KR102170822B1 - An internet of things based integrated control device for DMX-512 lightings and a method thereof - Google Patents

Abstract

The present invention discloses a DMX-512 lighting integrated control apparatus and method based on the Internet of Things. The apparatus includes: a lighting directing data generating unit for designing a lighting directing program, downloading a command list from among the designed lighting directing programs, and transmitting first remote control data for primarily remotely controlling lighting directing of a plurality of lighting devices; An Internet of Things detection unit generating a dimming control command in response to sensing data in which a real-time fluctuation situation is sensed, and transmitting second remote control data for remotely controlling the lighting presentation; And a plurality of lighting integrated controllers outputting device control signals that command driving of the plurality of lighting devices in response to the lighting directing program and the first and second remote control data. And wherein the plurality of lighting devices are adaptively driven individually and in groups according to the real-time fluctuations in response to the device control signal.

Description

TECHNICAL FIELD An internet of things based integrated control device for DMX-512 lightings and a method thereof

The present invention relates to a lighting control device and method, and in particular, by integrated control of the primary remote control of the DMX-512 LED lighting configured in advance and the secondary remote control of the Internet of Things including various sensors, The present invention relates to an IoT-based DMX-512 lighting integrated control apparatus and method for adaptively responding to an operation according to the use of a plurality of lighting devices.

In general, systems have been developed to enable more efficient adjustment of a plurality of lights, and each system has certain limitations depending on its configuration.

For example, in a lighting control system to which DMX-512 (ANSI E1.1), which is one of the international communication protocols, is applied, a console device that generates a DMX-512 data packet signal for controlling each lighting and a DMX transmitted from the console device When configuring the connection method between receiving devices that control the lighting device by receiving the -512 data packet signal in a parallel manner, a channel order must be set for each receiving device.

In this case, in order to set the channel order, a dip switch for setting the channel order must be attached to each receiving device.If there are multiple receiving devices connected to the console device (DMX-512 system receives up to 512 receiving devices) Devices can be connected), the configuration of the entire lighting control system becomes very complex, making it difficult to apply to small lighting equipment systems.

That is, there is a certain limitation in applying the DMX-512 (ANSI E1.1) protocol, which is mainly applied to lighting control systems of theaters or indoor and outdoor stadiums, to indoor lighting control systems such as homes or offices.

Accordingly, development of an efficient lighting control system that can simplify the configuration of the lighting control system even in the DMX-512 (ANSI E1.1) protocol environment is requested.

Here, the DMX-512 protocol is a digital multiplex communication protocol created by the American Theater Technology Association (USITT) in 1986 to control a lighting console dimmer, and is a method of transmitting data in the form of a data stream.

This protocol method is a transmission protocol capable of transmitting information on up to 512 channels, and is currently used in various lighting control systems such as theaters and stadiums.

On the other hand, landscape lighting refers to lighting that expresses a light environment that cannot be found in a daytime landscape by systematizing the relationship between various lights that make up a city, with an emphasis on the formation of a landscape by light.

The landscape lighting facility is a lighting facility designed to enhance the effect of landscape and design by focusing lighting on various sculptures, statues of great men, and the exterior of buildings, and to induce public attention and interest.

In recent years, many of these landscape lighting facilities are mainly installed around various sculptures using LEDs to concentrate a number of landscape lightings on the sculptures.

However, there is a limitation in that it is not possible to induce interest of the general public due to the lack of landscape lighting facilities in places and facilities that attract public attention, such as various sculptures and works of art installed in parks, etc., and statues and cultural relics of great persons.

Therefore, attempts and studies were needed to overcome these limitations to improve visual landscape and design effects in addition to the function of simply classifying and bordering roads.

Meanwhile, a light emitting diode (LED) is an optoelectronic device that has a junction structure of a P-type and an N-type semiconductor, and emits light of energy corresponding to the band gap of the semiconductor by combining electrons and holes when a voltage is applied. However, the reaction time is faster than that of ordinary light bulbs, and the power consumption is lowered to about 20%, so it is being used in a wide variety of fields including high-efficiency lighting devices.

Flood lighting using such light emitting diodes utilizes a module in which a number of high-intensity light emitting diodes or power light emitting diodes are assembled on a substrate as a light source, and is used as a light source for signboards, structure lighting, bridges, etc. It is being used as a means.

In addition, a lighting lamp using light-emitting diodes is a method of arranging a plurality of light-emitting diodes on a printed circuit board formed in a disc shape or in various shapes so that they can be used as a general lighting lamp, and a solid or flexible printed circuit having a strip shape. It is used in various forms such as a line bar type method in which a plurality of light emitting diodes are arranged on a substrate at regular intervals.

The former case is widely used for general lighting or traffic lights, and the latter case is widely used for lighting such as high-rise buildings, bridges, overpasses, or advertisements.

For such landscape lighting, many landscape lighting devices are required. In the past, many landscape lighting devices were individually controlled, but recently, controlling many landscape lighting devices through a single control device through the DMX-512 protocol method. It became possible.

In other words, in the past, lighting control technology was dominated by the concept of ON/OFF that simply turns on and off lights, but in recent years, multiple lights such as landscape lighting or stage lighting are turned on/off according to a certain program. Centralized lighting control systems that can control the illuminance of each light at once are becoming common.

In addition, in order to more smoothly and directly respond to the control of LED lighting fixtures in a remote control system such as the Internet of Things including various sensors, which is currently common, the conventional PWM dimming control of DMX-512 LED lighting control and A method of mixing IoT remote control including sensors has been used.

Here, the Internet of Things (IOT) method refers to communication for providing object information to a person or an intelligent device using a communication network, or for a person or an intelligent device to control the state of an object.

In the past, IoT communication in the late 1990s meant one-to-one or one-to-many communication for a simple point-to-point (P2P) connection. Ultimately, the goal of IoT communication is location awareness, context awareness, and augmented reality. It aims to improve the quality and stability of Internet of Things communication services by operating automatically without human control or with minimal human intervention, tailored to the individual or situation through introduction.

Currently, there are a wide variety of services such as remote meter reading, building or facility management, vending machine management, indoor lighting control service, traffic information and vehicle control, emergency dispatch, fire alarm, security alarm, telematics, wireless payment services, etc. It is being provided.

IoT communication is a communication between IoT devices, and differs from the existing human-oriented H2H (Human-to-Human) communication in several characteristics.

From these differences in characteristics, technically necessary technologies may vary, and necessary characteristics may vary slightly depending on the application field using IoT communication.

However, in order to more smoothly and directly respond to the control of LED lighting fixtures in a remote control system such as the Internet of Things including various sensors that are currently common, the conventional pulse width modulation dimming of DMX-512 LED lighting control ) A method that mixes remote control of IoT and Internet of Things including sensors has been used.

However, in this method, there is an instability that occurs when both control methods are not compatible, so that some lighting devices are not partially controlled, and when control of the entire lighting device becomes impossible.

Meanwhile, the conventional lighting control method requires a wired line to be installed between the lighting device and the console that controls the lighting device, so that the connection is complicated and high cost is required.

That is, when one lighting device fails, a lot of time and cost are required for repair, and there is a problem that control of other lighting devices is impossible due to a failure of one lighting device.

In order to improve this problem, there have been attempts to control a lighting device in a wireless manner.

However, in the case of RS-232C protocol, which is currently used in the data transmission/reception unit when connecting wired and wireless networks, there is no reception regulation for special characters and break marks used in the DMX-512 protocol, so it is not compatible with the DMX-512 protocol. Due to limitations, the wireless control method DMX-512 has not been developed.

Accordingly, there is a growing demand for a control device capable of overcoming the irrationality of the conventional lighting control system according to the DMX-512 method and for real-time analysis and transmission of color and illuminance by using a DMX-512 signal as a wireless module.

In particular, PWM dimming of DMX-512 LED lighting control in order to respond more flexibly and smoothly according to real-time fluctuations in real-time fluctuations in the control method of a remote control system such as the Internet of Things (IoT), which is currently common. It is a reality that there is a need for integrated control of both methods that can overcome the instability due to the incompatibility of the method of mixing (Dimming) control and the Internet of Things (IoT) remote control.

In addition, the wireless DMX lighting control system has limitations due to the use of wireless signals, and there is also a problem of signal transmission due to interference of wireless signals.

That is, the circuit configuration is performed in a variety of ways that are unspecified due to the characteristics of the electrical circuit configuration of the lighting control communication, and there is a possibility that distortion of the communication signal due to various electrical noises accompanying this may occur.

KR 10-0598932 B1

An object of the present invention is to provide an IoT-based DMX-512 lighting integrated control device capable of integrating and controlling the primary remote control of the DMX-512 LED lighting configured in advance and the secondary remote control of the IoT including various sensors. To provide.

Another object of the present invention is to provide an IoT-based DMX-512 lighting integrated control method to achieve the above object.

In the IoT-based DMX-512 lighting integrated control device of the present invention for achieving the above object, a lighting directing program is designed, and a command list is downloaded from among the designed lighting directing programs to primarily perform lighting direction of a plurality of lighting devices. A lighting direction data generation unit for transmitting first remote control data to be remotely controlled; An Internet of Things detection unit generating a dimming control command in response to sensing data in which a real-time fluctuation situation is sensed, and transmitting second remote control data for remotely controlling the lighting presentation; And a plurality of lighting integrated controllers outputting device control signals that command driving of the plurality of lighting devices in response to the lighting directing program and the first and second remote control data. And wherein the plurality of lighting devices are adaptively driven individually and in groups according to the real-time fluctuations in response to the device control signal.

The lighting directing data generation unit of the DMX-512 lighting integrated control device based on the Internet of Things of the present invention for achieving the above object is applied with a configuration of a plurality of layers to design the lighting directing program, and stores the designed lighting directing program. A user terminal to store it in; And a remote control device for downloading the command list and transmitting the first remote control data for remotely controlling the lighting direction for each layer. It characterized in that it comprises a.

The remote control device of the DMX-512 lighting integrated control apparatus based on the Internet of Things of the present invention for achieving the above object comprises: a first wireless receiver for downloading the command list; A lighting presentation application that displays the downloaded command list in a menu format on a screen; And a first wireless transmitter configured to load and transmit the presentation information manipulated in the lighting presentation application on a signal of a selected frequency among a plurality of signals having different frequencies into the first remote control data. It characterized in that it comprises a.

To achieve the above object, the IoT sensing unit of the IoT-based DMX-512 lighting integrated control device of the present invention detects real-time fluctuations according to the use of the plurality of lighting devices, and outputs the sensing data. ; A dimming control command generation unit receiving the sensing data and generating a dimming control command for adjusting illuminance of the plurality of lighting devices; And a remote control data transmission unit that receives the dimming control command, converts it to the second remote control data, and transmits it. It characterized in that it comprises a.

Each of the plurality of integrated lighting control units of the DMX-512 lighting integrated control apparatus based on the Internet of Things of the present invention for achieving the above object comprises: a lighting control signal receiving unit receiving the lighting directing program and the first remote control data; A dimming control signal receiving unit receiving the second remote control data; An input signal controller configured to receive the lighting presentation program and the first and second remote control data, analyze a color and illuminance level of a lighting fixture, and an illuminance level related to the Internet of Things, and output an integrated control signal; And a pulse width modulation controller configured to output the device control signal for controlling the illuminance of each of the plurality of lighting devices by receiving the integrated control signal and modulating the pulse width. It characterized in that it comprises a.

Each of the plurality of lighting devices of the DMX-512 lighting integrated control apparatus based on the Internet of Things of the present invention for achieving the above object comprises: a second wireless receiver configured to receive the device control signal through a wireless communication network; A driving unit for driving the lamps individually and in groups by adaptively controlling turn-on and turn-off operations and illuminance of the lamp in real time according to pre-designed direction information and the sensing data in response to the received device control signal; And a second wireless transmitter that transmits data on the operation of the driven lamp and the adjusted illumination intensity to a corresponding lighting integration control unit among the plurality of lighting integration control units. It characterized in that it comprises a.

The first to second wireless transmitters of the DMX-512 lighting integrated control device based on the Internet of Things of the present invention to achieve the above object, have an isolation resistance as a signal isolating device at the output terminal to prevent distortion of the transmission signal due to noise. It characterized in that it is mounted.

In order to achieve the above object, a power supply unit for supplying power for a lighting device is connected to each of the plurality of integrated lighting control units of the DMX-512 lighting integrated control device based on the Internet of Things of the present invention.

In the IoT-based DMX-512 lighting integrated control method of the present invention for achieving the other object, (a) a lighting directing program is designed on a lighting directing data generator, and a command list is downloaded from the designed lighting directing program, and a plurality of Transmitting first remote control data for primarily remotely controlling lighting direction of the lighting devices; (b) generating a dimming control command in response to sensing data in which a real-time fluctuation situation is sensed by the IoT sensor, and transmitting second remote control data for secondary remote control of the lighting presentation; (c) outputting, by a plurality of integrated lighting controllers, a device control signal commanding driving of the plurality of lighting devices in response to the lighting directing program and the first and second remote control data; And (d) adaptively driving the plurality of lighting devices individually and in groups according to the real-time fluctuations in response to the device control signal. It characterized in that it comprises a.

In the step (a) of the DMX-512 lighting integrated control method based on the Internet of Things of the present invention for achieving the other object, the lighting presentation program is designed by applying a plurality of layers configuration on the user terminal (a-1) , Storing the designed lighting presentation program in a storage unit; And (a-2) downloading, by a remote control device, the command list and transmitting the first remote control data for remotely controlling the lighting direction for each layer. It characterized in that it comprises a.

The step (a-2) of the integrated control method for DMX-512 lighting based on the Internet of Things of the present invention for achieving the other object includes: downloading the command list by a first wireless receiver in the remote control device; Displaying, by the lighting directing application, the downloaded command list in a menu format on a screen; And loading, by a first wireless transmission unit, the direction information manipulated in the lighting presentation application on a signal of a selected frequency among a plurality of signals having different frequencies into the first remote control data. It characterized in that it comprises a.

The step (b) of the IoT-based DMX-512 lighting integrated control method of the present invention for achieving the other object is a situation in which the sensor unit in the IoT sensing unit changes in real time according to the use of the plurality of lighting devices. Sensing and outputting the sensing data; Generating a dimming control command for adjusting the illuminance of the plurality of lighting devices by receiving the sensing data by a dimming control command generator; And receiving, by a remote control data transmission unit, the dimming control command, converting it into the second remote control data, and transmitting the received dimming control command. It characterized in that it comprises a.

In the step (c) of the IoT-based DMX-512 lighting integrated control method of the present invention for achieving the other object, the lighting control signal receiver in the plurality of lighting integrated controllers includes the lighting directing program and the first remote control. Receiving data authorization; Receiving, by a dimming control signal receiver, the second remote control data; Receiving, by an input signal controller, the lighting presentation program and the first and second remote control data, analyzing a color and illumination level of a lighting fixture, and an illumination level related to the Internet of Things, and outputting an integrated control signal; And outputting, by a pulse width modulation controller, the device control signal for controlling the illuminance of each of the plurality of lighting devices by receiving the integrated control signal and modulating the pulse width. It characterized in that it comprises a.

The step (d) of the integrated control method for DMX-512 lighting based on the Internet of Things of the present invention for achieving the other object is that a second wireless receiver in the plurality of lighting devices receives the device control signal through a wireless communication network. step; Driving the lamps individually and in groups by adaptively controlling turn-on and turn-off operations and illuminance of the lamp in real time according to pre-designed direction information and the sensing data in response to the received device control signal ; And transmitting, by a second wireless transmission unit, data on the operation of the driven lamp and the adjusted illuminance to a corresponding lighting integrated control unit among the plurality of integrated lighting control units. It characterized in that it comprises a.

Details of other embodiments are included in "Specific contents for carrying out the invention" and the attached "Drawings".

Advantages and/or features of the present invention, and a method of achieving them will become apparent with reference to various embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited only to the configuration of each embodiment disclosed below, but may be implemented in various different forms, and only each embodiment disclosed in the present specification makes the posting of the present invention complete. It should be understood that the present invention is provided to completely inform the scope of the present invention to those of ordinary skill in the art, and the present invention is only defined by the scope of each claim in the claims.

According to the present invention, the instability of controlling a plurality of lighting devices is overcome due to incompatibility of the conventional control method of mixing DMX-512 LED lighting control and IoT remote control including a sensor.

In addition, it is possible to smoothly respond to the operation according to the use of a plurality of lighting devices adaptively according to real-time fluctuations, thereby remarkably improving the situation coping ability and efficiency.

In addition, it is possible to prevent distortion of an output communication signal caused by various electrical noises accompanying the characteristics of the electrical circuit configuration of the lighting control communication.

1 is a block diagram schematically illustrating a DMX-512 lighting integrated control device based on the Internet of Things according to an embodiment of the present invention.
2 is a flowchart schematically illustrating an operation of a method for controlling integrated lighting of DMX-512 based on the Internet of Things according to an embodiment of the present invention.
3 is an internal block diagram of the lighting direction data generation unit 100 in the lighting control device shown in FIG. 1.
4 is an internal block diagram of the remote control device 140 in the lighting direction data generation unit 100 shown in FIG. 3.
FIG. 5 is a flowchart illustrating detailed operations of the lighting direction data generation unit 100 in step S100 of the DMX-512 lighting integrated control method illustrated in FIG. 2.
6 is an internal block diagram of the IoT sensor 200 in the lighting control device shown in FIG. 1.
7 is a flowchart illustrating detailed operations of the IoT sensor 200 in step S200 of the DMX-512 lighting integrated control method shown in FIG. 2.
FIG. 8 is an internal block diagram of a first integrated lighting controller 300-1 in the lighting control device illustrated in FIG. 1.
FIG. 9 is a flow chart for explaining a detailed operation of step S300 of the method for controlling the integrated lighting of the DMX-512 shown in FIG. 2.
10 is an internal block diagram of the first lighting device 400-1 in the lighting control device illustrated in FIG. 1.
FIG. 11 is a flowchart for explaining a detailed operation of step S400 in the method for controlling the integrated lighting of the DMX-512 shown in FIG. 2.

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

Before describing the present invention in detail, terms and words used in the present specification are not to be interpreted as being unconditionally limited to their usual or dictionary meanings, and in order for the inventors of the present invention to describe their invention in the best way The concept of various terms can be appropriately defined and used.

Furthermore, it should be understood that these terms or words should be interpreted as meanings and concepts consistent with the technical idea of the present invention.

That is, the terms used in the present specification are only used to describe a preferred embodiment of the present invention, and are not intended to specifically limit the content of the present invention.

It should be understood that these terms are terms defined in consideration of various possibilities of the present invention.

In addition, in the present specification, a singular expression may include a plurality of expressions unless clearly indicated in a different meaning in the context.

In addition, it should be noted that even if it is expressed in a similar plural form, it may include a singular meaning.

Throughout the present specification, when a component is described as "including" another component, it does not exclude any other component, but further includes any other component unless otherwise indicated. It could mean you can do it.

Furthermore, when a component is described as "existing inside or being connected and installed" of another component, the component may be directly connected to or installed in contact with the other component.

In addition, it may be installed spaced apart by a certain distance, and in the case of installation spaced apart from each other by a certain distance, a third component or means for fixing or connecting the component to other components may exist. .

Meanwhile, it should be understood that the description of the third component or means may be omitted.

On the other hand, when a component is described as being "directly connected" to another component or "directly connected", it should be understood that there is no third component or means.

Likewise, other expressions describing the relationship between each component, such as "between" and "directly between", or "neighbor to" and "directly neighbor to" have the same effect. Should be interpreted as.

In addition, in the present specification, terms such as “one side”, “the other side”, “one side”, “the other side”, “first”, and “second” refer to a component in which one component is different for one component. It is used to make it clearly distinct from the element.

However, it should be noted that the meaning of the corresponding component is not limitedly used by such terms.

In addition, in the present specification, terms related to positions such as "upper", "lower", "left", and "right", if used, should be understood as indicating a relative position in the drawing with respect to the corresponding component.

In addition, these position-related terms should not be understood as referring to absolute positions unless absolute positions are specified for their positions.

Moreover, in the specification of the present invention, terms such as "unit", "group", "module", "device", if used, mean a unit capable of processing one or more functions or operations.

It should be noted that this can be implemented in hardware or software, or a combination of hardware and software.

In the drawings attached to the present specification, the size, position, and coupling relationship of each component constituting the present invention are partially exaggerated, reduced, or omitted in order to sufficiently clearly convey the spirit of the present invention or for convenience of description. It may have been described, and therefore its proportion or scale may not be exact.

In addition, in the following description of the present invention, a detailed description of a configuration determined to unnecessarily obscure the subject matter of the present invention, for example, a known technology including the prior art may be omitted.

1 is a block diagram schematically showing an IoT-based DMX-512 lighting integrated control apparatus according to an embodiment of the present invention, and a lighting direction data generation unit 100, an Internet of Things detection unit 200, and a plurality of Power supply units 250-1 to 250-n, a plurality of integrated lighting controllers 300-1 to 300-n, and a plurality of lighting devices 400 are provided.

2 is a flowchart schematically illustrating an operation of a method for controlling integrated lighting of DMX-512 based on the Internet of Things according to an embodiment of the present invention.

The structure and function of each component of the IoT-based DMX-512 lighting integrated control apparatus according to the present invention will be schematically described as follows with reference to FIGS. 1 and 2.

The lighting directing data generation unit 100 designs a lighting directing program by applying a plurality of layer configurations, downloads a command list from the designed lighting directing programs, and primarily remotely directs the lighting of the plurality of lighting devices 400 for each layer. The first remote control data to be controlled is transmitted (S100).

The IoT sensing unit 200 detects a situation that changes in real time according to the use of the lighting device 400, generates a dimming control command in response to the detected sensing data, and directs the lighting of the plurality of lighting devices 400. Secondly, the second remote control data to be remotely controlled is transmitted (S200).

The plurality of integrated lighting controllers 300-1 to 300-n receive the lighting directing program and first remote control data stored from the lighting directing data generator 100, and control the second remote control from the IoT sensing unit 200 The data is received, and in response thereto, a device control signal for commanding driving of the plurality of lighting devices 400 is output (S300).

The plurality of lighting devices 400 are individually and group units adaptively in real time according to pre-designed direction information and real-time sensing data in response to device control signals output from the plurality of integrated lighting controllers 300-1 to 300-n. Drive (S400).

The plurality of power supply units 250-1 to 250-n supply power for lighting devices to each of the plurality of integrated lighting control units 300-1 to 300-n.

3 is an internal block diagram of the lighting directing data generation unit 100 in the lighting control device shown in FIG. 1, and includes a user terminal 120 and a remote control device 140, and the user terminal 120 is a storage unit. It has 125.

FIG. 4 is an internal block diagram of the remote control device 140 in the lighting direction data generation unit 100 shown in FIG. 3, a first wireless receiver 142, a lighting presentation application 144, and a first wireless transmission unit 146 ).

FIG. 5 is a flowchart illustrating detailed operations of the lighting direction data generation unit 100 in step S100 of the DMX-512 lighting integrated control method illustrated in FIG. 2.

The structure and function of each component of the lighting directing data generation unit 100 in the DMX-512 lighting integrated control device based on the Internet of Things according to the present invention will be schematically described as follows with reference to FIGS. 1 to 5.

The user terminal 120 is configured with a plurality of layers to design a lighting directing program, and the designed lighting directing program is stored in the storage unit 120 (S110).

The first wireless receiver 142 in the remote control device 140 downloads a list of commands from among the lighting directing programs designed in the user terminal 120 (S210).

The lighting directing application 144 displays the lighting directing program downloaded from the first wireless receiver 142 in a menu format on the screen (S220).

The first wireless transmission unit 146 in the remote control device 140 loads the presentation information (S230) manipulated in the lighting presentation application 144 on a signal of a selected frequency among a plurality of signals having different frequencies into data and transmits Do (S240).

6 is an internal block diagram of the IoT sensing unit 200 in the lighting control device shown in FIG. 1, and includes a sensor unit 220, a dimming control command generation unit 240, and a remote control data transmission unit 260 do.

7 is a flowchart illustrating detailed operations of the IoT sensor 200 in step S200 of the DMX-512 lighting integrated control method shown in FIG. 2.

The sensor unit 220 includes a temperature sensor, an illuminance sensor, a humidity sensor, an air pollutant sensor, an infrared sensor, a motion sensor, an acoustic sensor, a speed sensor, an acceleration sensor, a vibration sensor, and the like.

The sensor unit 220 detects a situation that changes in real time according to the usage of the plurality of lighting devices 400 and outputs the detection data.

For example, when a plurality of lighting devices 400 are used to direct lighting in an outdoor concert hall, the visibility of the performance stage can be detected in real time through humidity or illumination around the concert hall through a humidity sensor or an illuminance sensor, and security/security alarm In Yongin, it is possible to detect in real time whether an outsider in the security control area has intruded through an infrared sensor, a motion sensor, or an acoustic sensor.

In addition, when the plurality of lighting devices 400 are used for warning of air pollution in the metropolitan area, fine dust, carbon monoxide, nitrogen dioxide, ozone, sulfurous acid gas, etc. exposed to the atmosphere can be detected in real time through the air pollutant sensor. In case of fire alarm, the occurrence of fire can be detected in real time through temperature sensor.

In addition, when the plurality of lighting devices 400 are for traffic information and vehicle control, the speed sensor can detect the driving speed of the vehicle and the current status of road traffic congestion in real time, and in the case of an earthquake warning of a cultural heritage site, a vibration sensor or an acceleration sensor The earthquake can be detected in real time.

The dimming control command generation unit 240 receives sensing data from the sensor unit 220 and generates a dimming control command that adjusts the illuminance of the plurality of lighting devices 400.

The remote control data transmission unit 260 receives a dimming control command from the dimming control command generation unit 240, converts the lighting direction of the plurality of lighting devices 400 into second remote control data that is secondary remotely and transmits it. do.

FIG. 8 is an internal block diagram of the first integrated lighting controller 300-1 in the lighting control device shown in FIG. 1, wherein the signal isolating unit 310-1, the lighting control signal receiving unit 320-1, and a dimming control signal A receiver 330-1, an input signal control unit 340-1, and a pulse width modulation control unit 350-1 are provided.

FIG. 9 is a flow chart for explaining a detailed operation of step S300 of the method for controlling the integrated lighting of the DMX-512 shown in FIG. 2.

The structure and function of each component of the first lighting integrated control unit 300-1 in the IoT-based DMX-512 lighting integrated control device according to the present invention will be schematically described as follows with reference to FIGS. 1 to 9 .

The signal isolating unit 310-1 is a signal isolating device of an input terminal and is equipped with an isolation resistor having an isolation characteristic.

The lighting control signal receiving unit 320-1 receives the stored lighting directing program and first remote control data from the lighting directing data generating unit 100.

The dimming control signal receiving unit 330-1 receives second remote control data from the IoT sensing unit 200.

The input signal control unit 340-1 receives the stored lighting direction program and first remote control data from the lighting control signal receiving unit 320-1, and transmits second remote control data from the dimming control signal receiving unit 330-1. It receives and analyzes the color and illumination level of the lighting fixture and the illumination level related to the Internet of Things, and outputs an integrated control signal.

The pulse width modulation control unit 350-1 receives an integrated control signal from the input signal control unit 340-1 and controls the illuminance of each of the plurality of lighting devices 400 by performing pulse width modulation (PWM). Outputs a device control signal.

FIG. 10 is an internal block diagram of a first lighting device 400-1 in the lighting control device shown in FIG. 1, a second wireless receiver 420-1, a driving part 440-1, and a lamp 445-1 And a second wireless transmission unit 460-1.

FIG. 11 is a flowchart for explaining a detailed operation of step S400 in the method for controlling the integrated lighting of the DMX-512 shown in FIG. 2.

The structure and function of each component of the first lighting device 400-1 in the DMX-512 lighting integrated control device based on the Internet of Things according to the present invention will be schematically described as follows with reference to FIGS. 1 to 11.

The second wireless receiver 420-1 receives the device control signal transmitted from the first integrated lighting control unit 300-1 (S410).

The driving unit 440-1 adaptively turns on and turns on the lamp 445-1 in real time according to pre-designed direction information and real-time sensing data in response to the device control signal received from the second wireless receiving unit 420-1. The off operation is driven, and the illuminance is adjusted to drive (S420).

The second wireless transmission unit 460-1 transmits data on the turn-on and turn-off operation of the lamp 445-1 driven through the driving unit 440-1 and the adjusted illuminance to the corresponding lighting integrated control unit 300-1. It is transmitted to (S440).

The organic operation of the DMX-512 lighting integrated control device based on the Internet of Things according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 11.

PWM dimming of DMX-512 LED lighting control in order to respond more flexibly and smoothly to real-time fluctuations in real-time fluctuations in the control method of a remote control system such as the Internet of Things (IoT), which is now common. In order to overcome the problem that it is impossible to control partial or entire lighting equipment due to the incompatibility of a method of mixing the Internet of Things (IoT) remote control including control and sensor, the present invention provides a DMX-512 LED lighting control and various sensors. It integrates and controls a remote control such as the Internet of Things (IoT) including.

Through this, it is possible to smoothly respond in real time to the secondary remote control signal in the control method of the IoT remote control system including the sensor while maintaining the pulse width modulation control signal of the lighting control configured in advance.

For example, in the case of driving a plurality of lighting fixtures at low illuminance in response to a pulse width modulation control signal of lighting control that has been primarily pre-directed in normal times, and motion is detected by a temperature sensor or a motion sensor, 2 Secondly, by increasing the illuminance in response to the dimming control signal, a plurality of lighting fixtures are driven with high illuminance.

Here, the primary lighting control signal may be a control signal of a conventional general DMX 512 device, or may be a lighting control signal output from the user terminal 120 or the remote control device 140 which will be described later in detail below.

As such a primary lighting control signal and a secondary lighting control signal, various communication interfaces such as TCP/IP, ZigBee, BlueTooth, and Wi-Fi can be used.

As described above, in the configuration using the integrated control signal, convenience is remarkably improved because the IoT control signal including the sensor and DMX 512 data can be connected through one communication interface.

Meanwhile, at least two IoT repeaters (not shown) may be provided so that signals between the IoT sensing unit 200 and the plurality of integrated lighting controllers 300-1 to 300-n can be transmitted normally even at a distance. .

This is because the IoT sensor 200 and the IoT repeater are basically operated in a short-range wireless communication method such as Bluetooth, and thus, signals are weak or cannot be received over a certain distance.

The plurality of integrated lighting controllers 300-1 to 300-n combine the primary and second remote control data wirelessly input from the lighting directing data generation unit 100 and the IoT sensing unit 200 to complete DMX 512 Outputs a device control signal reproduced as a signal.

This operation compensates for attenuation of radio signals according to distance and blocking of radio waves by obstacles, like a repeater, so that remote and shaded lighting devices can be controlled with high reliability.

In FIG. 3, the remote control device 140 in the lighting direction data generation unit 100 is a mobile device and includes a smart phone, a PMP, a tablet PC, and a smart pad in which the lighting presentation application 144 can be installed.

A lighting directing application 144 may be installed in the remote control device 140, wherein a plurality of integrated lighting controllers 300-1 to 300-n and the remote control device 140 are connected through a wireless communication network, The lighting device control state of the integrated lighting controllers 300-1 to 300-n can be checked through the user's remote control device 140 located at a remote location.

In addition, as all results controlled by the plurality of integrated lighting controllers 300-1 to 300-n are directly transmitted to the user's remote control device 140, the process of passing data is simplified, thereby reducing loss due to data passage. It is possible to reduce and minimize the configuration due to operational errors.

In FIG. 8, the lighting control signal receiving unit 320-1 independently receives the stored lighting directing program and first remote control data from the lighting directing data generating unit 100, and the dimming control signal receiving unit 330-1 is The second remote control data is independently authorized from the Internet sensing unit 200.

The input signal control unit 340-1 receives primary and second remote control data independently applied from the lighting control signal receiving unit 320-1 and the dimming control signal receiving unit 330-1, respectively, and It analyzes the illuminance level and the illuminance level related to the Internet of Things, and outputs an integrated control signal.

The pulse width modulation control unit 350-1 receives an integrated control signal from the input signal control unit 340-1 and performs a pulse width modulation operation. The principle is as follows.

In general, since the luminance of the LED does not have a linear proportional relationship with the driving current, the color of the LED may change according to the driving current.

Therefore, when using LEDs as a back light or lighting system, difficulties are often encountered when changing the lighting by directly adjusting the drive current.

In order to avoid the difficulty of adjusting the lighting through the amplitude change of the driving current, a constant amplitude driving current is used as the lighting adjustment scheme achieved through pulse width modulation of the driving current.

Through this, the luminous efficiency of the LED can be constant within a wide range.

However, in the LED, as a ripple waveform synchronized with the lighting control pulse signal is generated from the power source, a'flickering phenomenon' that is recognized by the naked eye may occur by affecting the video display signal.

In order to prevent this'flickering phenomenon', the frequency of the illumination control pulse signal should be low, typically at least 200 Hz.

That is, the lighting control pulse signal must operate at a sufficiently high frequency so that a visible image remains to the naked eye, but a normal lighting change can be recognized by the naked eye without a flicker effect.

The pulse width modulation control unit 350-1 performing the pulse width modulation operation according to the above principle detects real-time fluctuations in the lighting presentation program pre-designed in the lighting presentation data generation unit 100 and the Internet of Things detection unit 200 A device control signal for controlling illuminance according to the purpose of the plurality of lighting devices 400 is output by reflecting one data in an integrated manner.

For example, when a plurality of lighting devices 400 are used for directing lighting in an outdoor concert hall, a lighting program was designed in anticipation of a normal day when the weather was clear, but the illumination was lowered due to weather changes on the day of the performance or the performance stage due to fog, etc. It is assumed that the visibility of is significantly reduced.

At this time, the illuminance sensor or humidity sensor of the sensor unit 220 in the IoT sensing unit 200 detects the changed real-time situation of the outdoor concert hall to generate a dimming control command to increase the illuminance of the plurality of lighting devices 400, According to a pre-designed lighting direction program, the illuminance and/or turn-on status of the plurality of lighting devices 400, which were originally scheduled to be remotely controlled, are changed in real time to output second remote control data that is secondary remotely controlled.

The plurality of integrated lighting controllers 300-1 to 300-n receive a pre-designed lighting directing program and first remote control data from the lighting directing data generating unit 100, and are changed in real time from the IoT sensing unit 200. 2 It receives remote control data, analyzes the color and illuminance level of the lighting fixture and the illuminance level related to IoT, and outputs an integrated control signal.

In addition, a pulse width modulation operation is performed in response to the integrated control signal to output a device control signal for increasing the illuminance of each of the plurality of lighting devices 400 in real time.

Accordingly, the plurality of lighting devices 400 increase the illuminance in response to the changed direction information according to the updated device control signal from the plurality of integrated lighting controllers 300-1 to 300-n to adaptively individually and in groups in real time. It is driven by unit.

On the other hand, when the lighting directing producer designs various lighting directing programs to which a plurality of layers is applied on the user terminal 120, the user terminal 120 stores the designed lighting directing program in a predetermined storage unit 125. .

Here, the configuration of a plurality of layers refers to a scene composed of a plurality of layers, which was designed to be controlled to be interlocked through a plurality of integrated lighting controllers 300-1 to 300-n in the prior art. Thus, it means a configuration for synchronizing each floor through one integrated lighting control unit 300-n.

For example, the present invention is composed of 10 layers, each layer may be arranged by dividing 512 luminaires by a predetermined number (10x10 = 100 in the case of the first layer (layer 001)).

That is, each of the 512 luminaires has a unique address controlled by the DMX 512 protocol, and are connected to each other through wiring to a local area network defining signal requirements.

In addition, data for a device callable by one or more addresses is defined, for example, in Ethernet packets.

Every Ethernet packet contains a payload containing a destination address indicating where the packet should go, a header describing the source address indicating where the packet came from, and several device control signals for lighting control.

Accordingly, since 512 luminaires arranged in a plurality of layers each have a specific color and illuminance at an RGB level, a lighting production producer can design various lighting production programs different for each layer with data.

The remote control device 140 mounts the lighting directing program designed on the user terminal 120 in the form of a predetermined application 144, and is a command among the lighting directing programs stored on the user terminal 120 through the first wireless receiver 142. Only the command name and contents of the list, that is, the lighting production scenario, are downloaded.

This is because the data capacity is too large for the user terminal 120 to download all of the lighting directing programs.

The plurality of integrated lighting controllers 300-1 to 300-n receive data transmitted from the remote control device 140 and a lighting directing program transmitted from the user terminal 120 through the second wireless receiver 320 and In response, a device control signal for commanding driving of the plurality of lighting devices 400 individually and/or in groups according to the direction information manipulated by the user is output through the second wireless transmission unit 360.

In this case, the plurality of integrated lighting control units 300-1 to 300-n may be provided in a stand-alone panel in case of an individual control method, or may be provided in a server of the central control room in case of a central control method. have.

The second wireless receiver 420 in the plurality of lighting devices 400 receives device control signals from the plurality of integrated lighting controllers 300-1 to 300-n, and the corresponding lighting device commanded to be driven is a built-in driving unit 440 ) In response to this, drives the lamps 445 individually and/or in groups according to the user's intended direction information.

In addition, the lighting control device of the present invention is equipped with a signal isolating device in the input port or the output port of the lighting control device in preparation for distortion of communication signals due to noise of various electrical signals inevitably involved in the electrical circuit configuration of lighting control communication. do.

For example, the output terminal of the first wireless transmission unit 146 in the remote control device 140, the input terminal of each of the plurality of integrated lighting controllers 300-1 to 300-n, and the second wireless device in the plurality of lighting devices 400 Isolation resistors 148, 310-n, 462, etc. having isolation characteristics as a signal isolation device are mounted at the output end of the transmitter 460.

As described above, the present invention is an IoT-based DMX-512 lighting integrated control device capable of integrating and controlling the primary remote control of DMX-512 LED lighting configured in advance and secondary remote control of the Internet of Things including various sensors. And a method.

Through this, the instability of controlling a plurality of lighting devices is overcome due to incompatibility of the conventional control method of mixing DMX-512 LED lighting control and IoT remote control including a sensor.

In addition, it is possible to smoothly respond to the operation according to the use of a plurality of lighting devices adaptively according to real-time fluctuations, thereby remarkably improving the situation coping ability and efficiency.

In addition, it is possible to prevent distortion of an output communication signal caused by various electrical noises accompanying the characteristics of the electrical circuit configuration of the lighting control communication.

In the above, several preferred embodiments of the present invention have been described with some examples, but the description of the various various embodiments described in the "Specific Contents for Carrying out the Invention" section is merely exemplary, and the present invention is Those of ordinary skill in the art to which it belongs will be well understood from the above description that the present invention can be variously modified and implemented or equivalent to the present invention.

In addition, since the present invention can be implemented in a variety of other forms, the present invention is not limited by the above description, and the above description is intended to complete the disclosure of the present invention, and is generally used in the technical field to which the present invention pertains. It should be understood that it is provided only to completely inform the scope of the present invention to those skilled in the art, and that the present invention is only defined by each claim of the claims.

100: lighting directing data generation unit
200: Internet of Things detection unit
250-1 to 250-n: a plurality of power supplies
300-1 to 300-n: a plurality of lighting integrated control unit
400: multiple lighting devices

Claims (14)

A lighting directing data generating unit for designing a lighting directing program, downloading a command list from the designed lighting directing programs, and transmitting first remote control data for primarily remotely controlling lighting directing of a plurality of lighting devices;
An Internet of Things detection unit generating a dimming control command in response to sensing data in which a real-time fluctuation situation is sensed, and transmitting second remote control data for remotely controlling the lighting presentation; And
A plurality of lighting integrated controllers for outputting device control signals that command driving of the plurality of lighting devices in response to the lighting directing program and the first and second remote control data, and
The plurality of lighting devices are adaptively driven individually and in groups according to the real-time fluctuations in response to the device control signal,
Each of the plurality of integrated lighting control units
A lighting control signal receiving unit receiving the lighting directing program and the first remote control data;
A dimming control signal receiving unit receiving the second remote control data;
An input signal controller configured to receive the lighting presentation program and the first and second remote control data, analyze a color and illuminance level of a lighting fixture, and an illuminance level related to the Internet of Things, and output an integrated control signal; And
And a pulse width modulation controller configured to output the device control signal for controlling the illuminance of each of the plurality of lighting devices by receiving the integrated control signal and modulating the pulse width.
Internet of Things based DMX-512 lighting integrated control device.
The method of claim 1,
The lighting direction data generation unit
A user terminal configured to apply a plurality of layers to design the lighting directing program, and store the designed lighting directing program in a storage unit; And
A remote control device for downloading the command list and transmitting the first remote control data for remotely controlling the lighting direction for each layer;
Characterized in that it comprises a,
Internet of Things based DMX-512 lighting integrated control device.
The method of claim 2,
The remote control device
A first wireless receiver for downloading the command list;
A lighting directing application that displays the downloaded command list in a menu format on a screen; And
A first wireless transmitter configured to load and transmit the presentation information manipulated in the lighting presentation application on a signal of a selected frequency among a plurality of signals having different frequencies into the first remote control data;
Characterized in that it comprises a,
Internet of Things based DMX-512 lighting integrated control device.
The method of claim 1,
The IoT detection unit
A sensor unit configured to output the detection data by detecting a situation that changes in real time according to the use of the plurality of lighting devices;
A dimming control command generation unit receiving the sensing data and generating a dimming control command for adjusting illuminance of the plurality of lighting devices; And
A remote control data transmission unit that receives the dimming control command, converts it into the second remote control data, and transmits it;
Characterized in that it comprises a,
Internet of Things based DMX-512 lighting integrated control device.
delete The method of claim 3,
Each of the plurality of lighting devices
A second wireless receiver configured to receive the device control signal through a wireless communication network;
A driving unit for driving the lamps individually and in groups by adaptively controlling turn-on and turn-off operations and illuminance of the lamp in real time according to pre-designed direction information and the sensing data in response to the received device control signal; And
A second wireless transmission unit for transmitting data on the operation of the driven lamp and the adjusted illuminance to a corresponding lighting integrated control unit among the plurality of integrated lighting control units;
Characterized in that it comprises a,
Internet of Things based DMX-512 lighting integrated control device.
The method of claim 6,
The first to second wireless transmitters
In order to prevent distortion of the transmission signal due to noise, an isolation resistor is mounted as a signal isolating device at the output terminal,
Internet of Things based DMX-512 lighting integrated control device.
The method of claim 1,
Each of the plurality of integrated lighting control units
Characterized in that the power supply for supplying power for the lighting device is connected,
Internet of Things based DMX-512 lighting integrated control device.
(a) A lighting directing program is designed on the lighting directing data generating unit, downloading a command list from the designed lighting directing programs, and transmitting first remote control data for primarily remotely controlling the lighting directing of a plurality of lighting devices. ;
(b) generating a dimming control command in response to sensing data in which a real-time fluctuation situation is sensed by the IoT sensor, and transmitting second remote control data for secondary remote control of the lighting presentation;
(c) outputting, by a plurality of integrated lighting controllers, a device control signal commanding driving of the plurality of lighting devices in response to the lighting directing program and the first and second remote control data; And
(d) adaptively driving the plurality of lighting devices in individual and group units according to the real-time fluctuations in response to the device control signal; and
Step (c)
Receiving, by a lighting control signal receiver in the plurality of integrated lighting controllers, the lighting directing program and the first remote control data;
Receiving, by a dimming control signal receiver, the second remote control data;
Receiving, by an input signal controller, the lighting presentation program and the first and second remote control data, analyzing a color and illumination level of a lighting fixture, and an illumination level related to the Internet of Things, and outputting an integrated control signal; And
And outputting the device control signal for controlling the illuminance of each of the plurality of lighting devices by receiving the integrated control signal, by a pulse width modulation controller, by modulating the pulse width.
Internet of Things-based DMX-512 lighting integrated control method.
The method of claim 9,
Step (a)
(a-1) applying a plurality of layer configurations on the user terminal to design the lighting presentation program, and storing the designed lighting presentation program in a storage unit; And
(a-2) transmitting, by a remote control device, the first remote control data for remotely controlling the lighting direction for each layer by downloading the command list;
Characterized in that it comprises a,
Internet of Things-based DMX-512 lighting integrated control method.
The method of claim 10,
Step (a-2)
Downloading the command list by a first wireless receiver in the remote control device;
Displaying, by the lighting directing application, the downloaded command list in a menu format on a screen; And
Loading, by a first wireless transmitter, the direction information manipulated in the lighting presentation application on a signal of a selected frequency among a plurality of signals having different frequencies into the first remote control data;
Characterized in that it comprises a,
Internet of Things-based DMX-512 lighting integrated control method.
The method of claim 9,
Step (b)
Detecting a situation that changes in real time according to the usage of the plurality of lighting devices by a sensor unit in the IoT sensing unit and outputting the sensing data;
Generating a dimming control command for adjusting the illuminance of the plurality of lighting devices by receiving the sensing data by a dimming control command generator; And
Receiving, by a remote control data transmission unit, the dimming control command, converting it into the second remote control data, and transmitting it;
Characterized in that it comprises a,
Internet of Things-based DMX-512 lighting integrated control method.
delete The method of claim 9,
Step (d)
Receiving the device control signal through a wireless communication network by a second wireless receiver in the plurality of lighting devices;
Driving the lamps individually and in groups by adaptively controlling turn-on and turn-off operations and illuminance of the lamp in real time according to pre-designed direction information and the sensing data in response to the received device control signal ; And
Transmitting, by a second wireless transmission unit, data on the operation of the driven lamp and the adjusted illuminance to a corresponding lighting integrated controller among the plurality of integrated lighting controllers;
Characterized in that it comprises a,
Internet of Things-based DMX-512 lighting integrated control method.

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