damage that may occur.

However, even if a lightning protection facility is installed along with a wireless repeater, it is impossible to block the flow of lightning into a wireless repeater 100%.

Therefore, there is a possibility that the wireless repeater may be damaged due to the lightning stroke, so another measure for protecting the wireless repeater from the lightning stroke is required.

Published Patent Publication No. 2006-0115945 (published November 13, 2006)

An embodiment of the present invention is to provide a digital wireless repeater capable of precisely grasping the occurrence position of a lightning stroke in the event of a lightning stroke and protecting the equipment by effectively and reliably blocking a lightning current.

According to an aspect of the present invention, there is provided a digital wireless repeater for wirelessly relaying signals between a first wireless terminal and a second wireless terminal, the digital wireless repeater comprising: an antenna unit; A digital wireless repeater for receiving a signal transmitted from a first wireless terminal through the antenna unit, performing a digital signal processing and relaying the digital signal processed signal to the second wireless terminal through relay; A first connector connected to the digital wireless repeater via a first coaxial cable, and a second connector connected to the antenna unit through a second coaxial cable, wherein a signal path is formed by the plunger moving as the solenoid is magnetized A first signal path connecting the first connector and the second connector or a second signal path connecting the second connector and the ground side; A lightning detection unit for detecting the occurrence position of the lightning stroke; And controlling the wireless relay by controlling the digital wireless repeater to detect a location of occurrence of a thunderstroke through the thunderstroke sensing unit during the wireless relaying operation and if the detected thunderstroke occurrence position is within a preset range, And a controller for switching the signal path of the coaxial selector unit to the second signal path by supplying power to the solenoid and moving the plunger, wherein the thunderstroke sensing unit includes a grounding unit, A dome-shaped cover portion which is supported by the support portion and accommodates therein the electric field detection portion and the magnetic field detection portion; and a dome-shaped cover portion which is provided in the dome- A horizontal support portion for supporting the dome-shaped cover portion to the support portion; When imported electric there can be a digital wireless repeater including a plurality of conductive strips being arranged in a radial shape with the dome-shaped longitudinally on the outer surface of the cover portion to the holding portion can flow provided via the horizontal support.

Here, the coaxial selector unit may include: a first connector pin connected to the first connector; A second connector pin connected to the second connector; A ground pin connected to the ground side; A solenoid magnetized at power supply; A plunger provided at one end of the solenoid and protruding at the other end to move by the magnetization of the solenoid; And a link member having one end fixed to the other end of the plunger so as to move together with the movement of the plunger and the other end connected to the second connector pin, wherein the first signal path includes a first connector pin, And the second signal path is formed by connecting the second connector pin to the ground pin.

The lightning detection unit includes an electric field detector for detecting a change in electric field at the occurrence of a lightning stroke, a magnetic field detector for detecting a magnetic field change at the time of occurrence of a lightning stroke, a sound detector for detecting a thunder sound at the time of occurrence of a lightning stroke, The first lightning distance estimating unit estimates a first lightning distance using a change in the electric field detected through the electric field detector, and a second lightning distance estimating unit estimating a second lightning distance based on a change in the magnetic field detected by the magnetic field detector, A third lightning distance estimating section for estimating a third lightning distance in accordance with the time and sound speed until the thunder sound is detected through the sound detecting section after detecting the lightning through the light detecting section, And an estimating unit for estimating a final lightning stroke distance by applying different weights to the estimated first to third lightning distances, It may include distance estimation part and the end lightning distance estimation unit estimates over the last lightning stroke distance and the lightning stroke occurs for estimating an electrical storm position on the basis of the detected lightning strike orientation through the light detection position estimating portion.

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Here, the dome-shaped cover part is made of a non-conductive material, and the conductive strip includes a base plate made of an insulating material, a thermosetting resin uniformly provided on the base plate, and a conductive metal material . ≪ / RTI >

According to another embodiment of the present invention, there is provided a digital wireless repeater for wirelessly relaying signals between a first wireless terminal and a second wireless terminal, the digital wireless repeater comprising: an antenna unit; A digital wireless repeater for receiving a signal transmitted from a first wireless terminal through the antenna unit, performing a digital signal processing and relaying the digital signal processed signal to the second wireless terminal through relay; A first connector connected to the digital radio relay unit by a first coaxial cable; a second connector connected to the antenna unit through a second coaxial cable; a first connector pin connected to the first connector; A second connector pin connected to the second connector, a ground pin connected to the ground, a solenoid magnetized when power is supplied, and a second solenoid having one end inserted into the solenoid and the other end projecting to the outside, And a link member having one end fixed to the other end of the plunger so as to move together with the movement of the plunger and the other end connected to the second connector pin, wherein the plunger moves with the plunger moving as the solenoid is magnetized, To a second signal path formed by connecting the first connector pin and the second connector pin to the ground pin or a first signal path formed by connecting the first connector pin and the second connector pin to the ground pin, A selector unit; A lightning detection unit for detecting the occurrence position of the lightning stroke; And a controller for supplying power to the solenoid of the coaxial selector unit so that the signal path of the coaxial selector unit is switched to the second signal in the first signal path when the lightning stroke occurs within a predetermined range based on the lightning stroke occurrence position information sensed by the lightning sensing unit, The control unit switches the signal path of the coaxial selector unit from the second signal path to the first signal path by turning off the power supplied to the solenoid of the coaxial selector unit when the lightning stroke occurs outside the predetermined range, Wherein the lightning detection unit comprises a grounding portion, an electric field detection portion provided at the grounding portion for detecting an electric field at the occurrence of a thunderstorm, a magnetic field detection portion provided at the grounding portion and detecting a magnetic field at the occurrence of a thunderstorm, And a dome-shaped cover portion for receiving the electric field detecting portion and the magnetic field detecting portion therein, A horizontal support portion for supporting the dome-shaped cover portion to the support portion, and a support portion for supporting the dome-shaped cover portion in a radial manner in the longitudinal direction on the outer surface of the dome- shaped cover portion so that electricity can flow to the support portion via the horizontal support portion when lightning- A digital wireless repeater may be provided that includes a plurality of conductive strips provided.

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The embodiment of the present invention can minimize the damage of the equipment due to the lightning strike by safely protecting the control device of the digital wireless repeater as well as the thunderstroke sensing device during the occurrence of thunderstroke within a certain distance by grasping the occurrence position of the thunderstroke.

In addition, the embodiment of the present invention can reliably protect the digital wireless repeater main body from the lightning current by reliably blocking the lightning current from being transmitted to the digital wireless repeater main body when a lightning stroke occurs.

1 is a block diagram of a digital wireless repeater according to an embodiment of the present invention.
2 is a control block diagram of a digital wireless repeater according to an embodiment of the present invention.
3 is a diagram for explaining signal connection between a main body of a digital wireless repeater and a coaxial selector unit according to an embodiment of the present invention.
4 is a view for explaining a configuration of a coaxial selector unit of a digital wireless repeater according to an embodiment of the present invention.
5 is a control block diagram illustrating a configuration of a lightning detection unit and a control unit of a digital wireless repeater according to an exemplary embodiment of the present invention.
6 is a schematic perspective view of a lightning surveillance unit of a digital wireless repeater according to an embodiment of the present invention.
7 is a cross-sectional view of a conductive strip provided on the dome-shaped cover of Fig.
8 is a view for explaining the operation of the coaxial selector unit when the occurrence position of the lightning occurs in a digital wireless repeater according to an exemplary embodiment of the present invention.
9 is a view for explaining the operation of the coaxial selector unit when the occurrence position of a lightning stroke is within a preset range in the digital wireless repeater according to an embodiment of the present invention.
10A and 10B are control flowcharts for explaining a control method of a digital wireless repeater according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments to be described below are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the width, length, thickness, etc. of components are exaggerated for the sake of convenience. Like reference numerals designate like elements throughout the specification.

1 is a block diagram of a digital wireless repeater according to an embodiment of the present invention.

Referring to FIG. 1, a digital wireless repeater is a wireless repeater that wirelessly transmits and receives signals to and from a wireless device such as a radio, a wireless, or a wireless communication network in order to eliminate a signal- Receiving and amplifying the wireless signal from the terminal and propagating the signal to the inside of the shadow area so that communication can be performed between the wireless terminals.

The digital wireless repeater 10 receives and relays the signal transmitted from the first wireless terminal T1 and performs a transmission operation to the second wireless terminal T2 as a communication partner. Since the first wireless terminal T1 and the second wireless terminal T2 can communicate with each other, the digital wireless repeater 10 receives and transmits the signal transmitted from the second wireless terminal T2, 1 wireless terminal (T1).

2 is a control block diagram of a digital wireless repeater according to an embodiment of the present invention.

2, the digital wireless repeater 10 may include an antenna unit 11, a digital wireless repeater unit 12, a coaxial selector unit 13, a lightning strike sensing unit 14, and a control unit 15 .

The antenna unit 11 is electrically connected to the digital radio relay unit 12 through the coaxial selector unit 13. The characteristics of the antenna of the antenna unit 11 as one of the components to be determined at the end of the digital wireless repeater, which determine the quality of the call, and the development of a good antenna is therefore essential. The antenna may be an antenna applicable for transmitting and receiving a signal in a VHF (Very High Frequency) band. The VHF band antenna may be an antenna such as a monopole antenna and a helical antenna.

The antenna unit 11 may include at least one of a receiving antenna unit such as a VHF receiving antenna and a transmitting antenna unit such as a VHF transmitting antenna.

The antenna unit 11 is electrically connected to a connector (Antenna Port) formed in the coaxial selector unit 13 by a coaxial cable. The connector is connected to one side of the coaxial selector unit 13 through a coaxial cable.

The digital radio relay unit 12 includes an analog-digital signal converter for converting an analog signal into a digital signal, a digital-analog signal converter for converting a digital signal into an analog signal, a digital-to-analog converter for filtering, amplifying, And a digital signal processor that performs appropriate digital signal processing such as noise cancellation and the like. This digital signal processor can be implemented as an FPGA (Field Programmable Gate Array).

The digital radio relay unit 12 includes a transceiver that transmits a signal through the antenna unit 11 in accordance with the control signal of the control unit 15 and receives the signal transmitted from the radio terminal through the antenna unit 11 do. For example, the transceiver of the digital radio relay unit 12 transmits a signal through a transmission antenna unit and receives a signal transmitted from an external terminal through a reception antenna unit.

In addition, the digital radio relay unit 12 uses the frequency division multiple access (FDMA) scheme to narrow the ownership frequency per channel to 12.5 KHz, for example, to 6.25 KHz, To be used. In frequency division multiple access, the effective bandwidth of a transmission medium is divided into frequency regions at regular intervals in data communication, and each frequency region is allocated to each channel to be used. Accordingly, the digital wireless relay unit 12 can digitize the transmission method to improve the sound quality and the intelligibility, and to transmit and receive encrypted communication and various data (text / code / video / voice) smoothly.

The coaxial selector unit 13 is provided on the signal line between the antenna unit 11 and the digital radio relay unit 12 and connects or disconnects the signal path between the antenna unit 11 and the digital radio relay unit 12. Here, the signal path interruption is achieved by physical separation of the signal lines.

The coaxial selector unit 13 selects the first signal path between the antenna unit 11 and the digital radio relay unit 12 and the second signal path between the antenna unit 11 and the ground according to the control signal of the controller 15 Selectively.

FIG. 3 is a view for explaining signal connection between a main body of the digital wireless repeater and a coaxial selector unit according to an embodiment of the present invention. FIG. 4 is a diagram illustrating a configuration of a coaxial selector unit of a digital wireless repeater according to an embodiment of the present invention Fig.

Referring to Figure 2 and W 3 and 4, coaxial selector section 13 to the digital radio relay unit 12 in the main body (13a), provided in the main body (13a) digital radio repeater unit (10a) A first connector 13b for signal connection and a second connector 13c for signal connection with the antenna unit 11. [

The first connector 13b of the coaxial selector unit 13 and the digital radio relay unit 12 are connected by a first coaxial cable 20. The second connector 13c of the coaxial selector unit 13 and the antenna unit 11 are connected by the second coaxial cable 21.

In addition, the coaxial selector unit 13 has a first connector pin 130, a ground pin 131, a second connector pin 132, a solenoid 133, a plunger 134 and a link member provided in a main body (13a), ( 135). The first connector pin 130 and the second connector pin 132 may be disposed opposite each other. The first connector pin 130 and the ground pin 131 may be arranged to have different heights from each other with reference to the second connector pin 132. For example, the first connector pin 130 and the ground pin 131 may be disposed up and down with respect to the contact end of the second connector pin 132.

The second connector pin 132 is electrically connected to the second connector 13c. The second connector pin 132 is provided between the first connector pin 130 and the ground pin 131 and selectively connected to the first connector pin 130 or the ground pin 131.

The solenoid 133 is provided at one side of the main body 13a, and moves the plunger 134 depending on whether power is applied or not. For example, the solenoid 133 lifts the plunger 134.

One end of the plunger 134 is inserted into the solenoid 52 and the other end of the plunger 134 is protruded to the outside and moved by the magnetism of the solenoid 133. For example, the solenoid 133 ascends and descends.

One end of the link member 135 is fixed to the other end of the plunger 134, and the other end of the link member 135 is fixed through the second connector pin 132.

The coaxial selector unit 13 having the above configuration is connected to the coaxial selector unit 13 through the signal path of the coaxial selector unit 13 in accordance with the power supply of the solenoid 133 supplied with power by the control unit 15, A first signal path connecting the first coaxial cable 20 and the second coaxial cable 21 connected to the digital radio relay unit 12 and a second signal path connecting the first coaxial cable 20 connected to the antenna unit 11 and the ground line The second signal path connecting the first signal path and the second signal path.

For example, if no power is supplied to the solenoid 133 of the coaxial selector unit 13, since the solenoid 133 is not magnetized and the plunger 134 is not lowered, the first and second connector pins 130, The pin 132 remains connected. Accordingly, the signal line between the antenna unit 11 and the digital radio relay unit 12 is electrically connected.

When power is supplied to the solenoid 133 of the coaxial selector unit 13, since the solenoid 133 is magnetized to lower the plunger 134, the second connector pin 132 connected by the link member 135 Is separated from the first connector pin (130) and connected to the ground pin (131). Accordingly, the signal line between the antenna unit 11 and the digital radio relay unit 12 is separated, and the signal line between the antenna unit 11 and the ground side is connected. Accordingly, even if the lightning current generated in the occurrence of a lightning stroke is introduced into the antenna unit 11, it can be transmitted to the ground side without being transmitted to the digital wireless repeater 12, thereby protecting the digital wireless repeater from a lightning stroke.

Referring again to FIG. 2, the lightning detection unit 14 detects the occurrence position of the lightning stroke.

FIG. 5 is a control block diagram illustrating a configuration of a lightning sensing unit and a control unit of a digital wireless repeater according to an exemplary embodiment of the present invention. FIG. 6 is a schematic block diagram of a lightning surveillance unit of a digital wireless repeater according to an exemplary embodiment of the present invention. Fig. 7 is a cross-sectional view of a conductive strip provided on the dome-shaped cover of Fig. 6; Fig.

5 through 7, the lightning strike sensing unit 14 may include an electric field detector 141, a magnetic field detector 142, a sound detector 143, and an optical detector 144.

The electric field detection unit 141 detects a change in electric field at the occurrence of a lightning stroke. The electric-field detecting unit 141 has a disk-shaped detecting electrode and a grounding electrode spaced from each other, and a capacitance is formed between these electrodes. The electric field detection unit 141 outputs a signal corresponding to the electric field waveform due to the electric field change occurring at the occurrence of the lightning stroke.

For example, a Franklin Lightning Sensor capable of detecting a lightning strike at a distance of up to 40 km may be used as the electric field detector 141. Franklin lightning sensors detect not only the lightning strike from the clouds to the ground, but also the cloud activity that is used to determine the storm accessibility. The Franklin lightning sensor detects lightning activity approaching up to 40 kilometers away. The Franklin lightning sensor uses the measured signal to statistically calculate the distance to the tip of the cloud where the lightning occurs, or the distance of the lightning. The lightning sensor detects the distance information or the lightning occurrence distance information to the tip of the cloud in which the lightening occurs, and transmits the information to the controller 15.

The magnetic field detection unit 142 detects a change in the magnetic field at the occurrence of a lightning stroke. The magnetic field detection unit 142 includes two loop sensors arranged in an orthogonal manner. A magnetic field is generated by the lightning stroke caused by the lightning stroke. The magnetic field detector 142 detects the change of the magnetic field at this time through the two loop sensors and outputs a signal corresponding to the magnetic field waveform due to the detected magnetic field change .

The sound detection unit 143 detects the following thunder sound after the occurrence of the lightning stroke. The sound detection unit 143 includes a microphone. For example, the sound detection unit 143 may be configured as a parallel plate capacitor with a fixed electrode that opposes the movable electrode that vibrates and displaces according to the negative pressure at a very narrow interval. The sound detection unit 143 outputs a change in capacitance due to the displacement of the movable electrode according to the sound pressure as an electrical signal corresponding thereto.

The light detection unit 144 detects lightning that occurs when a lightning stroke occurs. The light detection unit 144 detects lightning that occurs when a lightning stroke occurs, converts the detected lightning into an electric signal, and outputs the electric signal. The photodetector 144 is installed in eight different directions to detect light caused by instantaneous lightning strokes. The control unit (15) recognizes the direction information of the lightning stroke based on the signal provided by each of the light detecting units (144).

6, the lightning detection unit 14 having the above-described configuration includes a grounding portion 145 and a dome-shaped cover portion 146 supported by the grounding portion 145. As shown in FIG.

The supporting portion 145 is grounded on one side and branched on the other side. An electric field detector 141 is provided on the first branch side and a magnetic field detector 142 is provided on the second branch side.

The dome-shaped cover portion 146 is connected to the support portion 145 by a horizontal support portion 147 . The horizontal support portion 147 supports the dome-shaped cover portion 146 to the support portion 145 by connecting an intermediate portion between the one side and the other side of the support portion 145 and the circumferential end portion of the dome-shaped cover portion 146 . For example, the horizontal support 147 may be in the form of a fan. The horizontal support 147 may be made of a conductive material. The horizontal support portion 147 may be formed in a plate shape having a predetermined area if a hole having a sufficient size required for detecting an electric field is formed only in a portion corresponding to the electric field detector 141 side.

The dome-shaped cover portion 146 has an inner diameter enough to cover the electric field detecting portion 141 and the magnetic field detecting portion 142 so as to protect the electric field detecting portion 141 and the magnetic field detecting portion 142 from lightning.

The dome-shaped cover portion 146 is made of a nonmetallic material so that the electric field detecting portion 141 and the magnetic field detecting portion 142 inside can detect a magnetic field change in a field change occurring when a lightning stroke occurs. The dome-shaped cover portion 146 may include a non-conductive reinforced plastic.

On the outer surface of the dome-shaped cover portion 146, a conductive strip 148 is provided. The conductive strips 148 are provided radially on the outer surface of the dome-shaped cover portion 146. The conductive strip 148 serves to allow electricity to flow through the horizontal support 147 to the support portion 145 when the dome-shaped cover portion 146 is hit by a lightning strike. Accordingly, not only the electric field detector 141 and the magnetic field detector 142 can be protected from lightning, but also most of the lightning current can be quickly transmitted to the support portion 145 through the conductive strips, Can be prevented from being damaged.

7, the conductive strip 148 includes a substrate 148a made of an insulating material and forming a base, a thermosetting resin 148b uniformly provided on the base plate, And a conductive metal material 148c adhered to the base plate 148a by the resin 148b. The conductive metal material 148c may comprise aluminum. The conductive metal material 148c may be provided in a state in which the base plate 148a is scattered in powder form.

Since the conductive strip 148 having the above-described configuration moves the source of the streamer of the dome-shaped cover portion 146 to the support portion 145, the effect of forming the electrostatic shield on the dome-shaped cover portion 146 is obtained.

The dome-shaped cover portion 146 can generate an ionized streamer due to the friction between the electromagnetic field waves formed in the magnetic field detector 142 and the outer air of the dome-shaped cover portion 146. Since such a streamer provides a passage for a lightning strike, the dome-shaped cover portion 146 without the conductive strip 148 penetrates through the lightning strike and damages the detecting elements such as the electric field detecting portion 141 and the magnetic field detecting portion 142 . However, when the conductive strips 148 are provided, charges generated due to static electricity can be rapidly dispersed, and various detection elements can be safely protected from lightning strikes.

The conductive strip 148 is installed extending to the circumferential end of the dome-shaped cover portion 146. In addition, the conductive strip 148 may be extended to the horizontal support 147 or the support portion 145.

In addition, a mounting table 149 for supporting the sound detecting unit 143 and the light detecting unit 144 may be provided in the middle of the supporting unit 145. In this mounting table 149, the photodetector 144 may be disposed at equal intervals in eight different directions so as to grasp the lightning strike direction when a lightning stroke occurs. An acoustic detector 143 may be installed at one side of the mounting table 149.

5, the control unit 15 includes a first lightning distance estimating unit 150, a second lightning distance estimating unit 151, a third lightning distance estimating unit 152, a final lightning distance estimating unit 153, And a lightning occurrence occurrence position estimating unit 154.

The first lightning distance estimator 150 estimates the first lightning distance using the change of the electric field detected through the electric field detector 141.

The second lightning distance estimator 151 estimates the second lightning distance using the change of the magnetic field detected by the magnetic field detector 141.

The electric field waveform and the magnetic field waveform generated by the lightning stroke vary depending on the lightning distance. For example, the electric field waveform and the flux characteristic of the magnetic field waveform change depending on the lightning distance. Since the radioactive powder is mainly detected by the lightning strike by the remote lightning, the electric field and the magnetic field waveform are almost the same shape.

The characteristics of the wave portion of the electric field and the magnetic field wave radiated by the lightning stroke can be classified into a portion initially rising gradually and a portion rising rapidly after that. The slowly rising part is the peaks with a gentle slope that occurred during the deposition process. The rising part is due to the return light current from the ground, and a peak with a sharp gradient occurs. The rise time is, for example, several hundreds [ns]. The sudden increase in the waveform of the electric field and the magnetic field radiated by the lightning stroke corresponds to the change of the lightning current. The variations of the electric field waveform and the magnetic field waveform caused by the lightning stroke have a direct relation with the lightning current, The characteristics of the electric field waveform and the magnetic field waveform due to the lightning stroke are determined by various parameters such as a rise time, a zero crossing time, an inverted dip depth (representing the characteristic of the frustum and the ratio of the peak value of the opposite polarity to the first peak value of the waveform) And these parameters vary according to the distance from the lightning point position to the sensor for detection. Therefore, each lightning distance can be estimated by analyzing the electric field waveform and the magnetic field waveform.

The third lightning distance estimating unit 152 receives the sound signal detected by the sound detecting unit 143 and the optical signal detected through the optical detecting unit 144 and determines the time from the occurrence of the lightning to the detection of the thunder sound To calculate the lightning distance. When a predetermined time elapses after the occurrence of the lightning, sound having a specific frequency of the thunder sound can be detected. When a thunder sound is detected through the sound detection unit 143 after the lightning is detected through the light detection unit 144 The lightning distance is estimated according to the time and sound velocity.

The final lightning distance estimating unit 153 estimates the first lightning distance estimated through the first lightning distance estimating unit 150, the second lightning distance estimated through the second lightning distance estimating unit 151, And estimates the final lightning distance based on the third lightning distance estimated through the distance estimating unit 152. [ The final lightning distance estimating unit 153 can estimate the average value of the three lightning distance values as the final lightning distance value. At this time, the final lightning distance estimating unit 153 may apply different weights to the three lightning distance values. For example, the weights can be set to be higher in the order of the first lightning distance, the second lightning distance, and the third lightning distance.

The lightning occurrence occurrence position estimating unit 154 estimates the lightning occurrence occurrence position based on the final lightning stroke distance estimated through the final lightening distance estimating unit 153 and the lightning stroke detected through the light detecting unit 144. Since the eight light detection portions 144 are provided on the mounting table 149 in different directions, the direction of the lightning is determined by taking into consideration the optical signals detected through the respective light detection portions 144 and the directions in which the respective light detection portions 144 are installed Able to know.

On the other hand, the controller 15 determines whether the estimated lightning occurrence position is within a predetermined range after estimating the lightning occurrence occurrence position.

2, the control unit 15 controls the coaxial selector unit 13 in accordance with the lightning stroke occurrence position information sensed by the lightning stroke sensing unit 14 so that the signal path of the coaxial selector unit 13 is connected to the antenna unit 11 and the digital radio relay unit 12 in the first signal path between the antenna unit 11 and the ground.

More specifically, the control unit 15 determines whether the occurrence position of the lightning stroke detected through the lightning perception sensing unit 14 is within a predetermined range while relaying the wireless signal through the antenna unit 11. [ The control unit 15 supplies power to the solenoid 134 of the coaxial selector unit 13 when the lightning stroke occurrence position detected by the lightning stroke detection unit 14 is out of a predetermined range. When the power is supplied to the solenoid 133, the solenoid 133 is magnetized to lower the plunger 134, so that the second connector pin 132 connected by the link member 135 is separated from the first connector pin 130 And is connected to the ground pin 131. Accordingly, the signal line between the antenna unit 11 and the digital radio relay unit 12 is separated, and the signal line between the antenna unit 11 and the ground side is connected. Accordingly, even if the lightning current generated in the occurrence of a lightning stroke is introduced into the antenna unit 11, it can be transmitted to the ground side without being transmitted to the digital wireless repeater 12, thereby protecting the digital wireless repeater from a lightning stroke.

8 is a view for explaining the operation of the coaxial selector unit when the occurrence position of the lightning occurs in a digital wireless repeater according to an exemplary embodiment of the present invention.

Referring to FIG. 8, when the occurrence position of the lightning stroke detected through the lightning perception sensing unit 14 is out of the predetermined range, the control unit 15 determines that the lightning stroke occurs at a relatively far place, It is judged that the risk is low. Therefore, the control unit 15 does not apply the power to the solenoid 133 of the coaxial selector unit 13. Accordingly, the signal line between the antenna unit 11 and the digital radio relay unit 12 is maintained in an electrically connected state, and the digital radio repeater continuously performs the relay function of the signal.

2, the control unit 15 applies power to the solenoid 133 of the coaxial selector unit 13 when the occurrence position of the lightning stroke detected through the thunderstroke sensing unit 14 is within a preset range . Accordingly, the signal connection between the antenna unit 11 and the digital radio relay unit 12 is disconnected and the antenna unit 11 is connected to the ground side, whereby a lightning stroke current caused by a lightning stroke is transmitted through the antenna unit 11, (12) and bypassed to the ground side to protect the digital wireless repeater from lightning.

9 is a view for explaining the operation of the coaxial selector unit when the occurrence position of a lightning stroke is within a preset range in the digital wireless repeater according to an embodiment of the present invention.

Referring to FIG. 9, when the occurrence position of the lightning stroke detected through the lightning detection unit 14 is within a predetermined range, the control unit 15 determines that the lightning stroke occurs at a relatively short distance, Is in a large state. Therefore, the control unit 15 supplies power to the solenoid 133 of the coaxial selector unit 13. [ The solenoid 133 is magnetized as power is supplied to the solenoid 133 and the plunger 134 is lowered as the solenoid 133 is magnetized. When the plunger 134 descends, the link member 135 connected to the plunger 134 moves down together and the second connector pin 132 connected to the link member 135 moves and separates from the first connector pin 130 And is connected to the ground pin 131. The signal connection between the antenna unit 11 and the digital wireless repeater unit 12 is disconnected and the antenna unit 11 is connected to the ground side to protect the digital wireless repeater even if a lightning stroke current flows into the antenna unit 11. [ .

The control unit 15 controls the coaxial selector unit 13 to shut off the signal connection between the antenna unit 11 and the digital wireless repeater unit 12 and then outputs the signal to the coaxial selector unit 13 ) To return to the original operating state so that the signal connection between the antenna unit 11 and the digital radio relay unit 12 is performed again.

The control unit 15 temporarily suspends the radio relay operation while the signal connection between the antenna unit 11 and the digital radio relay unit 12 is separated by the coaxial selector unit 13 in the radio relay operation, And the digital radio relay unit 12, the radio relay operation can be resumed.

Although the coaxial selector unit 13 is provided between the antenna unit 11 and the digital radio relay unit 12 in the embodiment of the present invention, the present invention is not limited to this. The coaxial selector unit 13 is provided on the signal line between the antenna unit 11 and the control unit 15 in accordance with the control signal of the control unit 15 so that the antenna The signal line between the unit 11 and the control unit 15 can be electrically or physically connected or disconnected.

10A to 10B are control flowcharts for explaining a control method of a digital wireless repeater according to an embodiment of the present invention.

10A to 10B, a method of controlling a digital wireless repeater includes a process 200 for detecting an electric field, a process 202 for estimating a first lightning distance using the detected electric field change, a process 204 for detecting a magnetic field A step 206 of estimating a second lightning distance using the detected magnetic field change, a step 208 of detecting light and sound, a step of estimating a third lightning distance using the detected light and sound 210 A process 212 for estimating a final lightning distance based on the first lightning distance to the third lightning distance estimated in the operation modes 202, 206 and 210, and a process 214 for estimating the lightning direction using the direction of lightning ), And a step (216) of estimating a lightning occurrence position based on the final lightning distance and the lightning strike direction.

On the other hand, after estimating the lightning occurrence location, the controller 17 determines whether the estimated lightning occurrence location is within a preset range from the digital wireless repeater (218).

If the lightning occurrence position is out of the predetermined range from the digital wireless repeater as a result of the determination in the operation mode 218, the control unit 15 controls the coaxial selector unit 13 to switch the signal path of the coaxial selector unit 13 to the first signal path Thereby maintaining the signal connection between the antenna unit 11 and the digital wireless repeater 12 (220).

The control unit 15 supplies power to the solenoid 133 of the coaxial selector unit 13 and outputs the power to the coaxial selector unit 13 as a result of the operation mode 218. [ The signal connection between the antenna unit 11 and the digital wireless repeater unit 12 is electrically separated (222) by switching the signal path from the first signal path to the second signal path, and the antenna unit 11 is connected to the ground side (224). Accordingly, even if a lightning stroke caused by a lightning strike is inputted to the digital wireless repeater, the digital light repeater can be blocked and bypassed to the ground side, thereby safeguarding the digital wireless repeater from a lightning strike.

10: digital radio repeater 11: antenna unit
12: Digital radio relay unit 13: Coaxial selector unit
13a: main body 13b: first connector
13c: second connector 130: first connector pin
131: ground pin 132: second connector pin
133: Solenoid 134: Plunger
135: link member 14: lightning detection unit
15:

Claims (7)

A digital wireless repeater for wirelessly relaying signals between a first wireless terminal and a second wireless terminal,
An antenna section;
A digital wireless repeater for receiving a signal transmitted from a first wireless terminal through the antenna unit, performing a digital signal processing and relaying the digital signal processed signal to the second wireless terminal through relay;
A first connector connected to the digital wireless repeater via a first coaxial cable, and a second connector connected to the antenna unit through a second coaxial cable, wherein a signal path is formed by the plunger moving as the solenoid is magnetized A first signal path connecting the first connector and the second connector or a second signal path connecting the second connector and the ground side;
A lightning detection unit for detecting the occurrence position of the lightning stroke; And
Wherein the control unit controls the digital radio relay unit to control the radio relay and detects the occurrence position of the thunderbolt through the thunderstroke sensing unit during the radio relaying operation and if the detected thunderstroke occurrence position is within a preset range, And a control unit for switching the signal path of the coaxial selector unit to the second signal path by supplying power to the plunger to move the plunger,
The lightning detection unit includes a grounding portion, an electric field detection portion provided at the grounding portion for detecting an electric field at the occurrence of a thunderstorm, a magnetic field detection portion provided at the grounding portion for detecting a magnetic field at the occurrence of a thunderstorm, A dome-shaped cover portion for accommodating the electric field detecting portion and the magnetic field detecting portion therein; a horizontal support portion for supporting the dome-shaped cover portion to the support portion; And a plurality of conductive strips radially provided on the outer surface of the dome-shaped cover portion in the longitudinal direction so as to allow the conductive strip to flow therethrough. The method according to claim 1,
Wherein the coaxial selector portion comprises: a first connector pin connected to the first connector;
A second connector pin connected to the second connector;
A ground pin connected to the ground side;
A solenoid magnetized at power supply;
A plunger provided at one end of the solenoid and protruding at the other end to move by the magnetization of the solenoid; And
And a link member having one end fixed to the other end of the plunger and the other end connected to the second connector pin so as to move together with the movement of the plunger,
Wherein the first signal path is formed by connecting a first connector pin and the second connector pin and the second signal path is formed by connecting the second connector pin to the ground pin. The method according to claim 1,
Wherein the lightning detection unit includes an electric field detector for detecting a change in electric field at the occurrence of a thunderbolt, a magnetic field detector for detecting a magnetic field change at the time of occurrence of a thunderstorm, a sound detector for detecting a thunder sound at the occurrence of a thunderstorm,
The control unit includes a first lightning distance estimator for estimating a first lightning distance using a change in the electric field detected through the electric field detector, and a second lightning distance estimator for estimating a second lightning distance using a change in the magnetic field detected by the magnetic field detector. A third lightning distance estimator for estimating a third lightning distance according to a time and a sound speed until a thunder sound is detected through the sound detecting unit after detecting the lightning through the light detecting unit, A final lightning strike distance estimating unit for estimating a final lightning strike distance by applying different weights to the estimated first to third lightning distances, And a lightning occurrence occurrence position estimating section for estimating a lightning occurrence occurrence position based on the lightning strike direction detected by the light detecting section. delete The method according to claim 1 ,
Wherein the dome-shaped cover portion is made of a non-conductive material,
Wherein the conductive strip comprises a base plate made of an insulating material, a thermosetting resin uniformly provided on the base plate, and a conductive metal material adhered to the base plate by the thermosetting resin. A digital wireless repeater for wirelessly relaying signals between a first wireless terminal and a second wireless terminal,
An antenna section;
A digital wireless repeater for receiving a signal transmitted from a first wireless terminal through the antenna unit, performing a digital signal processing and relaying the digital signal processed signal to the second wireless terminal through relay;
A first connector connected to the digital radio relay unit by a first coaxial cable; a second connector connected to the antenna unit through a second coaxial cable; a first connector pin connected to the first connector; A second connector pin connected to the second connector, a ground pin connected to the ground, a solenoid magnetized when power is supplied, and a second solenoid having one end inserted into the solenoid and the other end projecting to the outside, And a link member having one end fixed to the other end of the plunger so as to move together with the movement of the plunger and the other end connected to the second connector pin, wherein the plunger moves with the plunger moving as the solenoid is magnetized, To a second signal path formed by connecting the first connector pin and the second connector pin to the ground pin or a first signal path formed by connecting the first connector pin and the second connector pin to the ground pin, A selector unit;
A lightning detection unit for detecting the occurrence position of the lightning stroke; And
When the lightning stroke occurs within a predetermined range based on the lightning stroke occurrence position information sensed by the lightning stroke sensing unit, the solenoid of the coaxial selector unit supplies power to the signal path of the coaxial selector unit from the first signal path to the second signal path A control unit for switching the signal path of the coaxial selector unit from the second signal path to the first signal path by turning off the power supplied to the solenoid of the coaxial selector unit when the lightning stroke occurs outside the preset range; Wherein the lightning detection unit comprises a grounding part, an electric field detection part provided at the grounding part for detecting an electric field at the occurrence of a thunderstorm, a magnetic field detection part provided at the grounding part for detecting a magnetic field at the occurrence of a thunderstorm, A dome-shaped cover portion for receiving the electric field detecting portion and the magnetic field detecting portion therein, A horizontal support portion for supporting the dome-shaped cover portion to the support portion, and a support portion for supporting the dome-shaped cover portion to be radially extended in the longitudinal direction on the outer surface of the dome- shaped cover portion so that electricity can flow to the support portion through the horizontal support portion when lightning- Wherein the plurality of conductive strips comprises a plurality of conductive strips. delete

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