KR20210115540A - Lighting control device used to low frequency - Google Patents

Abstract

The present invention relates to a lighting control device for a space with low frequency of use, which is usually driven in a standby mode with low power, to have a long standby time, automatically illuminates a space for a short time by changing ambient illuminance or detecting motion, to provide temporary living lighting when a space with low frequency of use is used in real life, reduces unnecessary standby power, and brings convenience of space use. The lighting control device includes: an illumination sensor for measuring ambient light for an operating area; and a driving control unit for controlling an illumination driving unit to turn on a light source unit according to an illumination measurement result of the illumination sensor.

Description

LIGHTING CONTROL DEVICE USED TO LOW FREQUENCY

The present invention relates to a lighting control device for a space with low frequency of use, and more particularly, it is usually driven in a standby mode with low power, so that it has a long standby time and automatically controls the space for a short time by changing ambient illuminance or detecting motion. It relates to a lighting control device for a space with low frequency of use, which can provide temporary living lighting when using a space with low frequency of use in real life by making it illuminated, can reduce unnecessary standby power, and bring convenience of space use.

Conventional lighting devices are implemented in a way that power is supplied to the lighting by a switching operation by manipulating the switch artificially to turn on the light. Such a lighting device is installed in all spaces used by people, and a person who wants to use the space directly operates the lighting.

There is no major inconvenience or waste of power in turning on a lighting device using this switch-driven method because the space is continuously used for a relatively long time when used once, such as a general bedroom, kitchen, or office.

On the other hand, a space such as a closet has a characteristic that it is not used for a long time and therefore has a low frequency of use. have.

Although the closet is rarely used like this, it is difficult to see the inside when the surrounding lighting is not bright, so a separate light is needed to illuminate the inside even for a moment. However, it is difficult to newly install switch-type lighting using commercial power due to the nature of the space. Alternatively, a battery-powered human body recognition system can be installed instead of commercial power, but since it is a rarely used space, the standby time (automatic lighting consumes a lot of power in the standby time to detect a human body) is very long. It has a problem that the efficiency of use is extremely low compared to the price.

The present invention has been devised to solve the above problems, and the purpose is that it is usually driven in a standby mode with low power, so that it has a long standby time and automatically illuminates the space for a short time by changing ambient illuminance or motion detection. It is to provide a lighting control device for a space with a low frequency of use that can provide temporary living lighting when using a space with low frequency of use in real life, can reduce unnecessary standby power, and bring convenience of space use.

According to the present invention, there is provided an illuminance sensor for measuring ambient illuminance for an operating zone; a driving control unit for controlling the illumination driving unit according to the illuminance measurement result of the illuminance sensor to turn on the light source unit; Including, a standby mode for checking changes in illuminance of the area where the lighting is installed; a turn-on mode in which the light source unit is turned on for a set time when a change in illuminance is recognized in the standby mode; a turn-off mode for turning off the light source when a set time elapses in the turn-on mode; It provides a lighting control device, characterized in that divided and operated.

Preferably, in the standby mode, the driving controller determines the driving of the light source unit by setting a reference illuminance and comparing the measured illuminance value of the illuminance sensor with the reference illuminance.

Preferably, the reference illuminance includes a first reference illuminance value and a second reference illuminance value set as the illuminance value, and when the illuminance value measured by the illuminance sensor is equal to or greater than the first reference illuminance value, a lighting control signal is output, , when the measured illuminance value is less than or equal to the first reference illuminance value or greater than or equal to the second reference illuminance value, the lighting control signal is not output.

Preferably, the reference illuminance includes a first reference illuminance change width and a second reference illuminance change width set as the illuminance change width. If the output and the measured illuminance value is less than or equal to the first reference illuminance change width or greater than the second reference illuminance change width, the lighting control signal is not output.

Meanwhile, according to another aspect of the present invention, an illuminance sensor for measuring ambient illuminance for the operation zone; an image sensor that is driven according to a measurement result of the illuminance of the illuminance sensor to acquire image data for an operation area; an image recognition unit that receives image data captured from the image sensor and analyzes the received image data to detect an image change in an operation area; and a driving control unit for controlling the lighting driving unit to turn on the main light source according to the detection result of the image recognition unit. Including, a standby mode for checking changes in illuminance of the area where the lighting is installed; a confirmation mode for checking an image change when a change in illuminance is recognized in the standby mode; a turn-on mode in which the light source unit turns on for a set time when an image change is recognized in the confirmation mode; a turn-off mode for turning off the light source when a set time elapses in the turn-on mode; It is characterized in that it operates separately.

Preferably, in the standby mode, the driving controller determines the driving of the light source unit by setting a reference illuminance and comparing the measured illuminance value of the illuminance sensor with the reference illuminance.

Preferably, the reference illuminance includes a first reference illuminance value and a second reference illuminance value set as the illuminance value, and when the illuminance value measured by the illuminance sensor is equal to or greater than the first reference illuminance value, a lighting control signal is output, , when the measured illuminance value is less than or equal to the first reference illuminance value or greater than or equal to the second reference illuminance value, the lighting control signal is not output.

Preferably, the reference illuminance includes a first reference illuminance change width and a second reference illuminance change width set as the illuminance change width. If the output and the measured illuminance value is less than or equal to the first reference illuminance change width or greater than the second reference illuminance change width, the lighting control signal is not output.

Preferably, in the confirmation mode, whether a change of 3 to 5 times or more of the image noise is detected in the image captured through the image sensor is used as the image change standard, and the turn-on mode is switched to the turn-on mode when the standard is abnormal.

According to the present invention, it is usually driven in a low-power standby mode, so it has a long standby time and automatically illuminates the space for a short period of time by changing ambient illuminance or motion detection. It can be provided, and it is possible to reduce unnecessary standby power and has the effect of bringing convenience of space use.

Through this, there is an effect that a simplified configuration such as using a battery without using commercial power is possible.

1 is a view for explaining a lighting control device according to an embodiment of the present invention.
2 is a view for explaining an operation process of the lighting control device according to an embodiment of the present invention.
3 is a view for explaining a lighting control device according to another embodiment of the present invention.
4 is a diagram for explaining a circuit configuration of an image sensor according to another embodiment of the present invention.
5 is a view for explaining an operation process of a lighting control device according to another embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals have been used for like elements.

Terms such as first, second, A, and B may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that no other element is present in the middle.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view for explaining a lighting control device according to an embodiment of the present invention.

First, the lighting control device according to the present invention recognizes whether a person intends to use a space with low frequency of use through illuminance change or motion detection, and automatically turns on the tail lamp for a certain period of time to enable efficient use of the space. . In particular, in consideration of the fact that it is a space with low frequency of use, it is operated with low power in standby mode in consideration of the need to wait for a long time.

Referring to FIG. 1 , the lighting control device according to an embodiment of the present invention includes an illuminance sensor 120 for measuring ambient illuminance for an operating zone, and an illuminance value of the operating zone measured through the illuminance sensor 120. The driving control unit 140 outputs a light source control signal for turning on the light source unit 170 accordingly, and applying power to the light source unit 170 according to the light source control signal of the driving control unit 140 to light the light source unit 170 . It is configured to include a lighting driving unit 150 , and the illuminance sensor 120 , the driving control unit 140 , the lighting driving unit 150 , and the light source unit 170 are operated by receiving power through the battery 180 .

First, the light source unit 170 may be formed of a light emitting diode (LED). In general, an indoor lighting device of a building is typically implemented by providing a fluorescent lamp, a halogen lamp, an incandescent lamp, etc. on a ceiling or a wall. Such fluorescent lamps or halogen lamps have a disadvantage in that they consume a lot of power and mainly provide only monochromatic lighting, as opposed to common indoor lamps. In order to solve such high power consumption and monotony of lighting, lighting devices capable of producing lighting of various colors and illuminance have been recently developed. For example, lighting devices using LEDs capable of semi-permanently outputting various colors with low power consumption have been developed to replace existing lighting devices. In the following description, the light source unit 170 is described as an LED light source, but it is not necessarily limited thereto, and any configuration capable of incident/irradiating light in a certain range of the target surface with directionality may be applied.

The illuminance sensor 120 may use a commonly used CDS (cadmiumsulfide) sensor or a semiconductor-type ambient light sensor (illuminance sensor), but is not necessarily limited thereto. If so, anything can be used.

The driving control unit 140 may output a lighting control signal for controlling the lighting of the light source unit 170 according to the illuminance value of the operating area measured by the illuminance sensor 120 .

Here, the driving control unit 140 sets the reference illuminance and compares the measured illuminance value of the illuminance sensor 120 with the reference illuminance to determine the driving of the light source unit 170 .

The reference illuminance includes a first reference illuminance and a second reference illuminance. The first reference illuminance is a reference for outputting a lighting control signal for turning on the light source unit 170 . Also, the second reference illuminance is a reference for not outputting a lighting control signal for turning on the light source unit 170 . That is, when the illuminance value measured by the illuminance sensor 120 is equal to or greater than the first reference illuminance, the driving control unit 140 outputs a lighting control signal to turn on the light source unit 170 , but the measured illuminance value is the first reference illuminance. If it is less than or equal to the second reference illuminance, the driving control unit 140 does not output the lighting control signal for turning on the light source unit 170 .

In this case, the first reference illuminance and the second reference illuminance may be set as illuminance values. For example, the first reference illuminance value may be set to 20 lx, and the second reference illuminance value may be set to 100 lx. In this case, if the ambient illuminance is 20 lx or more, it is determined that the closet is open, that is, a situation in which a person intends to use the space, and the light source unit 170 is turned on. However, if the ambient illuminance is 100 lx or more, the closet is open, that is, a state in which a person intends to use the space, but the ambient illuminance is very bright and there is no need to turn on the light source unit 170, and the light source unit 170 is turned on. won't make it

Alternatively, the first reference illuminance and the second reference illuminance may be set as an illuminance variation width. For example, the first reference illuminance change range may be set to be three times the illuminance standard during standby, and the second reference illuminance change range may be set to 10 times the standby illuminance standard. In this case, if it is calculated that the ambient illuminance is three times or more compared to the illuminance in the dark standby mode, it is determined that the closet is open, that is, a situation in which a person intends to use the space, and the light source unit 170 is turned on. However, if the ambient illuminance is 10 times or more compared to the illuminance in the dark standby state, it is determined that the closet is open, that is, a state in which a person intends to use the space, but the ambient illuminance is very bright and there is no need to turn on the light source unit 170 Therefore, the light source unit 170 is not turned on.

The illuminance sensor 120 and the driving control unit 140 are configured to operate in three different modes according to the conditions of the area where the lighting is installed. Such modes are a standby mode, a turn-on mode, and a turn-off mode.

The standby mode is a mode in which a person waits in a space not used for a long time and detects it through a change in illuminance when a person enters. At this time, the illuminance sensor 120 measures the illuminance in real time while driving with low power to determine whether there is a illuminance change in the operation area.

That is, in the standby mode, the illuminance sensor 120 measures the illuminance of the operating area at an interval of 3 times per second or less, preferably about 1 time per second, thereby minimizing power consumption.

In this standby mode, the driving control unit 140 outputs a lighting control signal for controlling the lighting of the light source unit 170 according to the measured illuminance value of the operating area.

More specifically, the driving control unit 140 determines the driving of the light source unit 170 by comparing the measured illuminance value of the operating region with the first reference illuminance and the second reference illuminance.

That is, if the measured illuminance value of the operating zone is higher than the first reference illuminance and lower than the second reference illuminance, the driving control unit 140 outputs a lighting control signal to turn on the light source unit 170 , and the lighting control device is turned on. mode will be switched. On the other hand, if the measured illuminance value of the operating zone is lower than the first reference illuminance or higher than the first reference illuminance and higher than the second reference illuminance, the lighting control device maintains the standby mode.

The turn-on mode is a mode in which the light source unit 170 is turned on for a certain period of time in a state in which the closet is open, that is, in a state where a person intends to use the corresponding space. At this time, the driving control unit 140 sets a set time so that the light source unit 170 is turned on for about 8 to 15 seconds in the turn-on mode.

That is, after this set time has elapsed, the lighting control device is switched to a turn-off mode in which the light source unit 170 is turned off, and will return to the standby mode.

2 is a view for explaining an operation process of the lighting control device according to an embodiment of the present invention.

First, the lighting control device waits in the standby mode (S10).

The standby mode is a mode in which a person waits in a space not used for a long time and detects it through a change in illuminance when a person enters, and the illuminance sensor 120 is driven with low power.

In this standby mode, the lighting control device compares the illuminance of the operating area measured by the illuminance sensor 120 with the first reference illuminance and the second reference illuminance to determine whether to drive the light source unit 170 (S12, S14).

That is, the driving control unit 140 compares the measured illuminance value of the operating zone with the first reference illuminance and the second reference illuminance, so that the measured illuminance value of the operating zone is lower than the first reference illuminance or higher than the first reference illuminance. If it is high and is higher than the second reference illuminance, the lighting control device maintains the standby mode.

On the other hand, if the measured illuminance value of the operating zone is higher than the first reference illuminance and lower than the second reference illuminance, the procedure is performed in the turn-on mode by outputting a lighting control signal to turn on the light source unit 170 .

Accordingly, the lighting control device is operated in the turn-on mode (S16).

The turn-on mode is a mode that is executed when it is determined that there is a change in illuminance in the standby mode, and illuminates the lighting area for a predetermined period of time.

Thereafter, the lighting control device determines whether a preset set time has elapsed (S18), and when the set time elapses, the light source unit 170 is switched to a turn-off mode to turn off (S20), and will return to the standby mode.

3 is a view for explaining a lighting control device according to another embodiment of the present invention.

Referring to FIG. 3 , a lighting control device according to another embodiment of the present invention includes an illuminance sensor 120 for measuring ambient illuminance for an operation zone, and an image sensor for acquiring image data for an operation zone by photographing a set range. 110 and the image recognition unit 130 that receives the image data taken from the image sensor 110 and analyzes the received image data to check the movement of the human body due to the image change in the operation area and output a human body recognition signal ) and the driving control unit 140 that outputs a light source control signal for turning on the light source unit 170 according to the illuminance value of the operating area measured through the illuminance sensor 120 and the human body recognition signal of the image recognition unit 130 . ) and a lighting driver 150 that turns on the light source unit 170 by applying power to the light source unit 170 according to the light source control signal of the driving control unit 140, and the illuminance sensor 120, the image The sensor 110 , the image recognition unit 130 , the driving control unit 140 , the lighting driving unit 150 , and the light source unit 170 are operated by receiving power through the battery 180 .

A detailed description of a configuration overlapping with the above-described exemplary embodiment will be omitted, and only additional components and their connection relationships and functions will be described.

The image data photographed by the image sensor 110 may be photographed in units of one image frame, such as a still image, or in some cases, may be photographed in units of a plurality of image frames, such as a moving image. In addition, image data captured by each pixel of the image sensor 110 is transmitted to and stored in a separate memory unit (not shown), and the stored image data is an image for human body detection by the image recognition unit 130 . It is used as basic data for analysis.

The image recognition unit 130 analyzes the image data stored in the memory unit to check the image change in the operation area or the movement of the human body in the operation area to output a human body recognition signal. The image recognition unit 130 extracts a person located in the operation area as a monitoring object in order to confirm the movement of the human body. Here, in extracting the monitoring object, by comparing every image frame according to the time-series order of the image data, it is possible to extract an object that moves according to the change in RGB value or Black/White value, and determines the size and shape of the object. By limiting the detection of abnormal objects such as fallen leaves, animals, raindrops, curtains, etc., it is possible to detect and extract only the human body to be detected. The image recognition unit 130 determines the presence of a person in the operation area according to whether or not a monitoring object targeting the human body is extracted, and outputs a human body recognition signal according to the determined result. In addition, the image recognition unit 130 may check the difference between the front and rear image frames to confirm the movement of the person.

An image sensor according to another embodiment of the present invention will now be described in detail with reference to FIG. 4 .

4 is a diagram for explaining a circuit configuration of an image sensor according to another embodiment of the present invention.

Referring to FIG. 4 , an image sensor according to an embodiment of the present invention includes an optical sensor unit 111 including first and second photodiodes 111a and 111b for converting an optical signal into an electrical signal, and the optical sensor. An amplifying unit 112 when amplifying each electric signal converted from the unit 111, a comparing unit 113 comparing each electric signal amplified from the amplifying unit 112 and amplifying the difference; It may be configured to include a signal converter 114 for converting the electrical signal output from the comparator 113 into a digital signal.

The optical sensor unit 111 may include first and second photodiodes 111a and 111b. The first photodiode 111a is a general photodiode, and when an optical signal (light) is incident, an electrical signal is detected. On the other hand, the second photodiode 111b has an external optical filter that blocks visible light or infrared light, so that even when an optical signal is incident, no electrical signal is detected.

Here, the optical filter may be made of a metal film capable of blocking visible light or infrared light, and in order to block visible light, a metal line used in an integrated circuit manufacturing process is used as it is, and a metal line of aluminum is used. may be deposited on the surface of the photodiode to block visible light incident on the second photodiode 111b.

The amplifying unit 112 may include a first AMP 112a and a second AMP 112b. The first AMP 112a is configured to amplify the signal input from the first photodiode 111a, and the second AMP 112b is configured to amplify the signal input from the second photodiode 111b. configuration for it.

The comparison unit 113 compares the output value of the first AMP 112a with the output value of the second AMP 112b. The comparator 113 has a high gain and may be configured as a variable differential amplifier. Here, the reason for increasing the gain of the differential amplifier is to operate well in an ultra-low environment, and also to enable the entire module and device including the same to be driven with low power.

Basically, the first and second photodiodes 111a and 111b have a value unique to each pixel and have fixed pattern noise that does not change with time due to the characteristics of the photodiodes. This fixed pattern noise is noise generated from non-uniformity related to the AMP in the pixel, and is usually corrected in advance, but appears as noise when exposed for a long time.

In the present invention, an optical filter is formed in the second photodiode 111b constituting the optical sensor unit 111 in order to remove the influence of the fixed pattern noise.

Since the first AMP 112a is connected to the first photodiode 111a, it has the leakage fixed pattern noise of the diode together with the electrical signal according to the optical signal, but the second AMP 112b ) and connected to the second photodiode 111b, since an optical filter is formed, the second AMP 112b does not have an electrical signal according to the optical signal, but has only fixed pattern noise.

Therefore, in the process of comparing the output value of the first AMP 112a and the output value of the second AMP 112b in the comparator 113, only an electric signal according to the pure optical signal of the first photodiode 111a is detected. In this process, the fixed pattern noise of the first photodiode 111a is also removed.

In addition, the signal conversion unit 114 converts the two outputs of the comparator 113 into digital signals and transmits them to the image recognition unit 130 so that the image recognition unit 130 analyzes the image data for each pixel. A person located in the operating area should be extracted as a monitoring object.

The light source control signal for turning on the light source unit 170 output from the driving control unit 140 is the illuminance value of the operating area measured by the illuminance sensor 120 in the standby mode and the image recognition unit 130 in the confirmation mode. It is determined according to the transmitted human body recognition signal.

First, the driving control unit 140 determines whether the image sensor 110 and the image recognition unit 130 operate according to the illuminance value of the operating area measured by the illuminance sensor 120 in the standby mode, that is, whether the confirmation mode is executed. will decide

Here, the driving control unit 140 determines the driving of the image sensor 110 and the image recognition unit 130 by setting the reference illuminance and comparing the measured illuminance value of the illuminance sensor 120 with the reference illuminance in the standby mode. will be

The reference illuminance includes a first reference illuminance and a second reference illuminance. The first reference illuminance serves as a reference for executing the confirmation mode for driving the image sensor 110 and the image recognition unit 130 . In addition, the second reference illuminance serves as a reference for executing the confirmation mode for driving the image sensor 110 and the image recognition unit 130 . That is, if the illuminance value measured by the illuminance sensor 120 is equal to or greater than the first reference illuminance, the driving control unit 140 drives the image sensor 110 and the image recognition unit 130 , but the measured illuminance value is the first reference illuminance. When the illuminance is less than or equal to the second reference illuminance, the driving controller 140 does not drive the image sensor 110 and the image recognition unit 130 .

In this case, the first reference illuminance and the second reference illuminance may be set as illuminance values. For example, the first reference illuminance value may be set to 20 lx, and the second reference illuminance value may be set to 100 lx. In this case, when the ambient illuminance is 20 lx or more, the image sensor 110 and the image recognition unit 130 are driven by determining that the closet is open, that is, a situation in which a person intends to use the space. However, if the ambient illuminance is 100 lx or more, it is determined that the closet is open, that is, a state in which a person intends to use the space, but the ambient illuminance is very bright and there is no need to turn on the light source unit 170. The image recognition unit 130 is not driven.

Alternatively, the first reference illuminance and the second reference illuminance may be set as an illuminance variation width. For example, the first reference illuminance change range may be set to be three times the illuminance standard during standby, and the second reference illuminance change range may be set to 10 times the standby illuminance standard. In this case, if the ambient illuminance is calculated to be three times or more compared to the illuminance in the dark standby mode, the image sensor 110 and the image recognition unit 130 are driven by determining that the closet is open, that is, a situation in which a person intends to use the space. will make it However, if the ambient illuminance is 10 times or more compared to the illuminance in the dark standby state, it is determined that the closet is open, that is, a state in which a person intends to use the space, but the ambient illuminance is very bright and there is no need to turn on the light source unit 170 Therefore, the image sensor 110 and the image recognition unit 130 are not driven.

The illuminance sensor 120 , the image sensor 110 , the image recognition unit 130 , and the driving control unit 140 are configured to operate in four different modes according to the conditions of the area where the lighting is installed. Such modes are a standby mode, a check mode, a turn-on mode, and a turn-off mode.

The standby mode is a mode in which a person waits in a space not used for a long time and detects it through a change in illuminance when a person enters. At this time, the illuminance sensor 120 measures the illuminance in real time while driving with low power to determine whether there is a illuminance change in the operation area.

That is, in the standby mode, the illuminance sensor 120 measures the illuminance of the operating area at an interval of 3 times per second or less, preferably about 1 time per second, thereby minimizing power consumption.

In such a standby mode, the driving control unit 140 determines whether the image sensor 110 and the image recognition unit 130 operate, ie, whether to execute the check mode, according to the measured illuminance value of the operating area.

More specifically, the driving control unit 140 determines the driving of the image sensor 110 and the image recognition unit 130 by comparing the measured illuminance value of the operating region with the first and second reference illuminance. .

That is, if the measured illuminance value of the operating zone is higher than the first reference illuminance and lower than the second reference illuminance, the driving control unit 140 drives the image sensor 110 and the image recognition unit 130 , and the lighting control device is switched to confirmation mode. On the other hand, if the measured illuminance value of the operating zone is lower than the first reference illuminance or higher than the first reference illuminance and higher than the second reference illuminance, the lighting control device maintains the standby mode.

The confirmation mode is a mode for checking whether or not a person has entered the area where the lighting is installed through image change. At this time, the image sensor 110 and the image recognition unit 130 are driven with low power to determine whether there is an image change in the operation zone through a minute change in the image.

That is, the image sensor 110 includes a comparison unit 113, the output (V _out) of the differential amplifier to control the gain and integrator rating time (Integrating time, T _i) of the differential amplifier constituting the maximum value in the confirmation mode ( Max) and waits in 1/4 of the state.

In addition, in the confirmation mode, the image sensor 110 and the image recognition unit 130 operate by lowering the frame rate to 2 to 5 frames/sec. Preferably, the frame rate may be lowered to 2 frame/sec or less to enable lower power consumption.

In this confirmation mode, when a change is detected in a part of the entire pixel array constituting the image sensor 110 in order to confirm that a person enters the area where the lighting is installed as an image change, the image recognition unit 130 generates an image change signal. will create Here, the image sensor 110 may be configured as a 16×16 pixel array to enable low-power driving, and in this configuration, 3 to 5 times the normal noise (ambient noise + circuit noise) level for 3 to 5 frames. It is preferable to set the image recognition unit 130 to recognize the image change when the abnormal change is detected.

When the image change is recognized in the confirmation mode, the lighting control device is switched to the turn-on mode.

The turn-on mode is a mode in which the light source unit 170 is turned on for a certain period of time in a state in which the closet is open, that is, in a state where a person intends to use the corresponding space. At this time, the driving control unit 140 sets a set time so that the light source unit 170 is turned on for about 8 to 15 seconds in the turn-on mode.

That is, after this set time has elapsed, the lighting control device is switched to a turn-off mode in which the light source unit 170 is turned off, and will return to the standby mode.

5 is a view for explaining an operation process of a lighting control device according to another embodiment of the present invention.

First, the lighting control device waits in the standby mode (S30).

The standby mode is a mode in which a person waits in a space not used for a long time and detects it through a change in illuminance when a person enters, and the illuminance sensor 120 is driven with low power.

In this standby mode, the lighting control device determines whether to drive the image sensor 110 and the image recognition unit 130 by comparing the illuminance of the operating area measured by the illuminance sensor 120 with the first reference illuminance and the second reference illuminance. (S32, S34).

That is, the driving control unit 140 compares the measured illuminance value of the operating zone with the first reference illuminance and the second reference illuminance, and the measured illuminance value of the operating zone is lower than the first reference illuminance or higher than the first reference illuminance. If it is high and is higher than the second reference illuminance, the lighting control device maintains the standby mode.

On the other hand, if the measured illuminance value of the operating zone is higher than the first reference illuminance and lower than the second reference illuminance, the image sensor 110 and the image recognition unit 130 are driven to perform the procedure in the confirmation mode.

Accordingly, the lighting control device operates in the confirmation mode (S36).

The confirmation mode is a mode for checking whether or not a person has entered the area where the lighting is installed through image change.

In this confirmation, the lighting control device determines whether a change of several times (eg, 3-5 times) or more of the normal noise is detected in the image captured by the image sensor 110 (S36).

As a result of the determination in step S36, when a change of several times or more of the normal noise is detected, the lighting control device recognizes this as a change in the image of the operation area and performs the procedure in the turn-on mode.

Accordingly, the lighting control device operates in a turn-on mode (S40).

The turn-on mode is a mode that is executed when it is determined that there is a change in illuminance in the standby mode and there is a change in the image in the confirmation mode.

Thereafter, the lighting control device determines whether a preset set time has elapsed (S42), and when the set time elapses, the light source unit 170 is switched to a turn-off mode to turn off (S44), and will return to the standby mode.

As described above, the best embodiment has been disclosed in the drawings and the specification. Although specific terms are used herein, they are used only for the purpose of describing the present invention and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

110: image sensor 111: optical sensor unit
112: amplification unit 113: comparison unit
114: signal conversion unit 120: illuminance sensor
130: image recognition unit 140: driving control unit
150: light driving unit 160: external controller
170: light source unit

Claims (9)

an illuminance sensor for measuring ambient illuminance for the operating area;
a driving control unit for controlling the illumination driving unit according to the illuminance measurement result of the illuminance sensor to turn on the light source unit; includes,
a standby mode for checking changes in illuminance in an area where lighting is installed;
a turn-on mode in which the light source unit is turned on for a set time when a change in illuminance is recognized in the standby mode;
a turn-off mode for turning off the light source when a set time elapses in the turn-on mode; A lighting control device, characterized in that it is divided and operated.
The method of claim 1,
In the standby mode, the driving control unit sets a reference illuminance and compares the measured illuminance value of the illuminance sensor with the reference illuminance to determine the driving of the light source unit.
3. The method of claim 2,
The reference illuminance includes a first reference illuminance value and a second reference illuminance value set as the illuminance value,
If the illuminance value measured by the illuminance sensor is greater than or equal to the first reference illuminance value, a lighting control signal is output, and if the measured illuminance value is less than or equal to the first reference illuminance value or greater than or equal to the second reference illuminance value, the lighting control signal is not output. Lighting control device characterized.
3. The method of claim 2,
The reference illuminance includes a first reference illuminance change width and a second reference illuminance change width set as the illuminance change width,
If the variation of the illuminance value measured by the illuminance sensor is greater than or equal to the first reference illuminance variation, a lighting control signal is output. Lighting control device, characterized in that not.
an illuminance sensor for measuring ambient illuminance for the operating area;
an image sensor that is driven according to a measurement result of the illuminance of the illuminance sensor to acquire image data for an operation area;
an image recognition unit that receives image data captured from the image sensor and analyzes the received image data to detect an image change in the operation area; and
a driving control unit for controlling the lighting driving unit according to the detection result of the image recognition unit to turn on the main light source unit; includes,
a standby mode for checking changes in illuminance in an area where lighting is installed;
a confirmation mode for checking an image change when a change in illuminance is recognized in the standby mode;
a turn-on mode that turns on the light source for a set time when the image change is recognized in the confirmation mode;
a turn-off mode for turning off the light source when a set time elapses in the turn-on mode; A lighting control device, characterized in that it is divided and operated.
6. The method of claim 5,
In the standby mode, the driving control unit sets a reference illuminance and compares the measured illuminance value of the illuminance sensor with the reference illuminance to determine the driving of the light source unit.
7. The method of claim 6,
The reference illuminance includes a first reference illuminance value and a second reference illuminance value set as the illuminance value,
If the illuminance value measured by the illuminance sensor is greater than or equal to the first reference illuminance value, a lighting control signal is output, and if the measured illuminance value is less than or equal to the first reference illuminance value or greater than or equal to the second reference illuminance value, the lighting control signal is not output. Lighting control device characterized.
7. The method of claim 6,
The reference illuminance includes a first reference illuminance change width and a second reference illuminance change width set as the illuminance change width,
If the variation of the illuminance value measured by the illuminance sensor is greater than or equal to the first reference illuminance variation, a lighting control signal is output. Lighting control device, characterized in that not.
6. The method of claim 5,
In the confirmation mode, a lighting control device, characterized in that it is switched to the turn-on mode when the standard abnormality is based on whether a change of 3 to 5 times or more of the image noise is detected in the image captured through the image sensor as the standard of the image change.

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