KR102232870B1 - Tunnel lamp control circuit and method of operating the same - Google Patents

Abstract

Disclosed is a tunnel lamp control circuit for controlling a tunnel lamp. The tunnel lamp control circuit comprises: a power line communication unit configured to receive a control signal from a tunnel lamp controller; a memory configured to store an identifier of a tunnel lamp; and a light emission control unit configured to output a light emission control signal for controlling the light emission of a plurality of lamp modules arranged in a matrix form. The light emission control unit reads the identifier of the tunnel lamp from the memory, determines a first lamp module disposed at a position corresponding to the identifier among a plurality of lamp modules to visually indicate a value associated with the identifier, and turns on the first lamp module and outputs the light emission control signal for turning off a second lamp module excluding the first lamp module among the plurality of lamp modules. According to the present invention, it is possible to visually identify the location of the target tunnel lamp, which needs to be inspected, replaced or repaired, among tunnel lamps arranged inside the tunnel.

Description

Tunnel lamp control circuit and its operation method {TUNNEL LAMP CONTROL CIRCUIT AND METHOD OF OPERATING THE SAME}

Embodiments of the present invention relate to a tunnel light control circuit and a method of operating the same.

A tunnel is a passage through mountains, underground, or the sea so that vehicles or people can pass. Since the inside of the tunnel is generally dark, a plurality of tunnels or the like may be arranged inside the tunnel for pedestrians or drivers.

On the other hand, since dozens of tunnels are arranged side by side in a tunnel, it is difficult to distinguish the specific tunnel among dozens of tunnels with the naked eye when inspection, replacement or repair of a specific tunnel is required. There is this.

The problem to be solved by the present invention is to visually indicate a value associated with its own identifier, such as a tunnel, so that the location of a target tunnel that needs to be inspected, replaced, or repaired among tunnels arranged inside the tunnel can be visually identified. It is to provide a control circuit and a method of operation thereof, such as in a tunnel.

A tunnel light control circuit for controlling a tunnel light disposed in a tunnel according to embodiments of the present invention includes a power line communication unit configured to receive a control signal from a tunnel light controller, a memory configured to store an identifier of a tunnel, etc., and a matrix form. And a light emission control unit configured to output a light emission control signal for controlling light emission of the plurality of lamp modules arranged in, and the light emission control unit reads an identifier such as a tunnel from a memory, and visually displays a value associated with the identifier. For this purpose, a first lamp module disposed at a position corresponding to an identifier among a plurality of lamp modules is determined, the first lamp module is turned on, and a second lamp module other than the first lamp module among the plurality of lamp modules is determined. A light emission control signal for turning off is output.

A method of operating a tunnel light control circuit for controlling a tunnel light disposed in a tunnel and including a plurality of lamp modules arranged in a matrix form according to embodiments of the present invention includes an identifier indicating an arrangement order in the tunnel, etc. Turning on a first lamp module disposed at a position corresponding to the identifier among a plurality of lamp modules in order to visually indicate a value associated with the identifier and the step of storing an identifier such as a tunnel, etc. And outputting a light emission control signal for turning off a second lamp module other than the first lamp module among the lamp modules.

According to embodiments of the present invention, the tunnel lamp may turn on the first lamp module among the plurality of lamp modules in order to visually indicate a value associated with its own identifier such as the tunnel. Accordingly, by visually observing the turned-on first lamp modules, there is an effect that the identifier of the tunnel or the like can be identified. In particular, when an identifier such as a tunnel indicates an arrangement order of a tunnel or the like, there is an effect that the arrangement order of a tunnel or the like can be easily identified with the naked eye.

According to embodiments of the present invention, it is possible to determine an indicator tunnel light adjacent to a target tunnel light among a plurality of tunnel lights, and operate the indicator tunnel light in a different light emission mode than the other tunnel lights. Accordingly, since the indicator tunnel, etc. can be distinguished with the naked eye from the rest of the tunnel, etc., the target tunnel etc. arranged adjacent to the indicator tunnel can be easily recognized with the naked eye.

1 shows a tunnel light control system according to embodiments of the present invention.
2 shows a tunnel light control system according to embodiments of the present invention.
3 shows a tunnel light control system according to embodiments of the present invention.
4 shows a tunnel, etc. according to embodiments of the present invention.
5 to 8 show lamp modules of a tunnel lamp according to embodiments of the present invention.
9 is a flow chart showing the operation of a tunnel, etc. according to embodiments of the present invention.
10 and 11 illustrate a tunnel light control system according to embodiments of the present invention.
12 shows a controller such as a tunnel according to embodiments of the present invention.
13 is a flow chart showing the operation of a controller such as a tunnel according to embodiments of the present invention.
14 is a diagram for explaining the operation of a controller such as a tunnel according to embodiments of the present invention.
15 is a diagram for explaining an operation of a controller such as a tunnel according to embodiments of the present invention.
16 is a flow chart for explaining the operation of a tunnel, etc. according to embodiments of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 shows a tunnel light control system according to embodiments of the present invention. Referring to FIG. 1, the tunnel lamp control system 10 may include a tunnel lamp controller 100 and a plurality of tunnel lamps 200A and 200B.

The tunnel lamp controller 100 may control a plurality of tunnel lamps 200A and 200B. According to embodiments, the tunnel lamp controller 100 includes a plurality of tunnel lamps 200A and 200B and a power line PL. It may be connected through, and a plurality of tunnel lights 200A and 200B may be controlled through the power line PL. For example, one row of tunnels may be connected through one power line PL.

There are a plurality of tunnel lights 200A and 200B, and may be arranged side by side (eg, in a row). According to embodiments, tunnel lights 200A and 200B may be disposed in tunnels 300A and 300B. The uplink tunnel lights 200A may be disposed inside the uplink tunnel 300A, and the downlink tunnel lights 200B may be disposed inside the downlink tunnel 300B.

According to embodiments, the tunnel lights 200A and 200B may be disposed for each lane, or for each end lane, but embodiments of the present invention are not limited thereto.

Hereinafter, the embodiments described in the present specification target tunnel lights 200A and 200B arranged side by side in the tunnel 300, but embodiments of the present invention may be applied to other lighting other than tunnel lights. Those of ordinary skill in the art will understand that the embodiments of the present invention may be applied to a plurality of (especially, side by side) lights arranged in a specific place. For example, embodiments of the present invention may be applied to a plurality of street lights arranged side by side on a road side.

2 shows a tunnel light control system according to embodiments of the present invention. Referring to FIG. 2, for convenience of explanation, tunnel lights 200A and 200B of FIG. 1 are shown as tunnel lights 200, and tunnels 300A and 300B are shown as tunnel 300.

The tunnel lamp control system 10 may include a tunnel lamp controller 100 and a plurality of tunnel lamps 200 (typically 200, n is a natural number of 2 or more).

The tunnel lamp controller 100 may control the operation of the plurality of tunnel lamps 200. According to embodiments, the tunnel lamp controller 100 may output a control signal for controlling operations related to light emission of the plurality of tunnel lamps 200 to the plurality of tunnel lamps 200. For example, the tunnel lamp controller 100 may output a control signal for adjusting the brightness, light emission period, or light emission pattern of the plurality of tunnel lights 200.

The tunnel lamp controller 100 may be connected to the plurality of tunnel lamps 200 through a power line PL, and may output a power line signal (PLS) through the power line PL. The power line signal PLS may include a control signal and power for controlling the plurality of tunnel lights 200. The tunnel lamp controller 100 and the plurality of tunnel lamps 200 may exchange data through a power line communication method.

The tunnel lamp controller 100 may store arrangement data indicating an arrangement of a plurality of tunnel lamps 200. The arrangement data may include a position from a reference position (eg, the entrance or exit of the tunnel 300) of each of the plurality of tunnels 200 (eg, the number of times the tunnel is disposed from the reference position). . For example, when the first tunnel light 200 is disposed at the tenth position from the reference position, the placement data corresponding to the first tunnel light 200 may indicate “10”, but is not limited thereto.

According to embodiments, an identifier of each of the plurality of tunnel lights 200 may indicate the location of each of the plurality of tunnel lights 200. For example, the order of the identifiers of the plurality of tunnel lights 200 may be related to the arrangement order of the plurality of tunnel lights 200. For example, the order of identifiers of the plurality of tunnels 200 and the order of arrangement of the plurality of tunnels 200 may be the same. In this case, the arrangement data may be composed of an identifier of each of the plurality of tunnels 200, and the tunnel controller 100 is placed adjacent to the target tunnel through the identifiers of each of the plurality of tunnels 200 It is possible to determine the indicator tunnel, etc.

For convenience of description, the following description will be made on the assumption that the arrangement data includes an identifier and a location of each of the plurality of tunnels 200.

A plurality of tunnels 200 may be disposed inside the tunnel 300. According to embodiments, the plurality of tunnels 200 may be disposed in the tunnel 300 in succession (or side by side) along the traveling direction of the tunnel 300.

The plurality of tunnel lights 200 may receive a control signal generated by the tunnel lamp controller 100 through the power line PL. In addition, the plurality of tunnel lights 200 may output a status signal indicating the state of the plurality of tunnel lights 200 through the power line PL, and the tunnel lamp controller 100 transmits the status signal to the power line PL. ) Through.

The plurality of tunnel lights 200 may receive power for operation through the power line PL.

In some cases, it is necessary to identify a specific tunnel light (hereinafter, “target tunnel, etc.”) among the plurality of tunnel lights 200. For example, when inspection or repair of a target tunnel, etc. is required, the administrator must visually identify the target tunnel, etc. among the plurality of tunnels 200.

In the present specification, the target tunnel or the like may be determined by an external input or may be determined by the tunnel controller 100. For example, the target tunnel may be an abnormal tunnel that operates abnormally, a tunnel whose inspection period has arrived, or a tunnel with a poor communication state, but is not limited thereto.

Since a plurality of tunnels 200 are continuously arranged inside the tunnel 300, it may be difficult to visually identify the location of the target tunnel. For example, it may be difficult to visually identify the location of the 100th tunnel among the plurality of tunnels 200. In particular, when the target tunnel or the like is similar in brightness to other tunnels, such identification may be more difficult. In addition, since the tunnel lights 200 may emit light at all times in order to maintain a certain brightness inside the tunnel 300, it may be difficult in reality to manipulate only the target tunnels to emit light individually.

The tunnel lamp controller 100 according to embodiments of the present invention may determine an indicator tunnel lamp disposed adjacent to a target tunnel lamp, and control the indicator tunnel lamp in a light emission mode that is distinct from the other tunnel lamps. Accordingly, the administrator can easily identify the location of the indicator tunnel, etc. with the naked eye, and consequently, the location of the indicator tunnel, etc. adjacent to the indicator tunnel, etc. can be easily identified with the naked eye.

According to embodiments, the target tunnel or the like may not be visually distinguished from the other tunnels other than the target tunnel or the like. For example, the difference between the brightness of the target tunnel, etc. and the brightness of the other tunnels excluding the target tunnel, etc. may be such that it cannot be distinguished by the naked eye.

3 shows a tunnel light control system according to embodiments of the present invention. Referring to FIG. 3, the tunnel lamp controller 100 may be connected to a plurality of tunnel lamps 200 through a power line PL.

The tunnel lamp controller 100 may transmit a control signal CS to the plurality of tunnel lamps 200. The control signal CS may be a signal for controlling light emission of each of the plurality of tunnel lights 200. For example, each of the plurality of tunnel lights 200 may emit light in a corresponding light emission mode in response to the control signal CS.

According to embodiments, the control signal CS is a first control signal for controlling each of the plurality of tunnel lights 200 in a number display mode, and an indicator tunnel lamp among the plurality of tunnel lights 200 is set to the indicator light emission mode. It may include a second control signal for controlling and a third control signal for controlling other tunnel lights of the plurality of tunnel lights 200 except for the indicator tunnel lights in a non-indicator light emission mode.

The plurality of tunnel lights 200 may emit light in a corresponding light emission mode in response to a control signal transmitted from the tunnel lamp controller 100.

4 shows a tunnel, etc. according to embodiments of the present invention. The tunnel lamp 200 shown in FIG. 4 representatively represents the plurality of tunnel lamps 200 shown in FIG. 2.

4, the tunnel lamp 200 includes a memory 210, a power line communication unit 220, a light emission control unit 230, a power supply unit 240, and a plurality of lamp modules 250-1 to 250-m; m May include 2 or more natural numbers).

The memory 210, the power line communication unit 220, and the light emission control unit 230 may be referred to as a tunnel light control circuit.

The memory 210 may store data necessary for the operation of the tunnel light 200. According to embodiments, the memory 210 may store the identifier of the tunnel light 200.

The identifier of the tunnel light 200 may be data for distinguishing the tunnel light 200 from other tunnels. For example, the identifier of the tunnel light 200 may be associated with at least one of the arrangement order and location of the tunnel light. For example, when the tunnel lamp 200 is a tunnel lamp disposed tenth from the entrance side, the identifier of the tunnel lamp 200 may be 10, but is not limited thereto.

In addition, according to embodiments, the memory 210 may store arrangement data for the tunnel lamp 200 and a tunnel adjacent to the tunnel lamp 200. For example, when the tunnel 200 is a k-th tunnel, the memory 210 may store identifiers such as tunnels such as the (k-1)-th tunnel and the (k+1)-th tunnel, but the implementation of the present invention Examples are not limited thereto.

In addition, the memory 210 may store identifiers of the plurality of lamp modules 250-1 to 250-m and set values for controlling the emission mode of the plurality of lamp modules 250-1 to 250-m. have. For example, the memory 210 may store a setting value for controlling at least one of emission brightness, emission frequency, emission color, power consumption, current, and voltage of the plurality of lamp modules 250-1 to 250-m. .

The power line communication unit 220 may receive a control signal CS output from the tunnel controller 100 through the power line PL. According to embodiments, the power line communication unit 220 receives the power line signal PLS transmitted through the power line PL, obtains a control signal CS from the power line signal PLS, and obtains the control signal CS. May be transmitted to the light emission control unit 230.

The light emission control unit 230 may control light emission of the plurality of lamp modules 250-1 to 250-m.

According to embodiments, the light emission control unit 230 may control the current or voltage supplied to the plurality of lamp modules 250-1 to 250-m by controlling the power supply unit 240, and as a result, a plurality of Light emission of the lamp modules 250-1 to 250-m may be controlled.

For example, the light emission control unit 230 adjusts the intensity of the supply current to the plurality of lamp modules 250-1 to 250-m of the power supply unit 240 (analog control) or the plurality of lamp modules 250-1 By adjusting the frequency of the supply current to ~250-m (pulse width control), light emission of the plurality of lamp modules 250-1 to 250-m can be controlled. The light emission control unit 230 may output a light emission control signal ECS to the power supply unit 240. The emission control signal ECS may be a signal for adjusting characteristics of a current or voltage output from the power supply unit 240 to each of the lamp modules 250-1 to 250-m.

According to embodiments, the light emission control unit 230 reads a set value corresponding to the control command included in the control signal CS, and outputs the light emission control signal ECS according to the light emission mode corresponding to the read set value. I can.

The power supply unit 240 may supply power (eg, voltage or current) to the plurality of lamp modules 250-1 to 250-m. According to embodiments, the power supply unit 240 may supply power to the plurality of lamp modules 250-1 to 250-m by using the power PW received through the power line PL. For example, the power supply unit 240 converts AC power PW received through the power line PL into DC power, and supplies power to the plurality of lamp modules 250-1 to 250-m. have.

According to embodiments, the power supply unit 240 may supply power to the plurality of lamp modules 250-1 to 250-m based on the light emission control signal ECS transmitted from the light emission control unit 230. For example, the power supply unit 240 may selectively supply power to each of the plurality of lamp modules 250-1 to 250-m according to the light emission control signal ECS transmitted from the light emission control unit 230.

The plurality of lamp modules 250-1 to 250-m may emit light based on the supplied power. According to embodiments, the plurality of lamp modules 250-1 to 250-m may be an LED lamp module including light emitting diode (LED) devices, a halogen lamp module, or a sodium lamp module, but embodiments of the present invention They are not limited to the type of lamp module.

The plurality of lamp modules 250-1 to 250-m may be arranged in rows, columns, or along rows and columns. For example, the plurality of lamp modules 250-1 to 250-m may be arranged in a matrix form. For example, when the number of the plurality of lamp modules 250-1 to 250-m is 10, the plurality of lamp modules 250-1 to 250-m may be arranged in a 2 * 5 matrix form, It is not limited thereto.

The tunnel lamp 200 according to embodiments of the present invention may visually indicate a value associated with the identifier of the tunnel lamp 200. For example, a first lamp module disposed at a position corresponding to a value associated with an identifier of the tunnel lamp 200 among the plurality of lamp modules 250-1 to 250-m may be turned on. In addition, among the plurality of lamp modules 250-1 to 250-m, the remaining second lamp modules excluding the first lamp module may be turned off.

As described above, since the plurality of lamp modules 250-1 to 250-m may be arranged in a matrix form, the lamp modules (ie, first lamp modules) at a position corresponding to the value associated with the identifier are turned. By being turned on, a value (or number) associated with the identifier may be visually displayed in the plurality of lamp modules 250-1 to 250-m.

5 to 7 show lamp modules of a tunnel lamp according to embodiments of the present invention. For convenience of explanation, the memory 210, the power line communication unit 220, the light emission control unit 230, and the power supply unit 240 described with reference to FIG. 4 are omitted.

1 to 7, the tunnel lamp 200 may include a plurality of lamp modules 250-1 to 250-10. For convenience of explanation, the tunnel lamp 200 described with reference to FIGS. 5 to 7 is shown to include 10 lamp modules 250-1 to 250-10, but embodiments of the present invention are limited thereto. It does not become.

As shown in FIG. 5, the light emission control unit 230 may output a light emission control signal ECS for controlling light emission of each of the plurality of lamp modules 250-1 to 250-10, and the power supply unit ( 240 may adjust power supplied to the plurality of lamp modules 250-1 to 250-10 according to the emission control signal ECS. Accordingly, each of the plurality of lamp modules 250-1 to 250-10 may be turned off or turned on.

Hereinafter, for convenience, in this specification, the meaning that the light emission control unit 230 turns on and off the plurality of lamp modules 250-1 to 250 -m means that the light emission control unit 230 is the power supply unit 240 It means controlling turn-on and turn-off of the plurality of lamp modules 250-1 to 250-m by controlling.

The light emission control unit 230 controls light emission of each of the plurality of lamp modules 250-1 to 250-10 in response to a first control signal for controlling the number display mode transmitted from the tunnel lamp controller 100. A light emission control signal ECS for may be output.

6 to 8, based on the identifier of the tunnel lamp 200, the light emission control unit 230 turns on the first lamp module among the plurality of lamp modules 250-1 to 250-10, and The power supply unit 240 may be controlled so that the second lamp module is turned off.

According to embodiments, the light emission control unit 230 is positioned at a position corresponding to the associated value among the plurality of lamp modules 250-1 to 250-10 so that the value associated with the identifier of the tunnel lamp 200 is visually displayed. The power supply unit 240 may be controlled so that the arranged first lamp module is turned on.

For example, the light emission control unit 230 may determine the identifiers of the first lamp modules to be turned on among the identifiers of each of the lamp modules 250-1 to 250-10 from the memory 210 based on the identifier of the tunnel lamp 200. It may selectively read and output a first emission control signal ECS1 indicating turn-on of the first lamp module based on the identifiers of the first lamp modules.

According to embodiments, the light emission control unit 230 determines the number of lamp modules associated with the identifier of the tunnel lamp 200 among the plurality of lamp modules 250-1 to 250-10 as the first lamp module, and the remaining lamps The modules may be determined as the second lamp module.

According to embodiments, the light emission control unit 230 divides the identifier of the tunnel lamp 200 by 10 among the lamp modules 250-1 to 250-m and performs turn-on of the number of first lamp modules corresponding to the remainder. An indicative light emission control signal ECS may be output. For example, as shown in FIG. 6, when the identifier of the tunnel lamp 200 is 6, the six lamp modules 250-1 to 250 at the front of the plurality of lamp modules 250-1 to 250-10 -6) may be turned on, and the remaining four lamp modules 250-7 to 250-10 may be turned off.

By visually checking the number of the turned-on lamp modules 250-1 to 250-6, the administrator can confirm that the identifier of the tunnel lamp 200 is 6.

In addition, according to embodiments, the light emission control unit 230 selects the number of lamp modules corresponding to each position of the decimal notation of the identifier of the tunnel lamp 200 among the plurality of lamp modules 250-1 to 250-10. The power supply unit 240 may be controlled to turn on at a specific time interval. For example, as shown in FIG. 7, when the identifier of the tunnel light 200 is 115, one corresponding to “1”, which is the value of the digit ^{of 115 of 10 2 (the digit of 100) at the first time point (t1).} The lamp module is turned on, and at the second time point (t2), one lamp module corresponding to “1”, which is the value ^{of the 10 1 digit (10 digit) of 115, is turned on, and the third time (t3)} Five lamp modules corresponding to “5”, which is the value of 115's 10 ^{0's digit (1's digit), can be turned on.}

The administrator confirms that the identifier of the tunnel light 200 is 115 by visually checking the number (eg, 1, 1, 5) of the lamp modules 250-1 to 250-6 turned on for a certain period of time. I can.

According to embodiments, the light emission control unit 230 includes first lamp modules disposed at positions corresponding to the binary notation of the identifier of the tunnel lamp 200 among the plurality of lamp modules 250-1 to 250-m. A light emission control signal ECS for turning on may be output. For example, among the plurality of lamp modules 250-1 to 250-m, a first lamp module disposed at a position corresponding to a power of 2 having a value of 1 in the binary notation of the identifier of the tunnel lamp 200 Are turned on, and, among the plurality of lamp modules 250-1 to 250-m, are arranged at a position corresponding to the multiplier of 2 having a value of 0 in the binary notation of the identifier of the tunnel lamp 200. The second lamp modules may be turned off.

Each of the plurality of lamp modules 250-1 to 250-m corresponds to each digit (two digits) in the binary notation, and turns on each of the plurality of lamp modules 250-1 to 250-m And turn-off may represent "1" and "0" in the binary system, respectively. For example, as illustrated in FIG. 8, each of the lamp modules 250-1 to 250-10 may correspond to each position in the binary notation. The first lamp module 250-1 ^{corresponds to the position of 2 0} = 1 in binary notation, and the second lamp module 250-2 ^{corresponds to the position of 2 1} =2, and similarly, the tenth lamp module (250-10) corresponds to the place of ^{2 10 =1024.} If the identifier of the tunnel light 200 is 11 in decimal notation, since 11 ₍₁₀₎ =1011 ₍₂₎ , the first lamp module 250-1, the second lamp module 250-2, and the fourth lamp module 250-4 is turned on, and the remaining lamp modules 250-3 and 250-5 to 250-10 are turned off.

The administrator can confirm that the identifier of the tunnel lamp 200 is 1011(2)=11 by checking the positions of the turned-on lamp modules 250-1, 250-3, and 250-4.

9 is a flow chart showing the operation of a tunnel, etc. according to embodiments of the present invention. The operation method to be described with reference to FIG. 9 may be implemented in the form of a program stored in a computer-readable storage medium.

1 to 9, the tunnel lamp 200 may receive a first control signal indicating the number display mode from the tunnel lamp controller (S110). According to embodiments, the power line communication unit 220 may receive the first control signal transmitted through the power line PL.

The tunnel light 200 may read its own identifier of the tunnel light 200 (S120). According to embodiments, the light emission control unit 230 may read the identifier of the tunnel lamp 200 from the memory 210.

The tunnel lamp 200 may determine first lamp modules disposed at a position corresponding to a value associated with the tunnel lamp 200's own identifier among the plurality of lamp modules 250-1 to 250-m (S130). . According to embodiments, the light emission control unit 230 visually indicates a value associated with the identifier of the tunnel lamp 200, a value associated with the identifier to be turned on among the plurality of lamp modules 250-1 to 250-m The first lamp modules disposed at positions corresponding to may be determined.

For example, the light emission control unit 230 may determine the number of lamp modules corresponding to the remainder of the identifier of the tunnel lamp 200 divided by 10 among the plurality of lamp modules 250-1 to 250-m as the first lamp modules. have.

For example, the light emission control unit 230 may determine the number of lamp modules corresponding to each position in the decimal notation of the identifier of the tunnel lamp 200 from among the plurality of lamp modules 250-1 to 250-m.

For example, the light emission control unit 230 determines, as the first lamp modules, lamp modules disposed at positions corresponding to the binary notation of the identifier of the tunnel lamp 200 among the plurality of lamp modules 250-1 to 250-m. I can.

The tunnel lamp 200 may turn on the determined first lamp modules and may turn off the remaining lamp modules (S140). According to embodiments, the light emission control unit 230 reads the determined identifiers of the first lamp modules from the memory 210, and instructs the turn-on of the first lamp modules based on the read identifiers of the first lamp modules. The emission control signal ECS (eg, a first emission control signal) may be output to the power supply unit 240. In addition, the light emission control unit 230 includes a light emission control signal (ECS) (e.g., a second lamp module) indicating turn-off of the remaining lamp modules except for the first lamp module among the plurality of lamp modules 250-1 to 250-m. The light emission control signal) may be output to the power supply unit 240.

According to embodiments, the power supply unit 240 includes a switch circuit for selectively passing current and a light emitting circuit receiving current from the switch circuit, and the switch circuit is turned in response to a light emission control signal ECS. Can be turned off or turned on. For example, the switch circuit may pass or block current in response to the light emission control signal ECS.

The tunnel light 200 according to the embodiments of the present invention can visually indicate a value associated with the tunnel light 200's own identifier, and accordingly, the manager of the tunnel The identifier of the back 200 can be easily identified.

10 and 11 illustrate a tunnel light control system according to embodiments of the present invention. 1 to 10, the tunnel lamp control system 10 may include a plurality of tunnel lamps 200.

Referring to FIG. 10, when dozens or hundreds of tunnels 200 are arranged in a tunnel, the administrator ADMIN cannot easily identify which tunnel or the like is a tunnel arranged at a specific location. For example, when all of the plurality of tunnel lights 200 are in the light-emitting operation, it may be difficult to visually identify the fifth (eg, from the tunnel entrance) of the plurality of tunnel lights 200.

The tunnel lamp 200 according to the embodiments of the present invention may visually indicate a value associated with the tunnel lamp 200's own identifier. Accordingly, the administrator ADMIN can visually check the identifier of the tunnel light 200 through the tunnel light 200, and from this, it is possible to check the number of times the tunnel light 200 is disposed.

Referring to FIG. 11, the tunnel lights 200 may enter the number display mode under the control of the tunnel lamp controller 100, and in the number display mode, each of the tunnel lights 200 is associated with its own identifier. Values can be displayed visually. For example, each of the tunnels 200 may turn on first lamp modules disposed at a location corresponding to a value associated with its identifier.

According to embodiments, the identifier of each of the tunnel lights 200 may be associated with the order (or location) in which the tunnel lights 200 are arranged. For example, in the embodiment of FIG. 11, assume that the identifier of the first tunnel is 1 and the identifier of the fifth tunnel is 5. According to embodiments of the present invention, the first tunnel lamp may turn on one lamp module, and the fifth tunnel lamp may turn on five lamp modules. Accordingly, the administrator ADMIN can confirm that the tunnel lamp in which the five lamp modules are turned on is the tunnel lamp disposed in the fifth.

As such, the administrator ADMIN can visually identify the number of lamp modules turned on in each tunnel lamp, thereby confirming the identifier of the corresponding tunnel lamp. Furthermore, when the identifier of each of the tunnel lights 200 indicates the arrangement order of each of the tunnel lights 200, the administrator (ADMIN) visually identifies the number of lamp modules turned on in each of the tunnel lights, It is easy to identify which tunnel light is arranged in the tunnel.

In addition, as in the embodiment shown in FIG. 8, when each of the lamp modules 250-1 to 250-m of the tunnel lamp 200 represents each digit in the binary system, the administrator ADMIN is the tunnel lamp ( The identifier of the tunnel lamp 200 can be identified through the positions of the turned-on lamp modules 250-1 to 250-m of 200 ).

12 shows a controller such as a tunnel according to embodiments of the present invention. 1 to 12, the tunnel light controller 100 includes a memory 110, a mode setting unit 120, a target tunnel light determination unit 130, an indicator tunnel light determination unit 140, and a control unit 150. ) Can be included.

The memory 110 may store data necessary for the operation of the controller 100 such as a tunnel.

The memory 110 may store an identifier of each of the plurality of tunnels 200. According to embodiments, a target identification (TID) of a plurality of tunnels 200 may be stored.

The identifier (TID) of the target tunnel, etc. may be distinguished from the identifiers of other tunnels excluding the target tunnel among the plurality of tunnels 200 and stored. For example, the identifiers of the plurality of tunnels 200 may be matched and stored with a flag, and a flag (eg, “1”) matched with an identifier (TID) of a target tunnel, etc. and identifiers of the remaining tunnels Flags matched to (eg, “0”) may be different from each other.

According to embodiments, the identifier (TID) of the target tunnel may be input from the outside, or may be generated and stored by the tunnel controller 100 based on a status signal transmitted from the plurality of tunnel lights 200. In addition, the memory 110 may store arrangement data indicating an arrangement of a plurality of tunnels 200. The arrangement data may include a position from a reference position (e.g., the entrance or exit of the tunnel 300) of each of the plurality of tunnels 200 (e.g., the number of tunnels arranged from the reference position). have.

The memory 110 may include at least one of a nonvolatile memory and a volatile memory.

The mode setting unit 120 may generate a target display mode activation signal MAS. According to embodiments, when receiving an input instructing activation of the target display mode, the mode setting unit 120 may generate a target display mode activation signal MAS and output the generated target display mode activation signal MAS. have. For example, an input for instructing activation of the target display mode may be input from an input device (eg, a keyboard or a touch panel) provided in the controller 100 such as a tunnel, or may be input from the memory 110, but is not limited thereto.

When the target display mode is activated, the controller 100 controls an indicator tunnel light among the plurality of tunnel lights 200 as an indicator mode, and at least some of the remaining tunnel lights excluding the indicator tunnel light is in the indicator mode. It can be controlled in a different non-indicator mode. Accordingly, the administrator can easily identify the location of the target tunnel or the like by identifying the indicator tunnel or the like that emits light in the indicator mode.

The operation of tunnel lights in indicator mode and tunnel lights in non-indicator mode may be different. According to embodiments, at least one of the number of light-emitting lamps in the indicator mode, light emission brightness, light emission frequency, light emission color, power, current, and voltage is the number of light emission lamps in the non-indicator mode, light emission brightness, and emission frequency. , Light emission color, power, current, and voltage may be different from the corresponding at least one, but embodiments of the present invention are not limited thereto. For example, a tunnel light in a non-indicator mode may not flicker when viewed with the naked eye, whereas a tunnel light in an indicator mode may flicker when viewed with the naked eye.

When the target display mode is deactivated, the controller 100 may control the plurality of tunnel lights 200 in a non-indicator mode.

Meanwhile, according to embodiments, the mode setting unit 120 may be omitted.

The target tunnel, etc. determination unit 130 may determine a target tunnel, etc. According to embodiments, the target tunnel light determiner 130 may determine a target tunnel light in response to the mode activation signal MAS.

According to embodiments, the target tunnel light determination unit 130 may determine a target tunnel, etc. based on identifiers of a plurality of tunnels 200 stored in the memory 110 with reference to the memory 110. For example, the target tunnel, etc. determining unit 130 may determine a target tunnel, etc. by referring to flags matched with the identifiers of the plurality of tunnels 200 stored in the memory 110.

The target tunnel, etc. determination unit 130 may output an identifier (TID) of a target tunnel, etc.

The indicator tunnel light determination unit 140 may determine an indicator tunnel light disposed adjacent to the target tunnel light among the plurality of tunnel lights 200. For example, the indicator tunnel light determination unit 140 may determine a tunnel, etc., disposed immediately next to a target tunnel, among a plurality of tunnel lights 200 that are successively arranged as an indicator tunnel.

According to embodiments, the indicator tunnel light determination unit 140 may determine the indicator tunnel, etc. by using the arrangement data stored in the memory 110 and an identifier such as an indicator tunnel.

The indicator tunnel, etc. determination unit 140 may output an indicator (IID) of the determined indicator tunnel.

The controller 150 may output a control signal CS for controlling the operation of the plurality of tunnel lights 200.

According to embodiments, the controller 150 may output a first control signal for controlling each of the plurality of tunnel lights 200 in the number display mode through the power line PL.

In addition, the control unit 150 includes an identifier (IID) of the indicator tunnel, etc. determined by the indicator tunnel light determination unit 140 among the plurality of tunnel lights 200 and a control command indicating the indicator mode. 2 The control signal can be output through the power line PL.

In addition, the control unit 150 transmits a third control signal including an identifier of at least some of the remaining tunnel lights excluding the indicator tunnel light among the plurality of tunnel lights 200 and a control command indicating a non-indicator mode. It can be printed through (PL).

13 is a flow chart showing the operation of a controller such as a tunnel according to embodiments of the present invention. 1 to 13, the tunnel light controller 100 may activate a target display mode (S210). According to embodiments, the tunnel light controller 100 may generate a mode activation signal MAS based on an external input.

The tunnel controller 100 may identify a target tunnel, etc. using an identifier (TID) of the target tunnel (S220).

An identifier (TID) such as a target tunnel may be input from the outside, or may be generated and stored by the controller 100 such as a tunnel.

According to embodiments, the tunnel lamp controller 100 determines the operation state of each of the plurality of tunnel lamps 200 based on a state signal transmitted from the plurality of tunnel lamps 200, and a plurality of A target tunnel, etc., may be selected from among the tunnels 200 and the selected target tunnel identifier (TID) may be stored in the memory 110. For example, the status signal may include information on voltage, current, power, or brightness of the plurality of tunnel lights 200, but is not limited thereto.

The tunnel controller 100 reads an identifier (TID) of a target tunnel, etc. from the memory 110, and uses the read identifier (TID) of a target tunnel, etc. Can be identified.

The tunnel light controller 100 may determine an indicator tunnel light disposed adjacent to the target tunnel light (S230). According to embodiments, the tunnel light controller 100 may determine an indicator tunnel, etc. by using an identifier (TID) of a target tunnel and the like and arrangement data indicating the positions of the plurality of tunnels 200.

The tunnel controller 100 may read batch data from the memory 110. The tunnel light controller 100 may determine an indicator tunnel disposed adjacent to the target tunnel among the plurality of tunnel lights 200 by using an identifier (TID) of a target tunnel and the read arrangement data. According to embodiments, the tunnel light controller 100 may determine an arrangement position of a target tunnel, etc. based on the arrangement data, and may determine a tunnel or the like arranged in a position adjacent to the arrangement position of the target tunnel, as an indicator tunnel, etc. .

For example, the plurality of tunnel lights 200 may be arranged in a row and side by side in succession, and the indicator tunnels may refer to a tunnel or the like that is disposed directly on the side of the target tunnel or the like in the same row as the target tunnel or the like. For example, when the target tunnel is a third tunnel in the first row, etc., the indicator tunnel may be a second tunnel in the first row or a fourth tunnel.

The tunnel lamp controller 100 may output a second control signal for controlling the determined indicator tunnel lamp in the indicator mode (S250).

The tunnel lamp controller 100 may output a second control signal including an identifier (IID) of the indicator tunnel lamp and a control command indicating the indicator mode. According to embodiments, the controller 100 such as a tunnel reads a set value indicating an indicator mode from the memory 110, generates a control command based on the read set value, and generates a control command and an indicator tunnel. It is possible to generate a second control signal including an identifier (IID) such as.

Since the manager who manages the plurality of tunnel lights 200 can visually recognize the location of the indicator tunnels that emit light in the indicator mode, the location of the target tunnels arranged adjacent to the indicator tunnels can also be visually recognized. I can recognize it. Therefore, even if the manager does not count the plurality of tunnels 200 one by one, there is an effect that the location of the target tunnel can be easily identified by identifying the location of the indicator tunnel.

As described above, the embodiments of the present invention may be similarly applied not only to a tunnel lamp, but also to a plurality of (especially, side by side) lights arranged in a specific place. For example, when a plurality of streetlights are arranged, an indicator streetlight disposed adjacent to the target streetlight among the plurality of streetlights may emit light in the indicator mode, and the manager may not count the plurality of streetlights individually, the position of the indicator streetlight. There is an effect that can easily identify the location of the target street light by identifying the.

14 is a diagram for explaining the operation of a controller such as a tunnel according to embodiments of the present invention. 1 to 14, the tunnel lamp control system 10 includes a plurality of tunnel lamps 200, and the k-th tunnel lamp (1≤k≤n) among the plurality of tunnel lamps 200 is It is assumed that it is a target tunnel, etc.

When the brightness of the k-th tunnel light and the brightness of the other tunnels other than the k-th tunnel light are not visually distinguished, the administrator (ADMIN) inside the tunnel 300 visually identifies where the k-th tunnel light is located. It can be difficult to do. For example, it may be difficult to visually identify a 100th tunnel or the like among the plurality of tunnel lights 200.

15 is a diagram for explaining an operation of a controller such as a tunnel according to embodiments of the present invention. 1 to 15, the tunnel lamp controller 100 may identify that the k-th tunnel lamp among the plurality of tunnel lamps 200 is a target tunnel lamp. According to embodiments, the tunnel controller 100 refers to the memory 110 and reads an identifier (eg, “TLk”) of a k-th tunnel, etc., stored as an identifier of a target tunnel, etc. Can be identified.

The tunnel lamp controller 100 may identify that the k-th tunnel lamp among the plurality of tunnel lamps 200 is a target tunnel lamp. According to embodiments, the tunnel controller 100 refers to the memory 110 and reads an identifier (eg, “TLk”) of a k-th tunnel, etc., stored as an identifier of a target tunnel, etc. Can be identified.

According to embodiments, the tunnel lamp controller 100 uses the status signal output from the plurality of tunnel lamps 200 to operate abnormally among the plurality of tunnel lamps 200 (eg, a k-th tunnel lamp, etc.). ), and an identifier (eg, “TLk”) of a target tunnel or the like (eg, k-th tunnel).

The tunnel light controller 100 determines an indicator tunnel light (eg, (k-1) th tunnel or the (k+1) th tunnel, etc.) disposed adjacent to the target tunnel light (eg, k-th tunnel, etc.) And, it is possible to output a second control signal for controlling the indicator tunnel, etc. in the indicator mode.

According to embodiments, the tunnel light controller 100 may identify a location of a target tunnel, etc. by referring to arrangement data stored in the memory 110 and determine an indicator tunnel disposed adjacent to the target tunnel or the like. The arrangement data may be data for storing identifiers and locations of a plurality of tunnel lights 200.

According to embodiments of the present invention, an indicator tunnel light (eg, (k-1)th tunnel, etc.) or (k+1)th tunnel, etc. disposed adjacent to a target tunnel light (eg, k-th tunnel, etc.) It can emit light in this indicator mode.

Accordingly, even if tens to hundreds of tunnels are located in the tunnel, the administrator can easily determine the location of the indicator tunnels that emit light in the indicator mode (A), and target tunnels arranged adjacent to the indicator tunnels, etc. It has the effect of being able to easily identify the location of (B).

The number display mode and the indicator mode (or non-indicator mode) according to embodiments of the present invention may operate superimposedly (eg, together). For example, an indicator tunnel light disposed adjacent to the target tunnel light may emit light in the indicator mode. At this time, the indicator tunnel or the like can also emit light according to the number display mode. That is, the indicator tunnel or the like can visually indicate a value associated with its own identifier. Accordingly, the ADMIN can easily grasp the location of the target tunnel, etc. arranged adjacent to the indicator tunnel through the indicator tunnel, as well as the identifier of the indicator tunnel from the light emission of the indicator tunnel. There is an effect of being able to check and, through this, check the identifier of the target tunnel. For example, when an identifier such as a tunnel indicates an arrangement order of a tunnel or the like, an identifier of a target tunnel or the like can be recognized from an identifier such as an indicator tunnel.

16 is a flow chart for explaining the operation of a tunnel, etc. according to embodiments of the present invention. In the embodiment described with reference to FIG. 9, the tunnel lamp controller 100 determines the indicator tunnel, while the embodiment described with reference to FIG. 16 is whether the tunnel lamp 200 itself is an indicator tunnel, etc. There is a difference that you decide.

1 to 16, the tunnel lamp 200 may receive an identifier of a target tunnel, etc. from the tunnel lamp controller 100 (S310). According to embodiments, the memory 210 may store an identifier such as a received target tunnel.

The tunnel light 200 may read its own identifier (S320). According to embodiments, the light emission control unit 230 may read an identifier of the tunnel lamp 200 from the memory 210.

The tunnel light 200 may determine whether the tunnel light 200 is disposed adjacent to the target tunnel, based on the identifier of the target tunnel and the like and its own identifier (S330).

According to embodiments, the light emission control unit 230 reads the batch data stored in the memory 210, and based on the batch data, the identifier of the target tunnel, and its own identifier, the location of the target tunnel and the like ( 200) may determine its own location, and determine whether the tunnel light 200 itself is disposed adjacent to the target tunnel or the like.

According to embodiments, the light emission control unit 230 may determine whether the tunnel lamp 200 itself is disposed adjacent to the target tunnel by comparing the identifier of the target tunnel lamp and the identifier of the tunnel lamp 200 itself. . For example, the memory 210 stores the identifiers of each of the plurality of tunnels, and the light emission control unit 230 is based on the identifiers of each of the plurality of tunnels, etc. When the identifier of the lamp 200 is in a continuous sequence, it may be determined that the tunnel lamp 200 is disposed adjacent to the target tunnel.

When the tunnel lamp 200 is disposed adjacent to the target tunnel lamp (Y in S330), the tunnel lamp 200 may emit light according to the indicator mode (S340). According to embodiments, when the tunnel lamp 200 is disposed adjacent to the target tunnel lamp, the light emission control unit 230 is a power supply unit so that the plurality of lamps 250-1 to 250-m emit light according to the indicator mode. 240) can be controlled. For example, the light emission control unit 230 may output an indicator light emission control signal to the power supply unit 240 for controlling a tunnel light disposed adjacent to the target tunnel light according to the indicator mode.

When the tunnel lamp 200 is not disposed adjacent to the target tunnel lamp (N in S330), the tunnel lamp 200 may emit light according to the non-indicator mode (S350). According to embodiments, when the tunnel light 200 is not disposed adjacent to the target tunnel light, the light emission control unit 230 causes the plurality of lamps 250-1 to 250-m to emit light according to the non-indicator mode. The power supply unit 240 can be controlled. For example, the light emission control unit 230 may output a non-indicator light emission control signal to the power supply unit 240 for controlling a tunnel light not disposed adjacent to the target tunnel light according to the non-indicator mode.

The tunnel light 200 according to the embodiments of the present invention determines whether the target tunnel light and the tunnel light 200 are disposed adjacent to each other, based on the identifier of the target tunnel, etc. transmitted from the tunnel light controller 100, and Accordingly, there is an effect of emitting light in an indicator mode or a non-display mode.

As described above, although the embodiments have been described with reference to limited embodiments and drawings, various modifications and variations are possible from the above description to those of ordinary skill in the art. For example, the described techniques are performed in a different order from the described method, and/or components such as systems, structures, devices, circuits, etc. described are combined or combined in a form different from the described method, or other components Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and those equivalent to the claims also fall within the scope of the claims to be described later.

100: tunnel light controller 200: tunnel light
300: tunnel PL: power line
210: memory 220: power line communication unit
230: light emission control unit 240: power supply unit
250-1~250-m: lamp modules

Claims (15)

In the tunnel light control circuit for controlling the tunnel light arranged in the tunnel,
A power line communication unit configured to receive a control signal from a controller such as a tunnel;
A memory configured to store an identifier such as the tunnel; And
And a light emission control unit configured to output a light emission control signal for controlling light emission of a plurality of lamp modules arranged in a matrix form,
The light emission control unit,
Read an identifier such as the tunnel from the memory,
To visually indicate a value associated with the identifier, a first lamp module disposed at a position corresponding to the identifier among the plurality of lamp modules is determined, and
Turning on the first lamp module and outputting the light emission control signal for turning off a second lamp module other than the first lamp module among the plurality of lamp modules,
The power line communication unit receives an identifier of a target tunnel, etc. from the tunnel controller,
The light emission control unit,
Using the identifier of the target tunnel and the like and the identifier of the tunnel, etc., it is determined whether the tunnel is disposed adjacent to the target tunnel, etc.
When the tunnel light is disposed adjacent to the target tunnel light, outputting an indicator light emission control signal for controlling the plurality of lamp modules according to an indicator mode,
When the tunnel light is not disposed adjacent to the target tunnel light, outputting a non-indicator light emission control signal for controlling the plurality of lamp modules according to a non-indicator mode different from the indicator mode,
The number of blinks during the reference time in the indicator mode is different from the number of blinks during the reference time in the non-indicator mode,
Tunnel light control circuit. The method of claim 1,
The identifier is a value indicating an arrangement order in the tunnel, such as the tunnel,
Tunnel light control circuit. The method of claim 2, wherein the light emission control unit,
Among the plurality of lamp modules, outputting the light emission control signal for turning on the number of the first lamp modules corresponding to the identifier,
Tunnel light control circuit. The method of claim 2, wherein the light emission control unit,
Among the plurality of lamp modules, the light emission control signal for sequentially turning on the number of the first lamp modules corresponding to the values of the multipliers of 10 in the decimal notation of the identifier at specific time intervals Outputting,
Tunnel light control circuit. The method of claim 2,
The position of each of the plurality of lamp modules corresponds to a power of 2 in binary notation,
The light emission control unit,
Turning on the first lamp module disposed at a position corresponding to a power of 2 having a value of 1 in the binary notation of the identifier, among the plurality of lamp modules, and among the plurality of lamp modules, Outputting the light emission control signal for turning off the second lamp module disposed at a position corresponding to a power of 2 having a value of 0 in the binary notation of the identifier,
Tunnel light control circuit. delete delete The method of claim 1,
The number of blinks during the reference time in the indicator mode is greater than the number of blinks during the reference time in the non-indicator mode,
Tunnel light control circuit. In a method of operating a tunnel lamp control circuit for controlling a tunnel lamp disposed in a tunnel and including a plurality of lamp modules arranged in a matrix form,
Storing an identifier indicating an arrangement order in the tunnel, such as the tunnel;
Reading an identifier such as the tunnel; And
To visually indicate a value associated with the identifier, a first lamp module disposed at a position corresponding to the identifier among the plurality of lamp modules is turned on, and the first lamp module among the plurality of lamp modules Including the step of outputting a light emission control signal for turning off the second lamp module except for,
The operation method of the control circuit such as the tunnel,
Receiving an identifier such as a target tunnel;
Determining whether the tunnel or the like is disposed adjacent to the target tunnel or the like by using the identifier of the target tunnel or the like and the identifier of the tunnel or the like;
Outputting an indicator light emission control signal for controlling the plurality of lamp modules according to an indicator mode when the tunnel lamp is disposed adjacent to the target tunnel lamp; And
When the tunnel light is not disposed adjacent to the target tunnel light, outputting a non-indicator light emission control signal for controlling the plurality of lamp modules according to a non-indicator mode different from the indicator mode. Including,
The number of blinks during the reference time in the indicator mode is different from the number of blinks during the reference time in the non-indicator mode,
How the tunnel light control circuit works. The method of claim 9, wherein the outputting the light emission control signal comprises:
Including the step of outputting the light emission control signal for turning-on the number of the first lamp modules corresponding to the number of the plurality of lamp modules,
How the tunnel light control circuit works. The method of claim 9, wherein the outputting the light emission control signal comprises:
Among the plurality of lamp modules, the light emission control signal for sequentially turning on the number of the first lamp modules corresponding to the values of the multipliers of 10 in the decimal notation of the identifier at specific time intervals Including the step of outputting,
How the tunnel light control circuit works. The method of claim 9,
The position of each of the plurality of lamp modules corresponds to a power of 2 in binary notation,
The step of outputting the light emission control signal,
Turning on the first lamp module disposed at a position corresponding to a power of 2 having a value of 1 in the binary notation of the identifier, among the plurality of lamp modules, and among the plurality of lamp modules, Including the step of outputting the light emission control signal for turning off the second lamp module disposed at a position corresponding to a power of 2 having a value of 0 in the binary notation of the identifier,
How the tunnel light control circuit works. delete delete The method of claim 9,
The number of blinks during the reference time in the indicator mode is greater than the number of blinks during the reference time in the non-indicator mode,
How the tunnel light control circuit works.

Images