KR20100135987A - Infrared sensor light control device - Google Patents

Abstract

The present invention relates to a lighting control device. The lighting control device according to the present invention detects the presence of heat emitted by the human body within a set effective area, and includes a sensor driving circuit made by integrating a resistive non-cooling thermal infrared sensor through a MEMS process in a CMOS circuit. And a first control unit to turn on an illumination unit when heat is detected in the effective area through the detection unit and the detection unit, and to turn off the illumination unit when heat is not detected in the effective area.

The apparatus may further include a second controller configured to gradually adjust the illumination brightness in response to the distance between the sensing unit and the effective region in which the sensed heat exists.

Description

Infrared Sensor Lighting Control Unit {Luminance Control Apparatus with Uncooled Micro Bolometer}

The present invention relates to a lighting control device, and more particularly, to a device capable of controlling lighting by sensing heat (infrared rays) emitted from a human body when a human body exists in an effective area without a human body moving.

In general, a pyroelectric infrared sensor is a thermal sensor and used as a sensor for motion detection. The pyroelectric infrared sensor detects the presence or absence of a change in an object or operation and a person in the measurement area by converting a heat change occurring in the measurement area into an electrical signal.

This type of pyroelectric infrared sensor is applied to a security system or an automatic lighting device of a general home. The conventional auto lighting device includes a pyroelectric infrared sensor for motion detection, a lens, and the like, and detects a change in motion in the measurement area using one sensor module to control lighting and turning off of a light source. For example, when there is a motion of a person, a light is output by outputting a detection signal of 0V, and when the motion of a person is not, a light is turned off by outputting a 5V detection signal.

1 and 2 is a view showing the operation of a conventional automatic lighting device.

As shown in FIG. 1, the auto lighting device including the pyroelectric infrared sensor recognizes the presence of a person when the person moves from the A position to the A 'position under the lighting device, and lights up the lighting. In addition, referring to FIG. 2, when a person does not move in the B position for a predetermined time, the illumination is turned off because the person is not recognized.

As such, the conventional auto lighting apparatus including the pyroelectric infrared sensor recognizes an object located in the sensing area according to the change of the thermal state, and thus, the object is not recognized without the movement of the object.

In other words, if a person under the autoilluminator does not move for a long time, the autoilluminator does not recognize the presence of a person and turns off, so that the person under the autoilluminator must move in order to turn it back on. The disadvantage is that it is inconvenient.

Microwave driven heat sensor instead of pyroelectric infrared sensor enables real-time detection of a person under automatic lighting, but microwave sensor heat sensor is very expensive. There is a problem that it is difficult to apply at all, such as a lighting device.

In addition, the pyroelectric infrared sensor requires a separate driving circuit PCB substrate, there is a problem that can not be applied to the CMOS circuit.

The present invention has been made to solve the above-described problems, by applying a resistive uncooled micro infrared sensor (Uncooled micro bolometer) instead of the pyroelectric infrared sensor, to detect the presence of heat in the effective area in real time, There is a technical problem to provide a light control device that does not turn off the lighting even without the movement of a person located in the effective area.

In addition, the present invention has been made to solve the above problems, there is a technical problem to provide a lighting control device that can be driven at low power by applying a resistive non-cooling thermal infrared sensor.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

Lighting control device according to the present invention for achieving the above object,

A sensing unit including a sensor driving circuit configured to sense the presence of heat emitted by the human body within a set effective area and to integrate a resistive non-cooling thermal infrared sensor through a MEMS process in a CMOS circuit; And a first controller to turn on an illumination unit when heat is detected in the effective area through the detection unit, and to turn off the illumination unit when heat is not detected in the effective area.

In addition, a second control unit for adjusting the illumination brightness step by step in response to the distance between the sensing unit and the effective region in which the sensed heat exists; It may further include.

Here, the second control unit divides the set effective area according to the distance between the sensing unit, and maximizes the brightness of the illumination when the distance between the sensing unit and the effective area in which the heat detected by the sensing unit exists is the shortest. In addition, as the distance increases, the brightness of the light decreases proportionally, and when the distance is the longest, the brightness of the light may be adjusted to the minimum.

By dividing the set effective area according to the distance from the sensing unit, if the distance between the sensing unit and the effective region in which heat detected by the sensing unit is shortest is minimized, the brightness of the illumination is minimized and the distance becomes farther. As the brightness of the light increases proportionally as the distance increases, the brightness of the light may be adjusted to the maximum when the distance is the longest.

In addition, the lighting control device according to the present invention,

A sensing unit including a sensor driving circuit configured to sense the presence of heat emitted by the human body within a set effective area and to integrate a resistive non-cooling thermal infrared sensor through a MEMS process in a CMOS circuit;

A first control unit which turns off the lighting unit when heat is detected in the effective area through the sensing unit and turns on the lighting unit when heat is not detected in the effective area;

It may be included.

As described above, according to the present invention, by applying a resistive uncooled micro bolometer instead of the pyroelectric infrared sensor, it is possible to detect the presence of heat in the effective area in real time, It provides a light control device that can prevent the lights from turning off even without the movement of people located.

In addition, by applying a resistive non-cooling thermal infrared sensor, it can be driven at low power, thereby providing a lighting control device that can be used in power saving products to create innovative effects on energy saving.

In addition, since a thermal infrared sensor can be integrated directly into a CMOS circuit using a MEMS process, a separate driving circuit PCB board is not required, thus providing a compact and low-cost lighting control device.

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

[First Embodiment]

3 is a control block diagram of a lighting control device according to a first embodiment of the present invention. Referring to FIG. 2, the lighting control apparatus according to the present embodiment controls to turn on or off the sensing unit 11 that detects whether heat is present in a set effective area and the lighting unit 20 that illuminates light. The first control unit 13 is included.

The detection unit 11 is implemented as an uncooled micro infrared sensor (Uncooled micro bolometer) that detects whether or not the thermal energy (infrared rays) corresponding to the temperature emitted by the object exists within the set effective area, according to the change of temperature It is implemented as a resistive non-cooling thermal infrared sensor using a thin film whose resistance changes.

Here, the set effective area may vary depending on the performance of the uncooled thermal infrared sensor. Therefore, the user can set a desired effective area by applying an uncooled thermal infrared sensor having a desired performance.

Conventional pyroelectric infrared sensors (Pyroelectric Infrared Sensor) recognizes the object located in the sensing area according to the change in the thermal state, the object will not be recognized without the movement of the object.

On the contrary, the uncooled thermal infrared sensor according to the present invention detects whether or not thermal infrared rays exist in the effective area, so that the object can be recognized without the movement of the object. Therefore, it is possible to solve the inconvenience of having to give a movement so that the sensor can detect.

The first controller 13 controls the lighting unit 20 to be turned on or off, and may be implemented as a controller such as a microcomputer. Or, it may be implemented as a switch for controlling to supply or cut off the power supplied to the lighting unit 20.

The first controller 13 determines whether heat is detected in the effective area through the detector 11. As a result of the determination, when heat is detected in the effective area through the sensing unit 11, the lighting unit 20 is controlled to turn on. If the heat is not detected in the effective area through the sensing unit 11 or if the detected heat is out of the effective area, the lighting unit 20 is turned off.

For example, referring to FIG. 5, if a person exists in the set effective area C, the detector 11 may detect the presence of heat even if there is no movement of the person. Accordingly, the first control unit 13 controls the lighting unit 20 to be turned on.

In addition, referring to FIG. 6, if a person does not exist in the set valid area C, the detector 11 detects that no heat exists. The first control unit 13 controls the lighting unit 20 to be turned off.

The lighting control device according to the present embodiment may be installed in an apartment entrance or stairs, and the user is waiting for an elevator in the apartment entrance or stairs, or the lighting is turned off even if time passes while searching for a key, thereby eliminating the inconvenience.

Since the uncooled thermal infrared sensor can detect the object to be measured (for example, a person) without moving, the lighting does not turn off even if there is no movement of the person. In addition, since it can be driven with low power it can be usefully applied to real life.

Second Embodiment

4 is a control block diagram of a lighting control device according to a second embodiment of the present invention. Referring to FIG. 4, the lighting control device according to the present embodiment includes a sensing unit 11 implemented as an uncooled thermal infrared sensor for sensing the presence of heat in a set effective area, and an lighting unit 20 for illuminating light. The first control unit 13 for turning on or off the light and the second control unit 15 for adjusting the brightness of the illumination step by step corresponding to the distance between the detection unit and the effective region in which the sensed heat exists. In the description of the second embodiment, the same components as those of the first embodiment will be omitted.

The second controller 15 according to the second exemplary embodiment may adjust the brightness of the lighting unit 20 step by step in response to the distance between the sensing unit 11 and the effective region in which the sensed heat exists in the effective region. For example, as the distance between the sensing unit 11 and the effective region in which the sensed heat exists is closer, the brightness of the lighting unit 20 may be controlled to be brightened step by step or darkened step by step.

Referring to FIG. 7, the distance between the sensing unit 11 and the effective region in which the sensed heat is present is closer to the E region than to the D region, and closer to the F region than the E region. Therefore, the second control unit 15 is to be lit at 50% of the original brightness when in the area D, and to be lit at 75% of the original brightness when in the area E, and 100% of the original brightness when in the area F It can be turned on with the brightness of.

On the contrary, as the distance between the sensing unit 11 and the effective region in which the sensed heat is present increases, the light may be turned on with brighter brightness. For example, the second control unit 15 is turned on at the brightness of 100% of the original brightness when in the area D, and is turned on at 75% brightness of the original brightness when in the area E, and 50% of the brightness at the area F. It can be turned on with the brightness of.

[Third Embodiment]

A third embodiment of the present invention is a light control device applied to a mobile phone. The lighting control apparatus according to the third embodiment includes a sensing unit 11 and a first control unit 13 for controlling the lighting unit 20. Here, in describing the third embodiment, the same components as in the first embodiment will be omitted.

The first control unit 13 according to the third embodiment controls the lighting unit 20 to be turned on when no heat is detected in the effective area, and controls the lighting unit 20 to be turned off when heat is detected in the effective area. do.

For example, when a user makes a call using a mobile communication terminal, the illumination on the LCD screen does not need to be turned on. Accordingly, the first control unit 13 according to the third embodiment may control the lighting unit 20 to be turned off when the user makes a call, that is, when the human body has a high thermal sensitivity, so that energy may be reduced.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Instead of the pyroelectric infrared sensor, a resistive uncooled micro bolometer can be applied to detect the presence of heat in the effective area in real time. I can eliminate it.

In addition, since it can be driven at low power, it can be used in power saving products to create innovative effects on energy saving.

1 and 2 is a view showing a lighting control device that is operated according to the movement of a conventional person,

3 is a control block diagram of a lighting control device according to a first embodiment of the present invention,

4 is a control block diagram of a lighting control device according to a second embodiment of the present invention;

5 and 6 are views illustrating a lighting control device operated according to whether a person exists in the effective area according to the first or second embodiment of the present invention.

7 is a diagram illustrating a lighting control device operated according to a distance between a sensing unit and a person according to a second embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

11: detector 13: first controller

15: second control unit 20: lighting unit

Claims (5)

In the lighting control device, A sensing unit including a sensor driving circuit configured to sense the presence of heat emitted by the human body within a set effective area and to integrate a resistive non-cooling thermal infrared sensor through a MEMS process in a CMOS circuit; A first controller to turn on an illumination unit when heat is detected in the effective area through the detection unit, and to turn off the illumination unit when heat is not detected in the effective area; Infrared sensor light control device comprising a The method of claim 1, A second controller configured to adjust illumination brightness step by step in response to a distance between the sensing unit and an effective area in which the sensed heat exists; Infrared sensor light control device further comprising The method of claim 2, The second controller divides the set effective area according to the distance between the sensing unit, and maximizes the brightness of the lighting when the distance between the sensing unit and the effective region in which the heat detected by the sensing unit exists is the shortest, Infrared sensor lighting control device characterized in that as the distance increases, the brightness of the light decreases proportionally, and when the distance is the longest, the brightness of the light is adjusted to the minimum. The method of claim 2, The second controller divides the set effective area according to the distance between the sensing unit, and minimizes the brightness of the lighting when the distance between the sensing unit and the effective region in which heat detected through the sensing unit is shortest is the minimum. Infrared sensor lighting control device characterized in that the increase in the brightness of the light proportionally increases as the distance increases, the maximum brightness of the light when the distance is the longest In the lighting control device, A sensing unit including a sensor driving circuit configured to sense the presence of heat emitted by the human body within a set effective area and to integrate a resistive non-cooling thermal infrared sensor through a MEMS process in a CMOS circuit; A first control unit which turns off the lighting unit when heat is detected in the effective area through the sensing unit and turns on the lighting unit when heat is not detected in the effective area; Infrared sensor light control device comprising a

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