KR20130130497A - Helideck lighting diagnosis apparatus and method of the same - Google Patents

Abstract

The present invention discloses a device for diagnosing helideck lighting. The device for diagnosing the helideck lighting of one embodiment of the present invention comprises a surveillance camera photographing the image of lighting equipment mounted at a helideck; a real time image capture module extracting an image of set unit time from real time images transmitted by the surveillance camera; an image analyzing module analyzing the unit time image transmitted from the image capture module; a lighting equipment diagnosing module diagnosing the lighting equipment by comparing an image processed at the image analyzing module with an stored normal image; and a helideck monitoring system (HMS) monitor displaying results transmitted from the lighting equipment diagnosing module. [Reference numerals] (10) Surveillance camera;(20) Real time image capture module;(30) Image analyzing module;(40) Lighting equipment diagnosing module;(50) HMS monitor

Description

[0001] DESCRIPTION [0002] HELDECK LIGHTING DIAGNOSIS APPARATUS AND METHOD OF THE SAME [

The present invention relates to an apparatus and method for diagnosing a helideck illumination failure.

A large ship or a beach platform is equipped with a helideck for the helicopter's take-off and landing. Helidecks are equipped with lighting so that helicopters can safely take off and land at night.

Helideck's lighting facilities are not simply instruments that ensure brightness, but they follow the brightness, color, and signaling scheme of the international regulations set by national and regional aviation safety management centers. Lighting fixtures include a wide range of lighting-related equipment.

In this way, lighting fixtures operated by helidecks play an important role in the safety of helicopters. Reliability of lighting fixtures and reliability of lighting fixtures is important.

In addition, the helideck's lighting fixtures are much more constrained in location than on land. Therefore, once installed lighting equipment should be operated with minimum maintenance and stability for a long period of time.

Helideck lighting fixtures can be installed in packages or individually installed and managed for each purpose. Generally, each lighting equipment is configured to control by operating a lighting switch provided in a central control panel. However, Helideck's lighting facilities are not equipped with the ability to be integratedly managed or to implement maintenance through automation of fault diagnosis.

An embodiment of the present invention provides a helideck illumination fault diagnosis apparatus and method for automating fault diagnosis of a helideck illumination to enable fault diagnosis and integrated management of illumination facilities.

A helideck illumination failure diagnosis apparatus according to an embodiment of the present invention includes a surveillance camera that captures an image of a lighting facility installed in a helideck, a real-time image capture module that extracts a real-time image transmitted from the surveillance camera, An illumination device failure diagnosis module for diagnosing an illumination facility by comparing the image image processed by the image image analysis module with a stored normal image image, And a helideck monitoring system (HMS) monitor for displaying the results transmitted from the equipment fault diagnosis module.

The image analysis module may derive coordinates of the lighting fixture from the image extracted by the image capture module.

The lighting fixture failure diagnostic module may load a normal image for the coordinates of the lighting fixture.

The lighting equipment failure diagnosis module may compare the extracted image with the color value of the normal image to determine whether the difference in color value is out of the set value.

A method for diagnosing an illumination failure of a helideck according to an embodiment of the present invention includes a real-time image capturing step of extracting a real-time image transmitted from a surveillance camera according to a set unit time, a step of analyzing an image per unit time transmitted in the image capturing step An image analyzing step, an illumination equipment failure diagnosis step of diagnosing an illumination facility by comparing the image image processed in the image image analysis step with a stored normal image image, and a result of the illumination equipment failure diagnosis step is transmitted to a helideck monitoring system ) Display on the monitor.

The image image analyzing step may derive the coordinates of the lighting equipment from the image extracted in the image capturing step.

The lighting fixture failure diagnosis step may load a normal image for the coordinates of the lighting fixture.

In the lighting equipment failure diagnosis step, it is possible to determine whether the difference of the color values is out of the set value by comparing the extracted image with the color value of the normal image.

In an embodiment of the present invention, the image information of the helideck lighting equipment is acquired in real time through a surveillance camera, the real-time acquired image is extracted as a time-based image, and the extracted image is compared with the stored normal image, The fault can be identified.

1 is a block diagram of a helideck illumination failure diagnosis apparatus according to an embodiment of the present invention.
2 is a layout diagram of a lighting fixture installed in a helideck.
3 is a layout diagram of the unique coordinates identifying the lamps installed in the helideck.
4 is a flowchart of a method for diagnosing a helideck illumination failure according to an embodiment of the present invention.
5 is a state diagram showing a process of diagnosing the steady state of the lighting fixture.
6 is a state diagram showing a process of diagnosing a fault condition of the lighting equipment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

FIG. 1 is a block diagram of a helideck illumination failure diagnosis apparatus according to an embodiment of the present invention, and FIG. 2 is a layout diagram of a lighting facility installed in a helideck.

Referring to FIGS. 1 and 2, the helideck illumination failure diagnosis apparatus of the embodiment obtains status information of the lighting equipment from the real-time image acquired through the surveillance camera 10 for CCTV (closed-circuit television) And the like.

That is, the helideck illumination failure diagnosis apparatus includes a surveillance camera 10, a video capture module 20, a video image analysis module 30, an illumination facility failure diagnosis module 40, and a helideck monitoring system (HMS) do.

The surveillance camera 10 captures an image of a lighting facility installed in the helideck 60 and delivers the captured image to the image capturing module 20 in real time. The heli-deck (60) has lamps (61) of the lighting fixture in a set unique position.

The surveillance camera 10 is installed at a position where the entirety of the helicopter 60 can be lit so that the surveillance camera 10 can capture an image of the panoramic view of the helicopter 60. That is, the surveillance camera 10 is fixedly installed at a set position so that the entire view of the helideck 60, that is, the entire illumination of the helideck 60, can be seen in the image range.

The image capture module 20 extracts an image per unit time of the real time image transmitted from the surveillance camera 10, that is, transmits the extracted image to the image image analysis module 30. The real-time image capturing module 20 transmits the extracted image extracted per unit time together with the time information obtained by acquiring the image image, thereby making it possible to use the acquisition time in the extracted image analysis.

3 is a layout diagram of the unique coordinates identifying the lamps installed in the helideck. Referring to FIG. 3, the helideck 60 gives unique coordinates to the lamps 61 of the lighting fixture. The coordinate data of the ramps 61 and the helideck 60 applied thereto can be embedded in the HMS.

For example, the helideck 60 is divided into A to K in the lateral direction and 1 to 11 in the longitudinal direction. Each ramp 61 has its own position with the unique coordinate in the helideck 6. For example, the lamp 61 is located at the coordinate E1. The failure diagnosis of the lamp 61 is possible by comparing the extracted image of the coordinate E1 with the normal image.

The video image analysis module (30) analyzes the extracted image per unit time transmitted from the video capture module (20). The image analysis module 30 analyzes the extracted image per unit time, divides the foreground image of the heliDeck 60 according to predetermined coordinates, and divides the foreground image into individual images necessary for the diagnosis of failure, and then divides the foreground image into a database (DB, not shown) And transmits the information to the lighting equipment failure diagnosis module 40. [ The DB may be connected to the HMS and be provided separately.

The lighting equipment failure diagnosis module 40 can diagnose the failure of the lighting equipment by comparing the image processed by the image analysis module 30, that is, the extracted image with the stored normal image.

The lighting equipment failure diagnosis module 40 receives the extracted image processed through the DB, analyzes the failure of the helideck 60 lamp 61, and finally determines whether the failure has occurred.

For this purpose, the image analysis module 30 and the lighting equipment failure diagnosis module 40 may include horizontal and vertical coordinate values for the helideck 60, in addition to the HMS.

The diagnostic result of the lighting equipment failure diagnosis module 40 can be classified as normal, need for inspection, or need for replacement since it is a failure analysis for the lighting equipment of the helideck 60, that is, the lamp 61. [ The analyzed result is transmitted to the HMS monitor 50.

The HMS monitor 50 displays the results transmitted from the lighting equipment failure diagnosis module 40. The HMS is a monitoring system for secure takeoff and landing of the helicopter as a system for monitoring comprehensive conditions such as the weather condition of the helideck 60.

Lighting equipment is a key equipment for nighttime helicopter landing and landing. Therefore, HMS can notify the user of the fault through the alarm when the lighting equipment is out of order.

4 is a flowchart of a method for diagnosing a helideck illumination failure according to an embodiment of the present invention. Referring to FIG. 4, the helideck illumination failure diagnosis method according to an exemplary embodiment includes an image capturing step ST10, an image image analyzing step ST20, a lighting equipment failure diagnosis step ST30, and a display step ST40 .

The image capturing step ST10 extracts a set time-based image of a real-time image captured by the surveillance camera 10 and transmitted.

The image analyzing step ST20 analyzes the extracted image per unit time transmitted in the image capturing step ST10. For example, the image image analyzing step ST20 derives the coordinates of the lighting equipment from the extracted image extracted in the image capturing step ST10.

In the lighting equipment failure diagnosis step ST30, the extracted image processed in the image image analysis step ST20 is compared with the stored normal image image to diagnose the lighting equipment.

For example, the lighting equipment failure diagnosis step ST30 loads a normal image with respect to the coordinates of the lighting equipment, compares the extracted image with the color value of the loaded normal image, determines whether the difference in color value is out of the set value do.

5 is a state diagram showing a process of diagnosing the steady state of the lighting fixture. 5, the lighting equipment failure diagnosis step ST30 compares the extracted image (left) with the normal image (right), compares the brightness of the image and the RGB color value, It is judged as normal (ST40).

6 is a state diagram showing a process of diagnosing a fault condition of the lighting equipment. 6, the lighting equipment failure diagnosis step ST30 compares the extracted image (left) with the normal image (right), compares the brightness of the image and the RGB color value, It is judged as a failure.

In the case of a failure judgment, the lighting equipment failure diagnosis step ST30 includes a replacement necessity step ST31 and an inspection necessity step ST32. In step ST31, if it is determined that there is a failure, it is determined that there is a facility that needs to be replaced.

When the facility needs to be replaced, the lighting equipment failure diagnosis step ST30 informs the HMS of the replacement required equipment (ST41) and records the corresponding information in the facility history (ST42).

The check necessity step ST32 is a step to be performed if it is judged to be a failure and replacement is not required in the replacement need step ST31, and it is judged whether there is a facility requiring inspection.

When the equipment is to be inspected, the lighting equipment failure diagnosis step ST30 notifies the HMS of the equipment to be inspected (ST41), and records the corresponding information in the equipment history (ST42).

The display step ST40 displays on the HMS monitor 50 a result transmitted in the lighting equipment failure diagnosis step ST30, that is, a result of normal or failure, a need for replacement during a failure, or an inspection necessary situation.

The present invention has been described above with reference to the embodiments shown in the drawings. However, the present invention is not limited thereto, and various modifications or other embodiments falling within the scope of the present invention are possible by those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined by the following claims.

10: Surveillance camera 20: Image capture module
30: image analysis module 40: illumination equipment failure diagnosis module
50: HMS monitor 60: Helideck
61: Lamp

Claims (8)

A surveillance camera for capturing an image of a lighting facility installed in the helideck;
A real-time image capturing module for extracting an image per unit time of a real-time image transmitted from the surveillance camera;
A video image analysis module for analyzing an image per unit time transmitted from the image capture module;
A lighting equipment failure diagnosis module for diagnosing the lighting equipment by comparing the video image processed by the video image analysis module with the stored normal image; And
A helideck monitoring system (HMS) monitor for displaying the results transmitted from the lighting equipment failure diagnosis module
Helen deck lighting failure diagnosis device comprising a.
The method of claim 1,
Wherein the image analysis module comprises:
Deriving the coordinates of the lighting equipment from the image extracted by the image capture module
Helideck lighting fault diagnosis device.
3. The method of claim 2,
The lighting equipment failure diagnosis module includes:
Loading a normal image for the coordinates of the lighting fixture
Helideck lighting fault diagnosis device.
The method of claim 3,
The lighting equipment failure diagnosis module includes:
By comparing the color values of the extracted image and the normal image, it is determined whether the difference of the color values is out of the set value
Helideck lighting fault diagnosis device.
A real-time image capturing step of extracting a set time-based image of a real-time image transmitted from a surveillance camera;
An image analyzing step of analyzing the image per unit time transmitted in the image capturing step;
A lighting equipment failure diagnosis step of diagnosing the lighting equipment by comparing the video image processed in the video image analysis step with the stored normal image; And
A display step of displaying a result transmitted in the lighting equipment failure diagnosis step on a helideck monitoring system (HMS) monitor
Heli deck lighting failure diagnostic method comprising a.
The method of claim 5,
The image analysis step may include:
Deriving the coordinates of the lighting equipment from the image extracted in the image capturing step
Helideck illumination fault diagnosis method.
The method according to claim 6,
In the lighting equipment failure diagnosis step,
Loading a normal image for the coordinates of the lighting fixture
Helideck illumination fault diagnosis method.
The method of claim 7, wherein
In the lighting equipment failure diagnosis step,
By comparing the color values of the extracted image and the normal image, it is determined whether the difference of the color values is out of the set value
Helideck illumination fault diagnosis method.

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