KR20160044240A - A wireless lighting device and a method for controlling thereof - Google Patents

Abstract

The present invention relates to a wireless lighting device which can configure a network between lighting devices as the lighting devices include a wireless communication means, and transmit lighting control information through the network, and a method for controlling the wireless lighting device. According to the present invention, provided is a wireless lighting device comprising: a detection unit, a communication unit, a control unit, and a lighting unit. The control unit receives a lighting control signal from an external device via the communication unit, generates a processing signal which adjusts output of the lighting unit based on the lighting control signal, searches for an external device capable of performing wireless communication via the communication unit, evaluates received signal strength measured during communication with the searched external device and thus generates connectivity information based on the received signal strength, generates a network map of all wireless lighting devices by referring to connectivity information of other wireless lighting devices received via the communication unit, and refers to the network map when transmitting at least one of environmental information detected by the detection unit, the processing signal generated by the control unit, and the information received from the external device, via the communication unit.

Description

Technical Field The present invention relates to a wireless lighting device and a method for controlling the same,

The present invention relates to a wireless lighting apparatus and a control method thereof, and more particularly, to a lighting apparatus that is freely disposed in a space, which can form a network between each lighting apparatus by having wireless communication means, And more particularly, to a wireless lighting device and its control method capable of easily transmitting information.

Recently, thanks to the development of IT technology, electric, electronic and communication technologies have been applied to various household goods. Especially, as the concepts of Internet of Thing (IoT) and Ubiquitous Sensor Network are spreading, various information is gathered without any time and place, and a method to utilize the collected information There are many discussions about Here, the Internet refers to a technology or environment in which a sensor is attached to an object to exchange information with the Internet in real time. And ubiquitous sensor network is a communication network that recognizes objects and environment by attaching electronic tags to all objects and constructs and utilizes real-time information through network. In particular, the concept of the Internet of things and the ubiquitous sensor network has been actively used in the process of developing convenience and convenience in everyday life or managing the health of the people, .

According to the Internet of Things and the Ubiquitous Sensor Network, everything we can think of can be connected to the network. In addition, a pen, a toothbrush, and the like can be connected to the network, and information such as information on a person using the object and a pattern in which the object is used can be generated and shared.

On the other hand, since the invention of a light bulb, various types of lighting devices have been developed, thereby rapidly expanding the human activity area. Especially after the sun came up, people were able to carry on their daily lives conveniently, which caused a lot of cultural and economic changes in human society.

In this way, the concept of object Internet and ubiquitous sensor network can be applied to lighting devices that are essential in everyday life. However, research on this field is still in its infancy stage.

Recently, a product for controlling a plurality of lighting apparatuses through a network has been released. However, the product is configured in a simple form in which each lighting apparatus is collectively controlled by a central control apparatus. That is, the control device and the plurality of illuminating devices are connected in a one-to-many manner, and each illuminating device receives the control signal passively and outputs the illuminated light, which can be called a true object Internet or a ubiquitous sensor network none.

On the other hand, in the case of the above-mentioned product, in order to transmit certain information from one illuminating device terminal to another illuminating device, it is necessary to once communicate with a relay device connected to all the illuminating devices. In addition, in the case of the above product, the lighting device disconnected from the network with the relay device is also isolated and can not be used properly until the network connection is restored again.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wireless lighting device and a control method thereof that actively form a network with an external device to smoothly transmit and receive information.

In addition, the present invention has an object of providing a wireless lighting device which does not require a separate relay device.

According to an exemplary embodiment of the present invention, there is provided an image processing apparatus including: a sensing unit for sensing a change in an external environment; A communication unit for transmitting and receiving information to and from an external device; A control unit for generating a processing signal for controlling the operation of each unit; And an illumination unit for outputting light according to the processing signal; Wherein the control unit receives a lighting control signal from an external device through the communication unit and generates a processing signal for adjusting the output of the lighting unit based on the lighting control signal, The wireless communication device according to claim 1, further comprising: an external device capable of performing communication with the external wireless device, performing a communication with the searched external device, The control unit generates at least one of the environmental information sensed by the sensing unit, the processing signal generated by the control unit, and information received from the external device through the communication unit The network map is referred to when the wireless network It is possible to provide a device.

According to another embodiment of the present invention, Evaluating a signal reception strength measured when performing communication with the searched external device, and generating connectivity information based on the reception strength; Receiving connectivity information of another wireless lighting device and creating a network map of all wireless lighting devices with reference thereto; Receiving information from an external device; And transmitting information by referring to the network map; The method comprising the steps of:

According to the present invention, it is possible to actively configure a network between each wireless lighting device without a relay device and a separate central control device, and thereby, illumination of the wireless lighting device can be easily controlled through the network.

In addition, according to the present invention, it is possible to detect environment and network state change in which the wireless lighting device is installed in real time. In particular, according to the embodiment of the present invention, a network map can be generated from the network state, and illumination control information can be efficiently transmitted and received with reference to the network map.

In addition, according to the present invention, the network map can be updated automatically when a change in the state of the network due to addition of external devices is detected.

1 is a view illustrating a wireless lighting device according to an embodiment of the present invention.
2 is a diagram illustrating a wireless lighting system in accordance with an embodiment of the present invention.
3 is a diagram illustrating a network map generated in a wireless lighting device according to an embodiment of the present invention.
4 is a diagram illustrating a network map generated using connectivity information that is determined as a stable connection.
5 is a diagram illustrating a method of transmitting information by a wireless lighting device according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating another way in which a wireless lighting device according to an embodiment of the present invention transmits information.
7 is a diagram illustrating a method of controlling a wireless lighting device according to an embodiment of the present invention.

The present invention relates to a wireless lighting apparatus and a control method thereof that can form a network between lighting apparatuses and can easily transmit lighting control information through the network, and a control method thereof, and a preferred embodiment of the present invention will be described in detail with reference to the drawings do.

1 is a view illustrating a wireless lighting device according to an embodiment of the present invention.

1, a wireless lighting device 100 according to an embodiment of the present invention may include a sensing unit 110, a communication unit 120, a controller 130, and an illumination unit 140.

The sensing unit 110 may sense an environmental change outside the wireless lighting device. Here, the environmental change may include changes in illuminance, temperature, and humidity of the space where the wireless lighting device 100 is installed. In addition, the sensing unit 110 may sense the movement of objects in the space where the wireless lighting device 100 is installed. The sensing unit 110 may include a thermometer, a hygrometer, and an illuminometer to detect various environmental changes described above, and may also include an infrared sensor and an image sensing unit. The sensing unit 110 senses a change in the external environment and transmits information related to the change to the controller 130.

The communication unit 120 transmits / receives information to / from an external device. Here, the external device may include another wireless lighting device, a wireless network access point (AP), an external control terminal, and the like. Although the name of the present invention is described as a wireless lighting device, the wireless communication device is not limited to a wireless communication device, and information may be transmitted and received through a wired line, if necessary.

The communication unit 120 can transmit and receive information to / from an external device through two or more types of wireless communication methods. The communication unit 120 may transmit and receive information through WiFi, infrared communication, ZigBee, UWB (Ultra Wide Band), Bluetooth (BlueTooth), and BLE (BlueTooth Low Energy). The communication unit 120 can maximize the possibility of network connection with an external device by transmitting and receiving information using two or more types of wireless communication methods. The communication unit 120 can use a plurality of communication methods when transmitting and receiving information with a specific external device. In addition, for example, the communication unit 120 may communicate with a neighboring first external device using a ZigBee, and may communicate with a second external device located in another direction using Bluetooth. Of course, the communication unit 120 does not always mix two or more kinds of wireless communication systems. The control unit 130, which will be described later, can select a communication method to be used for communication with reference to the signal reception strength of each wireless communication method.

On the other hand, the communication unit 120 can transmit and receive information without being bound to directions by using a non-directional antenna. However, the present invention is not limited thereto, and the communication unit 120 may transmit and receive information only in a specific direction by using a directional antenna or utilizing a beamforming technique through a plurality of antennas. The communication unit 120 may further include driving means for adjusting the position and direction of the antenna.

The control unit 130 may generate a processing signal for controlling the operation of each unit of the wireless lighting device 100. [

Basically, the control unit 130 can adjust the intensity, color, and the number of output frequencies of the light output from the illumination unit 140, which will be described later.

As described above, the control unit 130 can sense the illuminance, the temperature, the humidity, and the movement of objects including the person through the sensing unit 110. [ The control unit 130 may transmit the information generated by the sensing unit 110 to an external device through the communication unit 120 or may control the output of the lighting unit 140 according to a predetermined operation method. For example, when the wireless lighting device 100 is installed in a warehouse for storing valuables, the control unit 130 can detect movement of a person entering from the outside through the sensing unit 110, To a secure network. Alternatively, the control unit 130 may generate a processing signal for outputting a sound indicating the intruder's intrusion, or maximize the output of the illumination unit 140 to illuminate the interior of the warehouse. As another example, when the temperature of the current room is detected to be over 100 degrees centigrade through the thermometer of the sensing unit 110, the controller 130 can determine that a fire has occurred. At this time, the control unit 130 outputs red light blinking five times per second through the illumination unit 140, thereby informing people of the occurrence of the fire. In addition, the control unit 130 can receive information indicating the occurrence of a fire through the communication unit 120, and can notify people of the occurrence of the fire in the above-described manner. The control unit 130 may analyze the sensing signal of the sensing unit 110 or the information transmitted through the communication unit 120 to determine the external weather and may control the lighting unit 140 to output light suitable for each weather can do. For example, in the case of a cloudy weather, the space becomes blue as a whole due to the shadow. The controller 130 adjusts the illuminance and the color temperature of the illumination unit 140 to output light, It can be kept constant.

The control unit 130 can determine the time and the season through a built-in clock and can automatically generate a processing signal for gradually increasing the output of the illumination unit 140 after sunset.

The control unit 130 may control the lighting unit 140 to output light at an illuminance and a color temperature suitable for the type of the space in which the wireless lighting device 100 is installed. For example, when the wireless lighting device 100 is installed in an emergency room of a hospital, the control unit 130 determines whether the illumination unit 140 is illuminated at an illuminance of 1,000 to 1,500 lx (lux) and a color temperature of 6,500 K It can be set to output light.

Meanwhile, the control unit 130 may receive the illumination control signal transmitted from the external device through the communication unit 120, and may adjust the output of the illumination unit 140 based on the illumination control signal. The user can control the operation of the wireless lighting device 100 by using a smart phone or the like which is an external device. For example, the user may operate the smart phone to output blue light in the wireless lighting device 100 installed in the space where the user is located, thereby performing a space presentation that can feel a refreshing feeling. At this time, 130 may generate processing signals of the respective units for performing the operation.

As described above, the control unit 130 can evaluate the signal reception strength of each of a plurality of communication methods used in the communication unit 120, and can use a communication method in which the signal reception strength of a predetermined reference value or more is measured at the time of information transmission and reception.

The control unit 130 can search for an external device capable of transmitting and receiving information through the communication unit 120. [ Here, the controller 130 may evaluate the signal reception strength measured at the time of performing communication with the searched external device, and generate connection possibility information based on the signal reception strength. The connectivity information may include a list of external devices capable of communicating with the wireless lighting device 100, a communication method used to transmit and receive information to and from each external device, and signal strength information have. Since the communication environment and conditions vary depending on the position where the wireless lighting device 100 is installed, the control unit 130 can generate different connectivity information depending on each location. In addition, when an external terminal capable of wireless communication such as a smart phone accesses the wireless lighting device 100, the external terminal may be added to the connection possibility information. The control unit 130 can immediately determine whether a new external device is added through the communication unit 120. If the change of the network environment is detected, the control unit 130 can immediately update the connectivity possibility information. The control unit 130 may transmit the connectivity information stored in the wireless lighting device 100 to the other wireless lighting device through the communication unit 120 and may receive connection possibility information of another wireless lighting device. The control unit 130 may generate a network map indicating the network connection relationship of the entire wireless lighting device and other external devices by referring to the connection possibility information of the received other wireless lighting devices. For example, a simple structure may be assumed in which the first wireless illumination device is connected to the second wireless illumination device and the second wireless illumination device is connected to the third wireless illumination device. According to an embodiment of the present invention, the second wireless illumination device is included in the connectivity information of the first wireless illumination device, and the first wireless illumination device and the third wireless illumination device are included in the connectivity information of the second wireless illumination device And the second wireless illumination device may be included in the connectivity information of the third wireless illumination device. When each connectivity possibility information is shared with all wireless lighting devices to generate a network map, all wireless lighting devices determine that the entire network is the first wireless lighting device, the second wireless lighting device, and the third wireless lighting device are connected in series can do. The control unit 130 refers to the network map when transmitting at least one of the environment information sensed by the sensing unit 110, the processing signal generated by the control unit 130, and the information received from the external equipment through the communication unit 120 . The manner in which the control unit 130 efficiently transmits information with reference to the network map will be described in detail with reference to FIGS. 2 to 6. FIG.

The illumination unit 140 may output light in accordance with a processing signal of the control unit 130. The light source of the illumination unit 140 may be preferably provided as an LED, but is not limited thereto and may be provided in various ways. The illumination unit 140 can output light through a plurality of light sources. In addition, the illumination unit 140 may output various colors and may change the color temperature according to the processing signal of the controller 130. The illuminating unit 140 may output a flickering light at a predetermined interval according to a process signal of the controller 130, and gradually adjust the illuminance through a continuous change in light intensity.

The illumination unit 140 may further include a condensing module 142 for blocking light output from the light source or reflecting the light at a specific angle and a driving module 144 for adjusting the position and direction of the condensing module 142.

The light collecting module 142 may be provided in various forms. The light collecting module 142 may be composed of a combination of a plurality of blocking films, or may be configured in a single tube shape. The surface of the light collecting module 142 may be colored black to absorb light or may be made of a silver material having a smooth surface to reflect light.

The drive module 144 may include a motor that converts electrical signals into power. A plurality of driving modules 144 may be provided and connected to the respective components of the condensing module 142. The drive module 144 spreads the light of the light source by spreading the light condensing module 142 toward the outward direction of the light source by an electric signal or by pivoting the light condensing module 142 inward to reduce the light output area . The driving module 144 can tilt the condensing module 142 in a specific direction by an electrical signal. The control unit 130 may receive information for adjusting the direction of light output from the illumination unit 140 and the degree of dispersion of light through the communication unit 120. [ The control unit 130 may generate a processing signal for controlling the operation of the condensing module 142 and the driving module 144 of the illumination unit 140 by referring to the information for adjusting the direction of the light and the degree of dispersion of the light. For example, the user can control the wireless lighting device 100 installed in the exhibition room through a smart phone or the like, which is an external device. At this time, the user can input an operation of concentrating the light of the wireless lighting device 100 only on specific exhibits in the exhibition room through the smartphone, and the control unit 130 of the wireless lighting device 100, The processing signal for adjusting the position and direction of the condensing module 142 may be generated to reduce the optical output radius. The driving module 144 may be provided outside the wireless lighting device 100 to change the direction of light output from the lighting unit 140 by rotating the entire wireless lighting device 100.

The control unit 130 controls the illumination unit 130 according to a predetermined operation method when an emergency situation occurs so that the direction of light output from the light source to the wireless lighting device 100 can be directed to the adjacent emergency exit.

When the wireless lighting device 100 is configured as shown in FIG. 1, the user can freely install the wireless lighting device 100 in the space, and a separate relay device for controlling the wireless lighting device 100 is not required . If the installed wireless lighting device 100 can not be connected to the external network, the user may be notified of the fact by outputting a light blinking or a sound. The user can refer to the warning signal generated from the wireless lighting device 100 to take measures such as moving the installation position of the wireless lighting device 100 or using an additional device to help the network connection.

2 is a diagram illustrating a wireless lighting system 1000 in accordance with an embodiment of the present invention. 2, a plurality of wireless lighting devices 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100i, 100j, 100k, Can be installed. Each wireless lighting device is connected to a wireless or wired network, and has individual connectivity information and network map information. Since each wireless lighting device is tightly networked to each other, information generated in one wireless lighting device can be immediately transmitted to another wireless lighting device. A user can easily operate a wireless lighting device in a space in which the user is located and a wireless lighting device in another place by using an external device such as a smart phone. For example, if the user enters the upper left room of FIG. 2, both wireless lighting devices 100a, 100b may immediately recognize the user's smartphone and include it in their connectivity information. The connectivity information may be propagated throughout the wireless lighting system 1000 so that all wireless lighting devices may have a network map containing the user's smartphone. The user can operate the lighting state of the room where the user is located and the lighting state of the other place through a separate application or the like and the operation information can be transmitted to the corresponding wireless lighting device through the network of the wireless lighting system 1000. Alternatively, the user can register a specific wireless lighting device to be used mainly and control the operation of the wireless lighting device without any restriction on the place. A detailed description of the connectivity information and the network map will be given in Figs. 3 to 4.

3 is a diagram illustrating a network map 2000A generated in a wireless lighting device according to an embodiment of the present invention. In FIG. 3, circles are simplified views of the wireless lighting devices 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100i, 100j, 100k and 100l in FIG. 2, . In FIG. 3, squares and dotted lines shown by dashed lines indicate connectivity information of each wireless lighting device.

The wireless lighting devices 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100i, 100j, 100k, and 100l can transmit and receive information to each other by a wired or wireless network. However, the wireless lighting devices 100a, 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100i, 100j, 100k, Because of the disturbing factors, problems can arise in sending and receiving information directly.

FIG. 3 shows a transmission / reception path of information that can be generated according to the internal structure of the building and installation positions of the wireless lighting devices of FIG. For example, the wireless lighting device 100a located at the uppermost left can transmit and receive information directly to and from two adjacent wireless lighting devices 100b and 100i. However, the wireless lighting device 100a may be installed in other wireless lighting devices 100b, 100c, 100d, 100e, 100f, 100g, 100h, 100j, 100k, and 100l, Can not directly transmit and receive information. As described above, the wireless lighting device 100a at the upper left can evaluate the reception intensity of signals and the like, and can determine that information can be transmitted and received between the two wireless lighting devices 100b and 100i. The devices 100b and 100i can be recorded. The above process is also performed in all other wireless lighting devices, so that each wireless lighting device can generate unique connectivity information. The connectivity information of the wireless lighting device 100a may be transmitted to the wireless lighting devices 100b, 100i via the network and then to the wireless lighting devices 100g, 100h, 100j, 100e, 100k, and so on. If the information transmission process is repeated, the connectivity information of the wireless lighting device 100a may be transmitted to all other wireless lighting devices. When the connectivity information held by each wireless lighting device is shared by all the wireless lighting devices, each wireless lighting device can generate the network map 2000A referring to the transmitted connectivity information. Alternatively, the wireless lighting device that senses a new external device may update the connectivity information, and may share the updated networkability map and the network map reflecting the updated connectivity information with the entire network. That is, a network map may be generated in each wireless lighting device, and a network map generated in one wireless lighting device may be shared in the entire network.

Meanwhile, the control unit of the wireless lighting device can determine the intensity of the received signal when transmitting and receiving information through the communication unit. In FIG. 3, a bold solid line indicates an information transmission / reception path with a signal reception strength of a predetermined reference value or higher, and a thin broken line indicates an information transmission / reception path with a signal reception intensity lower than a predetermined reference value. Further, the wireless illuminator identification code located on the upper side in the connectivity information of each wireless lighting apparatus indicates that the reception strength of the signal is equal to or greater than a preset reference value. When transmitting / receiving information through the communication unit, the control unit can transmit / receive information using an information transmission / reception path whose reception intensity of the signal is equal to or higher than a preset reference value.

The controller may determine that the connection is stable if the signal reception strength associated with the connectivity information is greater than a preset reference value. Also, the control unit can create a network by referring to the connectivity information determined as the stable connection.

4 is a diagram illustrating a network map 2000B generated using connectivity information that is determined as a stable connection. Compared with the network map 2000A of FIG. 3, each wireless lighting device has a simpler connection relationship, and the wireless lighting device identification code included in the connectivity information is also reduced. Although the number of external devices capable of transmitting and receiving information has been reduced in each wireless lighting apparatus, the connection relationship has an excellent information transmission rate and signal reception strength with guaranteed transmission and reception quality of information.

Meanwhile, if the WiFi AP is connected to the wireless lighting device 100a as an external device, the entire wireless lighting system can access the external Internet through the wireless lighting device 100a. For example, environmental information sensed by the wireless lighting device 100l may be transmitted to the wireless lighting device 100a via the intermediate wireless lighting devices 100k, 100j, 100i, and 100b, and the information may be transmitted to the external Internet. Conversely, the lighting control information transmitted from the external Internet through the wireless lighting device 100a may be transmitted to the wireless lighting device 100g through the wireless lighting devices 100b, 100i, and 100h.

5 is a diagram illustrating a method of transmitting information by a wireless lighting device according to an embodiment of the present invention. FIG. 5 shows a state in which a wireless lighting device 100j recognizes a smart phone 200, which is an external device adjacent thereto, and transmits and receives information to each other in addition to the connection possibility information. In FIG. 5, the specific wireless lighting device 100c that the user wants to control using the smartphone 200 is indicated by vertical stripes. A method of transmitting information by referring to a network map in a wireless lighting system is described below.

First, the wireless lighting device 100j may receive information to be transmitted from the smartphone 200 to a specific wireless lighting device 100c. Upon receiving the information, the wireless lighting device 100j recognizes the smartphone 200 that has transmitted the information as the first external device, and can identify the identification code. The wireless lighting device 100j confirms the connection possibility information and confirms an external device list capable of transmitting / receiving information directly to / from the wireless lighting device 100j. The wireless lighting device 100j can transmit information through the communication unit when the wireless lighting device is included in the connectivity information or when there is a second external device connected to the specific wireless lighting device. According to Fig. 5, the connection possibility information of the wireless lighting device 100j does not include the specific wireless lighting device 100c. However, the wireless lighting device 100e connected to the specific wireless lighting device 100c exists as the second external device in the connection possibility information of the wireless lighting device 100j. That is, the wireless lighting device 100j can determine the network connection relationship of each wireless lighting device using the network map, and determine whether to transmit the information with reference to the network map.

The information transmitted from the wireless lighting device 100j can preferably be transmitted only to the wireless lighting device 100e. The wireless illumination device 100e receiving the information can recognize the wireless illumination device 100j that has transmitted the information as the first external device and discriminate the corresponding identification code as in the case of the wireless illumination device 100j. The wireless lighting device 100e checks the connection possibility information and confirms an external device list that can directly transmit and receive information to and from the wireless lighting device 100e. The wireless lighting device 100e can determine that the particular wireless lighting device 100c is included in the connectivity information, and accordingly, transmits the information.

On the other hand, when information is transmitted from the wireless lighting device 100j to the wireless lighting device 100e, if the antenna of the wireless lighting device 100j is not provided with directivity or does not perform beam forming, 100i and 100k connected to the wireless wireless communication devices 100i and 100k. The wireless lighting devices capable of receiving the information transmitted from the wireless lighting device 100j are indicated by thin dashed lines in Fig. Upon receiving the information to be transmitted to the wireless lighting device 100c, the wireless lighting device 100i can identify the identification code of the wireless lighting device 100j that has transmitted the information and the identification code of the specific wireless lighting device 100c to finally receive the information. The wireless lighting device 100k can determine that the transmission path of the information transmitted to the wireless lighting device 100j by 100k is wrong by referring to the identification codes and the network map and accordingly the wireless lighting device 100k does not send any more information . The same process is also performed in the wireless lighting device 100i so that the wireless lighting device 100i no longer transmits the information.

By transmitting information in the manner described above, the wireless lighting system can prevent information from being unnecessarily transmitted, thereby enabling more efficient network management.

FIG. 6 is a diagram illustrating another way in which a wireless lighting device according to an embodiment of the present invention transmits information. FIG. 6 shows a state in which a wireless lighting device 100k recognizes a smartphone 200, which is an external device adjacent to the wireless lighting device 100k, and adds and transmits information to the connection possibility information. In FIG. 6, the specific wireless lighting device 100c that the user wants to control using the smartphone 200 is indicated by vertical stripes. A method of transmitting information by referring to a network map in a wireless lighting system is described below.

First, the wireless lighting device 100k may receive information to be transmitted from the smartphone 200 to a specific wireless lighting device 100c. The wireless lighting device 100k to which the information is transmitted can generate an information transmission path by referring to the connectivity information and the network map. The control unit of the wireless lighting device 100k can generate the most efficient transmission path for transmitting information to the specific wireless lighting device 100c by referring to the connection relationship between the wireless lighting device included in the network map and other external devices. The information transmission path may be calculated by referring to the signal reception strength and the signal transmission rate recorded in the connectivity possibility information of each wireless lighting apparatus. The information transmission path may be calculated in various ways according to criteria such as transmission speed and stability. In Fig. 6, the information transmission path is a wireless illumination device 100k, 100j, 100e shaded with a diagonal stripe. The wireless lighting device 100k may also transmit the information transmission path when transmitting information. In Fig. 6, the information transmission path (a) transmitted from the wireless lighting device 100k to the wireless lighting device 100j is indicated by a solid line, and the identification information of the wireless lighting devices 100j and 100e is included in the information transmission path.

The information transmitted by the wireless lighting device 100k may preferably be transmitted to the wireless lighting device 100j. The wireless lighting device 100j can receive the information to be transmitted to the specific wireless lighting device 100c and the information transmission path together. The wireless lighting device 100j can confirm that the identification code of the wireless lighting device 100j is included in the information transmission path and can transmit the information accordingly. The wireless lighting device 100j may transmit the received information transmission path (a) as it is or may transmit the information transmission path (b) excluding the identification code of the wireless lighting device 100j in the information transmission path. The wireless lighting device 100e repeats the above process, and information can finally be transmitted to the specific wireless lighting device 100c.

The information transmitted from the wireless lighting device 100j can preferably be transmitted only to the wireless lighting device 100e. However, when the antenna of the wireless lighting device 100j is not provided with a directivity or does not perform beam forming, information transmitted from the wireless lighting device 100j is also transmitted to other wireless lighting devices 100i and 100k connected on the network map .

On the other hand, when information is transmitted from the wireless lighting device 100k to the wireless lighting device 100j, if the antenna of the wireless lighting device 100j is not provided with directivity or does not perform beamforming, Lt; RTI ID = 0.0 > 100l < / RTI > At this time, the wireless lighting device 100l can confirm that the wireless lighting device 100l is not included in the received information transmission path, and does not perform signal transmission accordingly. This is also applied to the wireless lighting apparatuses 100i and 100f that have received information unnecessarily during the signal transmission process. The two wireless lighting devices 100i and 100f can receive information, but can determine that their identification code is not included in the information transmission path, and thus do not perform signal transmission.

Like the case of FIG. 5, the wireless lighting system of FIG. 6 also prevents information from being unnecessarily transmitted, thereby enabling efficient network management. In the information transmission method of FIG. 6, only the wireless lighting device included in the information transmission path transmits a signal. At this time, since each wireless lighting device only has to check whether its identification code is included in the information delivery path, The process is simple.

As described above, according to the present invention, there is provided a wireless lighting device capable of actively configuring a network between each wireless lighting device without a relay device and a separate central control device, and easily controlling lighting of the wireless lighting device through the network can do.

In addition, according to the present invention, it is possible to detect environment and network state change in which the wireless lighting device is installed in real time. In particular, according to the embodiment of the present invention, a network map can be generated from the network state, and illumination control information can be efficiently transmitted and received with reference to the network map. In addition, according to the present invention, the network map can be updated automatically when a change in the state of the network due to addition of external devices is detected.

In addition, each wireless lighting device can easily share various information, and it is possible to effectively manage the network by suppressing transmission of unnecessary information when sharing the information.

7 is a diagram illustrating a method of controlling a wireless lighting device according to an embodiment of the present invention. 7 is a flowchart illustrating a method of controlling a wireless lighting device according to an exemplary embodiment of the present invention. Referring to FIG. 7, a method of controlling a wireless lighting device according to an exemplary embodiment of the present invention includes a step S 110 of searching for an external device, a step S 120 of generating connectivity information, a step S 130 of generating a network map Receiving information (S150) and transmitting the information by referring to the network map (S160). In addition, the step of determining whether to add a new external device (S140) may be further included.

In the external device search step (S110), the wireless lighting device recognizes an external device and determines whether or not network communication with the external device is possible.

The connection possibility information generation step S120 is a step of evaluating the signal reception strength measured at the time of performing communication with the searched external device and generating the connectivity possibility information based on the reception strength.

The step of generating a network map (S130) receives connection possibility information of the other wireless lighting devices and generates a network map representing the connection relationship of all the wireless lighting devices by referring to the connection possibility information.

Here, the step S 120 of generating the connectivity information based on the reception strength may determine that the connection is stable if the signal reception strength associated with the connectivity information is equal to or greater than a predetermined reference value. And, in the step of generating the network map (S130), the network map can be generated by referring to the connectivity information determined as the stable connection. The wireless lighting device can form a network having excellent information transmission speed and reliability by referring to the network map composed of the stable connection.

The step of determining whether a new external device is added (S140) is a step of confirming the presence of a new external device in the wireless lighting device. If it is determined that there is a new external device at this stage, the wireless lighting device updates the connection possibility information through the step of searching for the external device (S110) and generating the connectivity possibility information (S120) again, A new external device may be added to the existing network map in step S130. The wireless lighting device can always have a network map reflecting the latest network environment status by continuously repeating the above four steps.

Step S150 of receiving information from the external device is a step in which the wireless lighting device receives the illumination control information or the like from the adjacent wireless lighting device or other external device. The wireless lighting device determines the final destination of the received information, and performs sub-control according to the information.

The step S160 of transmitting the information with reference to the network map is a step of efficiently transmitting information using the network map held by each wireless lighting apparatus. If the final destination of the information received in the step of receiving information from the external device (S150) is not the wireless lighting device, the wireless lighting device again transmits the received information. There are two main ways in which wireless lighting devices transmit information using network maps.

First, the wireless lighting device can receive information to be transmitted to a specific external device in the step of receiving information from the external device (S150). In the step S160 of transmitting the information by referring to the network map, the wireless lighting device can identify the identification code of the first external device that has transmitted the information and the identification code of the specific external device that finally receives the information have. The wireless lighting device may transmit information to the specific external device or the second external device when the connection possibility information includes the specific external device or a second external device is connected to the specific external device. That is, the wireless lighting device can determine the connection relation between the specific external device and the wireless lighting device by having the network map, and can determine whether or not to transmit the information.

Another way in which the wireless lighting device transmits information using a network map is as follows.

First, the wireless lighting device can receive information to be transmitted to a specific external device in the step of receiving information from the external device (S150). The step S160 of transmitting the information with reference to the network map may generate an information transmission path by referring to the connection possibility information and the network map, and may transmit the information transmission path together when information is transmitted. That is, the wireless lighting device that receives the information for the first time can generate an information transmission path by referring to the network map, and transmit the same. The other wireless lighting device which receives the information to be transmitted to the specific external device together with the information transmission path can check whether the identification code of the corresponding wireless lighting device is included in the information transmission path and can transmit the information if included. Only the wireless lighting device included in the information transmission path transmits information, and each wireless lighting device can check whether or not its identification code is included in the information transmission path, so that the network can be managed simply and efficiently.

By using the wireless lighting control method described above, the user can easily share various information among the respective wireless lighting devices and actively cope with changes in the network environment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Accordingly, it is to be understood that within the scope of the appended claims, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

100: Wireless light device
110:
120:
130:
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1000: Wireless lighting system
2000: Network Map

Claims (11)

A sensing unit sensing a change in an external environment;
A communication unit for transmitting and receiving information to and from an external device;
A control unit for generating a processing signal for controlling the operation of each unit; And
An illumination unit for outputting light according to the processing signal; , ≪ / RTI &
Wherein,
Receives a lighting control signal from an external device through the communication unit and generates a processing signal for adjusting an output of the lighting unit based on the lighting control signal,
In addition, an external device capable of performing wireless communication through the communication unit is searched,
Evaluating signal reception strength measured at the time of performing communication with the searched external device to generate connectivity possibility information based on the reception strength,
Generates a network map of all the wireless lighting apparatuses by referring to the connectivity information of the other wireless lighting apparatuses received through the communication unit,
Wherein the control unit refers to the network map when transmitting at least one of the environment information sensed by the sensing unit, the processing signal generated by the control unit, and the information received from the external equipment through the communication unit. The method according to claim 1,
Wherein,
Receiving information to be transmitted from a first external device to a specific external device through the communication unit,
When the connection possibility information includes the specific external device or a second external device is connected to the specific external device,
And transmits the information to the specific external device or the second external device via the communication unit. The method according to claim 1,
Wherein,
When receiving information to be transmitted to a specific external device through the communication unit,
Generates an information delivery path by referring to the connection possibility information and the network map,
And the information transmission path is also transmitted when the information is transmitted through the communication unit. The method according to claim 1,
Wherein,
Transmits and receives information through at least two types of communication methods,
Wherein,
The signal reception strength is evaluated for each communication method of the communication unit,
Wherein the wireless communication apparatus uses a communication method in which a signal reception intensity of a predetermined reference value or more is measured when information is transmitted or received through the communication unit. The method according to claim 1,
Wherein,
If the signal reception strength associated with the connection possibility information is equal to or greater than a preset reference value,
And generates the network map with reference to the connectivity information determined as the stable connection. The method according to claim 1,
Wherein,
The sensing unit senses the movement of objects including illumination, temperature, humidity, and people,
And transmitting the sensed information through the communication unit,
And controls the output of the illumination unit according to a predetermined operation method based on the sensed information. The method according to claim 1,
The illumination unit includes:
A condensing module for blocking light output from the light source or reflecting the light at a specific angle; and
A driving module for adjusting a position and a direction of the condensing module; Further comprising:
Wherein,
And a control unit that receives information for adjusting the direction of light output from the illumination unit and the degree of dispersion of light through the communication unit,
And generates a processing signal for controlling operation of the light-condensing module and the driving module based on the received information. Searching for an external device;
Evaluating a signal reception strength measured when performing communication with the searched external device, and generating connectivity information based on the reception strength;
Receiving connectivity information of another wireless lighting device and creating a network map of all wireless lighting devices with reference thereto;
Receiving information from an external device; And
Transmitting information by referring to the network map; And a controller for controlling the wireless lighting device. 9. The method of claim 8,
The step of receiving information from the external device comprises:
Receives information to be transmitted to a specific external device,
Wherein the step of transmitting information by referring to the network map comprises:
The identification code of the first external device that has transmitted the information and the identification code of the specific external device that finally receives the information,
When the connection possibility information includes the specific external device or a second external device is connected to the specific external device,
And transmits the information to the specific external device or the second external device. 9. The method of claim 8,
The step of receiving information from the external device comprises:
Receives information to be transmitted to a specific external device,
Wherein the step of transmitting information by referring to the network map comprises:
Generates an information delivery path by referring to the connection possibility information and the network map,
And transmits the information transmission path together when information is transmitted. 9. The method of claim 8,
Wherein the step of generating connectivity information based on the reception strength comprises:
If the signal reception strength associated with the connection possibility information is equal to or greater than a preset reference value,
Wherein the generating the network map comprises:
And the network map is generated by referring to the connectivity information determined as the stable connection.

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