KR101253148B1 - Digital device control system capable of infrared signal addition using smart phone and home server - Google Patents

Abstract

The present invention relates to a digital device control system, and more particularly, to an IR repeater equipped with infrared generating means by receiving a driving signal of a digital device transmitted from an indoor or outdoor through a smart phone in a relay home server installed in each home. When transmitting, by generating and transmitting an infrared signal from the IR repeater receiving the drive signal of the digital device, the user can easily control the digital device in the home as well as indoors, as well as remote control and When the infrared signal transmitted from the same remote control device is received and captured by the IR repeater and transmitted to the smartphone, the smartphone analyzes the pattern of the captured infrared signal and compresses the data contained in the infrared signal and returns it to the IR repeater. By transmitting and storing it, Relates to an external signal to the smart phone and the IR repeater readily capable of using a smart phone makes it possible to learn the infrared signal learning digital device control system, or the like.

Description

Digital device control system capable of learning infrared signal using smartphone and relay home server {DIGITAL DEVICE CONTROL SYSTEM CAPABLE OF INFRARED SIGNAL ADDITION USING SMART PHONE AND HOME SERVER}

The present invention relates to a digital device control system, and more particularly, to an IR repeater equipped with infrared generating means by receiving a driving signal of a digital device transmitted from an indoor or outdoor through a smart phone in a relay home server installed in each home. When transmitting, by generating and transmitting an infrared signal from the IR repeater receiving the drive signal of the digital device, the user can easily control the digital device in the home as well as indoors, as well as remote control and When the infrared signal transmitted from the same remote control device is received and captured by the IR repeater and transmitted to the smartphone, the smartphone analyzes the pattern of the captured infrared signal and compresses the data contained in the infrared signal and returns it to the IR repeater. By transmitting and storing it, Relates to an external signal to the smart phone and the IR repeater readily capable of using a smart phone makes it possible to learn the infrared signal learning digital device control system, or the like.

2. Description of the Related Art Recently, digital apparatuses, particularly home digital apparatuses, are generally introduced with a remote controller, which is a remote control device for controlling the operation thereof in order to minimize the movement of a user for the convenience of use .

In this way, digital apparatuses which can be operated by a remote controller and improve the usability of use have been limited to televisions and audios which need to adjust the channel and sound volume from time to time. However, recently, air- Player, lighting, and so on.

However, in order to operate a digital device by the remote control in this way, the remote control should always be located nearby, but unlike the place where the remote control is always placed in front of the television, the remote control is always placed on the sofa in front of the television. In the case of a remote controller of a digital device, there is a problem that frequently occurs when the remote controller is searched for its operation.

In addition, as the type of digital devices operated by the remote control increases and the functions that can be operated by the remote control increase, operation keys and interfaces of each remote control become different and complicated, so that all functions provided by the remote There was a problem that can not fully utilize them.

In addition, the remote controller generally transmits an infrared signal formed by a binary code including a custom code for distinguishing a manufacturer and a digital device to be controlled and a data code as a control command so that only a specific digital device can recognize and control it. to be.

Accordingly, the time of a binary signal such as changing the length of a high pulse or changing the length of a low pulse so that various digital devices can be identified by a simple binary code and each control command can be generated. It was common for manufacturers to generate and transmit infrared signals in their own way, with different lengths and lengths.

In addition, even if a product produced by the same manufacturer is assigned a custom code in a different format for each digital device in order to prevent malfunction due to confusion of control commands, many manufacturers and various digital devices produced by each manufacturer Since they all have different custom codes, the format of the remote control used in the remote control varies considerably.

Therefore, in recent years, the custom codes of all the domestic and foreign manufacturers and all the digital devices sold by each manufacturer are stored in advance, and after extracting the custom codes matching the custom codes included in the infrared signals actually transmitted from the remote controller, A universal remote control has been proposed to store and use custom code.

However, such a conventional universal remote control has a problem that it is virtually impossible to store all the custom codes for the newly released products in advance, and there is a problem that it is quite inconvenient to search for and extract the matching custom code.

In addition, the conventional universal remote control still has the limitation of the remote control itself to transmit and operate the infrared signal from the front of the digital device to be operated, there was still an inconvenience to be careful in storage.

Recently, there is an increasing need to control on / off when a user is not only indoors but also outdoors in a digital device such as a plurality of home appliances in the home, and for this purpose, home automation by ubiquitous Attempts to build at home are increasing. However, such ubiquitous home automation is not only expensive for system construction but also limited to expensive homes newly constructed due to the hassle of construction work. There was a problem that could not be activated.

In addition, in the past, the mobile phone has always been located in close proximity to the form has been proposed in the form of a remote control in the mobile phone, but there are not many digital devices that can operate as a remote control, the interface of the remote control displayed on the mobile phone is simple by the keypad In many cases, there is a problem that there is not much utilization due to many operations, and a problem of securing a lot of space for installation of the infrared generating unit in the mobile phone. In recent years, mobile phones such as smartphones are released without the infrared generating unit. Is common.

Accordingly, in recent years, a combination device that allows a separate infrared generator to be used in combination with a smartphone has been proposed so that a smartphone released without the infrared generator can be used as a remote controller, but such an infrared generator is always used. There was a problem in that it was cumbersome to carry and use.

The problem to be solved by the present invention, when receiving a drive signal of a digital device transmitted indoors or outdoors via a smart phone in the relay home server installed in each home and transmits to the IR repeater equipped with an infrared generating means, By generating and transmitting an infrared signal from the IR repeater that receives the driving signal, the user can easily control digital devices in the home not only when indoors but also outdoors, and transmitted from a remote control device such as a remote controller. When the infrared signal is received from the IR repeater, captured and transmitted to the smartphone, the smartphone analyzes the pattern of the captured infrared signal, compresses the data contained in the infrared signal, sends it back to the IR repeater, and saves it. Infrared signals unique to digital devices such as smartphones and IR repeaters May be able to easily learn a smart phone using the infrared signal digital device control system, learning is possible to to provide.

Digital device control system capable of learning infrared signals using a smart phone for achieving the above object, the drive signal generation unit for generating a drive signal for controlling the digital device by the operation of a button displayed on the display means is activated digital device control application And a driving signal communication unit for transmitting a driving signal of the digital device generated by the driving signal generation unit through a wireless communication network. A relay home server for receiving a driving signal transmitted from an external smartphone and transmitting the IR signal to an IR repeater installed indoors; A drive signal receiver for receiving a drive signal transmitted from the smartphone or relay home server, an infrared signal generator for generating an infrared signal corresponding to a custom code and a control command of a digital device constituting the received drive signal, and the infrared ray And an IR repeater having an infrared signal transmitting unit for transmitting a signal toward a digital device, and a wireless communication unit forming a gateway for receiving the driving signal.

The relay home server includes a smart phone communication unit consisting of a Wi-Fi module for receiving a drive signal transmitted from an external smart phone, and a repeater communication unit for transmitting a drive signal received from the smart phone to an IR repeater located indoors It is preferred to be configured.

In this case, when the IR repeater is provided with a Bluetooth module, the repeater communication unit is also configured as a Bluetooth module. When the IR repeater is equipped with a Wi-Fi module, the repeater communication unit is also configured as a Wi-Fi module capable of Wi-Fi communication.

In addition, the digital device control system capable of learning the infrared signal using the smart phone according to the present invention, the smart phone authentication unit for authenticating the access authority to the format database by authenticating users connected on the wireless communication network, and provided from domestic and overseas manufacturers Format database for storing remote control formats of digital devices or interfaces that users have learned from infrared signals and created and uploaded user interfaces, and formats for transmitting user-selected remote control formats and user interfaces to an authorized user's smartphone It is preferably configured to further include a format server including a portion.

In addition, the smart phone, the infrared signal learning unit for receiving and storing the infrared signal of the new digital device transmitted from the IR repeater; And a UI setting unit configured to form an interface of a smartphone user for operating a function of the newly learned infrared signal, and to match and store a function of a control command to each button constituting the user interface;

The IR repeater, learning signal receiving unit for receiving an infrared signal transmitted from a remote control device of a new digital device; And a microcomputer for capturing and transmitting the infrared signal received from the learning signal receiver to a smart phone, and receiving and storing the infrared code transmitted from the smart phone.

In this case, the infrared signal learning unit preferably comprises a pattern analysis unit for receiving the infrared signal of the new digital device transmitted after capturing by the IR repeater to analyze, compress and store the pattern of the infrared signal.

In addition, the smart phone uploads the infrared signal pattern of the digital device that has learned through the infrared signal learning unit and analyzes the pattern to the format server through a wireless communication network, and the other user has already uploaded the remote control format or the manufacturer of the digital device. It is preferable to further include a format down unit connected to the format server on the wireless communication network so that the uploaded remote control format can be downloaded from the format server.

In addition, the relay home server may be configured as a personal computer equipped with a communication means for receiving a drive signal transmitted through a 3G network or Wi-Fi using a base station from an external smartphone located indoors. In this case, the relay home server matches the dynamic IP with the host domain to automatically update the DNS database whenever a new IP address is given by the Internet service provider to implement a DDNS (Dynamic Domain Name System) service. It is preferably configured to include a DDNS matching unit.

In addition, the IR repeater further comprises a multi-control processing unit for controlling the plurality of digital devices by sequentially generating and transmitting the infrared signal according to the custom code and data code included in each drive signal transmitted from a plurality of smartphones It is preferable to be configured.

The present invention enables the user to easily control the digital devices in the home as well as indoors as well as indoors, and analyzes the patterns of the infrared signals made of a new remote control format for remote operation of the new digital devices. By storing them in phones and IR repeaters, it is easy to learn and use the infrared signals unique to new digital devices.

In addition, the present invention is to install a Bluetooth module or a Wi-Fi module in the IP repeater installed with an infrared light emitting diode in a radial manner, and the drive signal transmitted by using a 3G network or Wi-Fi communication directly transmitted from a smart phone or an outdoor smart phone It is configured to control digital devices by receiving them from a relay home server made up of a personal computer located in a home and transmitting them to an IR repeater through a local network such as Bluetooth communication or Wi-Fi communication forming a local area network in the home. As a result, stable home automation can be realized.

1 is a block diagram of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.
Figure 2 is a schematic block diagram showing that the infrared learning is made according to the present invention.
3 is a schematic structural diagram illustrating transmitting a user interface (UI) between smartphones in accordance with the present invention.
Figure 4 is a block diagram showing an IR relay radially installed IR LED in accordance with the present invention.
5 is a block diagram showing multi-control of a plurality of digital devices in the IR repeater in accordance with the present invention.
6 is a schematic structural diagram illustrating downloading and searching for a remote control format from a format server according to the present invention.
7 is a system configuration diagram showing a first embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.
8 is a system configuration diagram showing a second embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.
9 is a system configuration diagram showing a third embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.
10 is a system configuration diagram showing a fourth embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.
11 is a system configuration diagram showing a fifth embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

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

1 is a block diagram of a digital device control system capable of learning an infrared signal using a smart phone according to the present invention, FIG. 2 is a schematic block diagram showing that infrared learning is performed according to the present invention, and FIG. In accordance with the present invention is a schematic block diagram showing the transmission of a user interface (UI) between the smartphone, Figure 4 is a block diagram showing an IR relay installed radially in accordance with the present invention, Figure 5 is an IR repeater in accordance with the present invention FIG. 6 is a schematic diagram illustrating multi-control of a plurality of digital devices, and FIG. 6 is a schematic diagram illustrating searching for and downloading a remote controller format from a format server according to the present invention.

Referring to FIG. 1, a digital device control system capable of learning an infrared signal using a smart phone according to the present invention generates a driving signal for controlling a digital device by operating a button displayed on a display means by activating a digital device control application. The smart phone 100 to transmit and receive the drive signal transmitted from the external smartphone to the relay home server 200 for transmitting to the IR repeater installed in the room, and receives the drive signal transmitted from the relay home server It includes an IR repeater 300 for generating and transmitting an infrared signal corresponding to the control command of the drive signal.

At this time, the relay home server 200 has a smart phone communication unit 210 consisting of a Wi-Fi module for receiving a drive signal transmitted from an external smart phone, and the IR located in the indoor drive signal received from the smart phone It is configured to include a repeater communication unit 220 for transmitting to the repeater.

Accordingly, the repeater communication unit 220 is composed of a communication means capable of transmitting and receiving data according to the wireless communication unit 340 provided in the IR repeater, the repeater communication unit when the Bluetooth module 342 is provided in the IR repeater Bluetooth module 222, if the IR repeater is provided with a Wi-Fi module 344, the repeater communication unit is also configured with a Wi-Fi module 224, such as a wireless LAN capable of Wi-Fi communication.

In addition, a digital device control system capable of learning infrared signals using a smart phone according to the present invention is a format for providing a remote control format for authenticating a smart phone user connected on a wireless communication network and controlling a digital device to be operated by a smart phone. It is preferable that the server 400 further comprises.

The smart phone 100 generates a drive signal for controlling a digital device and transmits a drive signal generator 110 and a drive signal of the digital device generated by the drive signal generator to the relay home server and the IR repeater. The drive signal communication unit 120 converts and converts the data into a form that can be processed by the provided communication module, an infrared signal learning unit 130 for receiving and storing infrared signals of a new digital device transmitted from the IR repeater, and newly It comprises a UI setting unit 140 for generating an interface of the smart phone user for adjusting the function of the learned infrared signal.

In this case, the digital device control application is preferably configured to be downloaded and installed in the smart phone in a software form on the wireless communication network to improve the user's ease of use.

The driving signal generation unit 110 selects the digital device 500 to be operated, expresses and activates an interface for inputting a control command of the selected digital device on the display means of the smartphone 100, and then activates the interface. It is configured to generate a control signal matched to the input signal of the user for operating the interface displayed on the display means and to transmit to the relay home server 200 or the IR repeater 300.

Accordingly, the driving signal generator 110 displays the name, channel and volume control key, or number input key of the selected digital device on the display means, and manipulates and inputs a plurality of keys displayed on the screen. By generating a drive signal for performing a function matched to the operation signal is transmitted through a wireless communication network.

In this case, the driving signal generation unit 110 is configured to generate a driving signal by combining the custom code and the data code of the digital device selected by the input signal by operating the interface displayed on the smartphone. In this case, the driving signal generation unit 110 reads the remote control format of the corresponding digital device stored in the remote control format storage unit 170 and drives the drive signal based on the read custom code and data code. Since it is generated, it is also possible to generate an infrared signal having a remote control format suitable for the control of the digital device in the IR repeater 300 receiving such a drive signal.

The driving signal communication unit 120 transmits the driving signal of the digital device generated by the smartphone to the relay home server 200 or to the IR repeater 300, the smartphone 100 to enable wireless data communication Consists of a Bluetooth module or a WiFi module provided in the.

In this case, when the smart phone user is indoors, direct transmission / reception of the driving signal with the IR repeater 300 may be performed through the Bluetooth module. When the smart phone user is outdoors, the relay home server 200 may be transmitted through the Wi-Fi module. After transmitting the drive signal, the relay home server 200 transmits the drive signal to the IR repeater 300 in the room, the digital device 500 not only when the user is indoors but also when outdoors ), So that home automation can be easily implemented at low cost.

In addition, the smart phone 100 includes a plurality of codes for controlling the digital device, including the custom code and data code of the digital devices to control to generate a custom code and data code suitable for the digital device It is preferable that the remote control format storage unit 170 that stores the made remote control format is further configured. The remote control format storage unit 170 is not only the custom code and data codes of digital devices manufactured by domestic and foreign home appliances that are automatically stored at the same time as the application installation, the custom code of the new digital device obtained through the infrared signal learning unit and The data codes consist of the stored memory.

The infrared signal learning unit 130 receives an infrared signal of a new digital device that is captured by the IR repeater, and then analyzes the pattern of the infrared signal, compresses and stores the pattern of the infrared signal, and in the IR repeater. And an infrared signal storage unit 134 for storing the captured infrared signal of the new digital device to be transmitted together with the control command of the corresponding signal.

As described above, in order to learn the infrared signal composed of the custom code and data code of the new digital device to the smart phone, the remote control device 510 such as a remote controller for operating the new digital device as shown in FIG. When the infrared signal is received by the IR repeater 300 and captured as it is, and then transmitted through the Bluetooth module 342 or the Wi-Fi module 344, which is a wireless communication unit 340 capable of data communication with the smartphone, the smartphone ( In step 100, the learning mode of the digital device control application is activated and received through the infrared signal learning unit 130.

At this time, the pattern analysis unit 132 analyzes patterns such as whether the low pulse and high pulse of the binary code forming the infrared signal of the digital device that is captured by the IR repeater, and changes the length of the low pulse and the high pulse, etc. After analyzing the lead code, the custom code, the data code and the inverted data code included in the infrared signal, it is configured to minimize (compress) the analyzed infrared signal and store it in the remote control format storage unit 170 including a memory. do.

In addition, the pattern analysis unit 132 stores the analyzed and compressed infrared signal in the memory provided in the smart phone to form a remote control format storage unit 170, and the data communication network with the IR repeater 300 Is provided through the IR repeater and configured to store in the repeater remote control format storage unit 380 made of a storage device such as EEPROM.

In addition, after performing a pattern analysis of the infrared signal for a new digital device may be configured to store it in a separate format server 400 through a wireless communication network. As such, by storing the infrared signal of the new digital device on which the pattern analysis is performed, in the separate format server 400 separated from the IR repeater 300 or the smart phone, other users can easily download and use it on the wireless communication network. do.

The infrared signal storage unit 134 receives a lead code, a custom code, a data code, an inverted data code, and the like that form a captured infrared signal of a new digital device transmitted from the IR repeater 300 as it is. It is configured to match and store the received infrared signal with a control command to be implemented by the corresponding infrared signal. In this case, when the control command is matched and stored as it is, the integrated infrared signal is read out and transmitted to the IR repeater as it is generated in the future, and the IR repeater generates and sends an infrared signal for the control command. The operation of the digital device is made.

The UI setting unit 140 forms an interface required for the operation of each digital device 500 according to the type of digital device that can be controlled using a smartphone, and each function key, numeric key or letter key constituting the interface. It is configured to match and store the function or number or letter.

In this case, the UI setting unit 140 conveniently sets a user interface (UI) such as adding a new button or deleting an unnecessary button for performing a function required for a specific digital device operation. It becomes possible.

As such, when forming a user interface for the operation of the digital device, the UI setting unit may be configured to generate a group button that collects various functions related to the operation of the digital device.

Accordingly, in the group button for performing specific functions, it is possible to improve the convenience of use by learning a control command for performing each function. In addition, by storing the group button itself in the format server without sharing the functions, and sharing the same among the users of the same digital device, it is possible to easily form a group button through the update of the application for the group button.

In addition, the UI setting unit 140 expresses the keys required for the operation of the digital device to the display means, the operation is performed only by the user's touch input or drag input or voice recognition for the keys displayed on the display means. It may be configured to allow, of course, further comprises a sensor recognition unit 142 for recognizing an input for the operation function of the digital device by the motion information of the smart phone recognized by the acceleration sensor or the direction sensor provided in the smart phone. It is preferable to be configured.

At this time, the sensor recognition unit 142 recognizes the movement and movement of the smart phone itself and is configured by matching the operation function of the digital device with the movement and movement of the smartphone 100, for this purpose, the sensor recognition unit ( 142 is connected to receive the motion information of the acceleration sensor or the direction sensor provided in the smartphone and is configured to match the function of the digital device by setting the desired function to the movement information of the smartphone.

Accordingly, as an example of matching the function of the TV using the sensor recognition unit, the sensor recognition unit 142 matches the rising signal of the channel to the right side of the smartphone by the acceleration sensor and the direction sensor, the smartphone The left side movement of the channel to match the falling signal, the movement of the smartphone to the front to match the rising signal of the volume, the movement of the smartphone to the rear can be configured to match the falling signal of the volume have. Such a function matching is just one example, and in addition to the function matching, the movement of the smart phone and the operation function of the digital device may be matched in various ways.

The UI setting unit 140 may further include a macro setting unit 144 configured to sequentially generate different driving signals according to the arrival of a specific time or the passage of a predetermined time to generate and transmit a driving signal. It is preferable.

The macro setting unit 144 may be configured to generate a driving signal by changing a data code which is a control command in an arbitrary time unit set for the same custom code so that different control commands for the same digital device are sequentially performed. Of course, it may be configured to generate a drive signal, such as by activating the digital device by combining a control command matched to each custom code while changing the custom code according to the time set to sequentially select a plurality of digital devices to operate continuously have.

Accordingly, the macro setting unit 144 is the first transmission of the drive signal at a predetermined time, after which the drive signal containing a plurality of predetermined control commands are sequentially generated according to the elapsed time set by the IR repeater To 300.

As an example set in the macro setting unit, when the set time is 8:00 AM, the television is turned on, and the EBS channel (CH 13) is sequentially selected, and the volume is gradually increased when there is no user response. Can be configured to help the user wake up. In addition, when setting the noise level (dB) of the television received through the call receiving unit provided in the smart phone may be configured to gradually increase the volume of the television to the set level of the volume.

In addition, when a plurality of digital devices are sequentially selected and continuously operated, a macro driving signal of digital devices to be continuously operated using a smartphone, for example, at 7 pm, lights up at 7 pm, 30 pm By automatically generating and transmitting various macro driving signals such as turning on the boiler at 8 minutes and turning on the television at 8 pm, home automation can be realized at a simple and low cost. .

In addition, even when the user is outside, after receiving the macro driving signal generated and transmitted from the smart phone 100 according to the arrival and elapse of a predetermined time from the relay home server 200, the IR repeater located in the room ( Since it is possible to operate the digital device 500 by transmitting to 300, it is possible to easily build automation without incurring a large cost.

In addition, the smart phone 100 is a digital device, as shown in Figure 3, so that the UI set by the user by the UI setting unit can be exchanged between users operating the same digital device stored in the smartphone, It is preferable that the gateway is further configured to generate a gateway for data transmission and reception between smartphones on which the control application is installed and through which the transmission and reception of the UI is performed.

In addition, the smart phone 100 uploads and stores the infrared signal pattern of the digital device, that is, the remote controller format, which is learned through the infrared signal learning unit 130 and analyzed the pattern, to the format server 400 through a wireless communication network. In addition, the format down unit 160 that is connected to the format server 400 on the wireless communication network to download the remote control format uploaded by another user or the format uploaded by the manufacturer of the digital device from the format server 160 to transmit and receive data. It is preferable that it is configured to include more.

Accordingly, a user who is authenticated by accessing the format server 400 through the format down unit 160 can easily download and use various remote control formats for various types of digital devices.

In addition, the remote control format downloaded through the format down unit 160, that is, the infrared signal pattern is matched with the display button on the user interface set in the smart phone to maintain a separate interface for each smart phone user, It is preferable to further include a function matching unit 162 for matching and storing the display button on the remote control format and the function of the digital device.

The relay home server 200 is a home server which is located indoors and has a communication means for receiving a driving signal transmitted through a 3G network or Wi-Fi using a base station from an external smartphone. It is composed.

At this time, the relay home server 200 is a smart phone communication unit 210 is provided with a wireless LAN that is a WiFi module that can receive a drive signal transmitted from an external smartphone, the drive signal received from the Wi-Fi module As a repeater communication unit 220 for transmitting to the IR repeater provided in the room, a Bluetooth module 222 made of a Bluetooth dongle or the like is provided.

When the IR repeater 300 also includes a Wi-Fi module 344 capable of transmitting and receiving data through Wi-Fi, the repeater communication unit 220 does not include a Bluetooth module for transmitting and receiving data with the relay home server indoors. Of course, it can be made of a Wi-Fi module 224 without.

In this case, the relay home server 200 may implement a Dynamic Domain Name System (DDNS) service that automatically updates the DNS database whenever a new IP address is given by the Internet service provider by matching the dynamic IP with the host domain. It is preferably configured to include a DDNS matching unit 230. Accordingly, even a user using the Internet service by the dynamic IP can stably receive the driving signal of the digital device transmitted from the smart phone to the 3G network or Wi-Fi in the smart phone to control the digital device.

In general, an Internet service provider assigns a dynamic IP when a user connects to the Internet so that a personal computer provided at home can be used as a server. In order to access the personal computer again, an Internet service provider needs to know a newly changed IP address. It is difficult to use a personal computer as a stable server.

Accordingly, the DDNS matching unit 230 is composed of a program that is executed in a personal computer to match the dynamic IP and the host domain so that the server can be used stably even with a dynamic IP changed, such as optical LAN or local cable Installed on your computer.

The DDNS matching unit 230 automatically updates the DNS database whenever an IP address is newly given by an Internet service provider, so that other users may know the newly changed IP address even if the IP address corresponding to the specific domain name is changed. It is possible to use a personal computer as a stable server because it is possible to easily access the personal computer using a domain name as before. In addition, if DDNS service is not supported for Internet service provider, the same function can be implemented by updating the DNS database every time a new IP address is given and making a program that enables stable access and executing it on a personal computer. Of course.

In addition, the relay home server 200 may be configured as an IP sharer 240 equipped with a Wi-Fi module capable of receiving a driving signal transmitted through Wi-Fi through a local network. When the relay home server is configured as the IP sharer 240 as described above, transmission and reception of driving signals can be performed by the IP sharer that always maintains the activation state even without continuously running the personal computer.

At this time, the IP sharer 240 may be configured with a separate Bluetooth module to transmit the drive signal received from the external smartphone to the IR repeater, IP router itself is not easy to install other equipment or programs Considering the characteristics of the IP router, only the Wi-Fi module is provided, it is preferable that the IR repeater 300 is configured to install the Wi-Fi module 344 to enable data transmission and reception with the IP router on the local network. .

As described above, the driving signal of the digital device transmitted from the smart phone 100 outdoors through the 3G network or the Wi-Fi is reliably transmitted by the relay home server 200 which is already installed in most homes, such as a personal computer or an IP router. It is possible to receive, the relay home server 200 is configured to transmit the drive signal directly to the IR repeater 300 located in the same room, thereby stably operating the operation of the digital device whether the user is indoors or outdoors It can be controlled to overcome the spatial constraints when controlling digital devices. Accordingly, it is possible to easily and stably operate the digital devices in the home at high distances without incurring a large amount of costs, thereby realizing home automation.

At this time, when the user operates the digital device indoors, the drive signal is transmitted through the local area network (Bluetooth network) without direct transmission of the driving signal through the Wi-Fi network. Of course it can be prevented.

The IR repeater 300 is a drive signal receiving unit 310 for receiving a drive signal transmitted from the smart phone or relay home server, and an infrared signal corresponding to a custom code and a control command of the digital device constituting the received drive signal An infrared signal generator 320 for generating, an infrared signal transmitter 330 for transmitting the infrared signal toward the digital device, and a learning signal receiver 350 for receiving an infrared signal transmitted from a remote control device of a new digital device. And a microcomputer 360 for capturing and transmitting the infrared signal received from the learning signal receiver to a smartphone and receiving and storing the infrared code analyzed by the smartphone again, and driving from the smartphone or the relay home server. It comprises a wireless communication unit 340 for receiving a signal.

The driving signal receiver 310 receives a driving signal of a digital device generated by the driving signal generator 110 of the smart phone and transmitted directly or transmitted through the relay home server 200 through the wireless communication unit 340. It is configured to.

To this end, the wireless communication unit 340 may be configured as a Bluetooth module 342 capable of transmitting and receiving data from the smart phone 100 or the relay home server 200 through the Bluetooth network, as well as the smart phone or relay home It may be configured as a Wi-Fi module 344 capable of transmitting and receiving data through the Wi-Fi from the server.

In this case, the driving signal receiver 310 distinguishes a custom code indicating a digital device from a received driving signal and a control command of the corresponding digital device, and stores the custom code in a repeater remote control format storage unit provided in the IR repeater. Compared to the custom code, it is configured to recognize suitable digital device to transmit control command.

The repeater remote control format storage unit 380 is preferably configured to store a remote control format including a custom code and data codes of digital devices released from domestic and foreign home appliances, similar to the remote control format storage unit provided in the smart phone. .

The infrared signal generating unit 320 is composed of infrared generating means for generating an infrared signal corresponding to a custom code and a control command recognized by the drive signal receiving unit, the infrared signal transmitting unit 330 is the infrared signal generating unit It is configured to control the operation of the digital device by transmitting the infrared signal generated by the outside.

In this case, since the infrared signal transmitted from the infrared signal transmitter 330 has a straightness like a conventional remote controller, the infrared signal can be transmitted to a digital device regardless of the position where the IR repeater is placed. As described above, the infrared repeater 300 may include a plurality of infrared light emitting diodes disposed radially on an outer circumferential surface thereof, and may be configured to simultaneously transmit infrared signals generated by the infrared signal generator from all infrared signal transmitters.

The signal of a typical infrared light emitting diode (IR LED) has a controllable angle of typically ± 30 ° when the light intensity is 50% at the maximum luminous intensity. Therefore, as shown in FIG. 4, when six infrared light emitting diodes (IR LEDs) 330 are radially disposed, infrared signals may be transmitted in all directions of 360 ° to easily control digital devices at any position. It becomes possible.

In addition, the learning signal receiving unit 350 is activated when the IR repeater is set to the learning mode, and receives an infrared signal transmitted from a remote control device 510 such as a remote control that is set with a digital device to be newly learned. It consists of an infrared receiver IR_Receiver.

The microcomputer 360 functions as a controller for general control of the IR repeater, and captures and stores an infrared signal received by the learning signal receiver 350 as it is, and transmits it to a smartphone. It is composed.

In this case, since the infrared signal takes the form of a signal transmitted from a conventional remote control device 510, a custom code that functions as a lead code for activating a digital device and an address distinguishing the digital device. A code (Custom code), a data code (Data code) which is an actual control command of the digital device, and an inverted data code () inverting the data code.

In addition, the custom code may be configured as a single custom code, as well as in a variety of forms adopted by the manufacturer, that is, the first custom code (Custom code) and the reverse or repeat the first custom code It may be configured to have a structure in which the second custom code (Custom code ') is configured to overlap.

In addition, the IR repeater 300 sequentially generates infrared signals according to a custom code and a data code included in each driving signal of driving signals transmitted from a plurality of smartphones, as shown in FIG. 5. It is preferably configured to further include a multi-control processing unit 390 to control the operation of.

In the home, a number of people may frequently transmit various types of driving signals to the same IR repeater 300 using their respective smartphones 100. That is, when user A controls TV and user B wants to control audio and generates and transmits a driving signal from his or her smartphone at about the same time, the multi-control processing unit 390 receives the driving signal according to the order of reception. Infrared signals corresponding to each driving signal are generated and transmitted.

As such, the multi-control processing unit 390 receives the driving signal transmitted from the smartphone, and sequentially generates and transmits an infrared signal corresponding to the received driving signal, so that multiple users can use the digital device in the same space. Even in the case of controlling the multiple digital devices can be controlled by a single IR repeater.

The format server 400 is a smart phone authentication unit 410 for authenticating a user accessing a format database by authenticating a user connected on a wireless communication network, and remote control formats of digital devices provided by domestic and overseas manufacturers or users by infrared signals. And a format database 420 for storing and uploading a user interface suitable for a user, and a format transmission unit 430 for transmitting a remote control format and a user interface selected by a user to a smartphone of an authenticated user. It is configured by.

At this time, the format database 420 analyzes the pattern of the remote control format forming the infrared signal by activation of the learning mode and then minimizes (compresses) the received infrared signal data uploaded from the smartphone 100 through a wireless communication network. To store the data.

Accordingly, when the user A learns the A format for the digital device of the company A and stores it in the smartphone 100 and the IR repeater 300 as well as the format database 420, the user B is installed in the smartphone. After activating the digital device control application is connected to the format server 400 is authenticated to be granted access to the format database (410). After receiving the access right to the format database as described above, the user uploads and stores the A format uploaded and stored in the B user's smartphone and the IR repeater to easily store the remote control format of the new digital device. .

In addition, by a community function, such as a bulletin board that can share information between smartphones with the digital device control application is installed, several users learn the remote control format of several digital devices, create their own user interface and store in a format database It may be configured to identify and share with each other.

As described above with reference to FIG. 6, a remote controller is connected to a format server using a smartphone to find a remote controller format, and a suitable remote controller format is downloaded and stored. In order to use, the remote control format stored in the IR repeater 300 and the remote control format stored in the smartphone 100 must be matched.

Accordingly, taking the TV as an example, the user checks the manufacturer (Company A) of the TV to be operated by the digital device control application provided in the smart phone 100, and then accesses the format server 400 to be authenticated to the format database. 420 is granted access. In this case, the format of the remote controller may be different even in the same manufacturer, so it is necessary to continuously check the format of the remote controller for the TV.

In the digital device control application provided in the smart phone to download the power remote control format of the TV produced by the manufacturer in order to check whether the TV operation. In this case, only the power remote control format is downloaded first without downloading all of the corresponding remote control formats (shown by the process of ① in FIG. 6), and then the driving signal is transmitted from the smart phone 100 to the IR repeater 300 so as to provide a TV 500. ) Will be checked.

As shown in FIG. 6, the TV is not turned on by the A format and the B format of the A company, but the TV is turned on by the C format of the A company (shown as a process of ② in FIG. 6). In the smart phone 100, a custom code and a data code of an infrared signal having a C format of company A are downloaded from the format database 420 (shown in step 3 in FIG. 6) and stored.

When the remote control format matching the TV is selected as described above, the user expresses and confirms the remote control format on the display means of the smart phone, and then downloads and stores the remote control format from the format database 420. In this case, the smart phone 100 is configured by the function matching unit 162 in the corresponding remote control format to match the button displayed on the display means of the smart phone and the function set in each button and then store.

Next, with reference to FIGS. 7 to 11, it will be described to control a digital device at home indoors or outdoors by a digital device control system capable of learning an infrared signal using a smart phone according to the present invention.

7 is a system configuration diagram showing a first embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

Referring to FIG. 7, the first embodiment of the present invention shows that the home appliance is controlled by activating a digital device control application installed in a smart phone indoors.

Accordingly, the smart phone 100 and the IR repeater 300 is provided with a Bluetooth module, respectively, and the drive signal transmitted from the drive signal generator 110 provided in the smart phone through the Bluetooth module IR repeater After receiving by the drive signal receiving unit provided in the 310 to generate and transmit an infrared signal suitable for the drive signal, to control the operation of the audio, air conditioning, TV or home theater in the home.

8 is a system configuration diagram showing a second embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

Referring to FIG. 8, the second embodiment of the present invention controls a home appliance in a home by activating a digital device control application installed in a smart phone outdoors.

To this end, the relay home server 200 made of a personal computer that first receives a driving signal transmitted from the smartphone is provided with a Wi-Fi module 210 to enable data transmission and reception via an external 3G network or Wi-Fi, and at home Bluetooth dongle which is a Bluetooth module 342 capable of transmitting the driving signal back to the IR repeater 300 is provided.

Accordingly, the driving signal, which is a device control signal for driving home appliances in the home, transmitted from the smart phone, uses a 3G network or Wi-Fi communication according to the Wi-Fi module 210 which is a communication means provided in the relay home server 200. In this case, the relay home server 200 can stably receive the driving signal by the DDNS matching unit 230 despite the IP change.

The relay home server transmits the driving signal to the IR repeater 300 by Bluetooth communication in the Bluetooth module 222, and thus transmits the driving signal transmitted from the smartphone 100 via the relay home server 200. By generating and transmitting an infrared signal suitable for the driving signal from the received IR repeater 300, it is possible to stably control the operation of the audio, air conditioner, TV or home theater in the home from the outside to implement home automation do.

9 is a system configuration diagram showing a third embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

Referring to FIG. 9, the third embodiment of the present invention shows that the home appliance is controlled by activating a digital device control application installed in a smart phone indoors. At this time, in the third embodiment, the IR repeater 300 is provided with a Wi-Fi module 344 capable of transmitting and receiving data through Wi-Fi communication.

As described above, the IR repeater is provided with a Wi-Fi module 344, and when the driving signal, which is a device control signal of a home appliance, transmitted through the Wi-Fi communication from the smart phone to the repeater, the IR repeater 300 receives the IR repeater 300. By generating and transmitting an infrared signal suitable for one drive signal, the operation of the audio, air conditioner, TV or home theater in the home is controlled.

10 is a system configuration diagram showing a fourth embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

Referring to FIG. 10, the fourth embodiment of the present invention controls the home appliance in a home by activating a digital device control application installed in a smart phone outdoors. At this time, in the fourth embodiment, a wireless LAN 210 capable of Wi-Fi communication is provided in the relay home server 200, and the IR repeater 300 is provided with a Wi-Fi module 344 capable of transmitting and receiving data through Wi-Fi communication. Is done.

The driving signal, which is a device control signal for driving home appliances, transmitted from the smart phone, is first received by using the Wi-Fi communication by the wireless LAN 210 which is a communication means provided in the relay home server 200. In this case, the relay home server can receive the driving signal stably despite the IP change by the DDNS matching unit.

The relay home server 200 transmits the received driving signal to the IR repeater 300 using the Wi-Fi communication in the wireless LAN, and the IR repeater 300 is smart via the relay home server by the Wi-Fi module. Receive the drive signal sent from the phone. In addition, the IR repeater 300 generates and transmits an infrared signal suitable for the driving signal, thereby stably controlling the operation of an audio, air conditioner, TV, or home theater in the home from the outside, thereby enabling home automation. do.

11 is a system configuration diagram showing a fifth embodiment of a digital device control system capable of learning infrared signals using a smart phone according to the present invention.

Referring to FIG. 11, the fifth embodiment of the present invention shows that the home appliance is controlled by activating a digital device control application installed in the smart phone. At this time, in the fifth embodiment, the relay home server is configured as an IP sharer 240 capable of Wi-Fi communication, and the IR repeater is provided with a Wi-Fi module 344 capable of transmitting and receiving data through Wi-Fi communication.

The drive signal, which is a device control signal for driving home appliances in the home, transmitted from the smart phone, is first received by the IP sharer 240 that forms a local network and enables Wi-Fi communication, and then uses the Wi-Fi communication to connect the IR repeater ( 300).

The IR repeater 300 receives a driving signal transmitted from the smartphone via the IP sharer 240 by the Wi-Fi module 344. In addition, the IR repeater 300 generates and transmits an infrared signal suitable for the driving signal, thereby stably controlling the operation of an audio, air conditioner, TV, or home theater in the home from the outside, thereby enabling home automation. do.

In this way, by installing a Bluetooth module or a Wi-Fi module in the IP repeater, as well as the drive signal transmitted directly from the smartphone, the drive signal transmitted using the 3G network or Wi-Fi communication from the smart phone in the outdoors located at home After receiving from a relay home server made of a personal computer or the like, and transmitting to an IR repeater through a local network such as Bluetooth communication or Wi-Fi communication that forms a local area network in the home, it is configured to control digital devices at low cost, thus providing stable home automation. Can be implemented.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

100-smartphone 110-drive signal generator
120-driving signal communication unit 130-infrared signal learning unit
132-Pattern Analysis Unit 134-Infrared Signal Storage Unit
140-UI setting unit 142-Sensor recognition unit
144-Macro setting unit 150-UI transmitting unit
160-Format down section 162-Function matching section
170-remote control format storage unit
200-Relay Home Server 210-Smartphone Communication Unit
220-Repeater Communication Unit 222-Bluetooth Module
224-Wifi Module 230-DDNS Matching Unit
240-IP Router
300-IR Repeater 310-Drive Signal Receiver
320-Infrared signal generator 330-Infrared signal transmitter
340-Wireless Communication Unit 342-Bluetooth Module
344-WiFi Module 350-Learning Signal Receiver
360-Microcomputer 370-Pattern Receiver
380-Repeater Remote Format Storage
390-Multi Control Processing Unit
400-Format Server 410-Smartphone Authentication
420 Format Database 430 Format Transmission
500-Digital Device 510-Remote Control Unit

Claims (17)

delete delete delete delete A drive signal generator for generating a drive signal for controlling a digital device by operating a button displayed on the display means by activating a digital device control application, and driving signals of the digital device generated by the drive signal generator through a wireless communication network. Smart phone including a drive signal communication unit for transmitting;
A relay home server for receiving a driving signal transmitted from an external smartphone and transmitting the IR signal to an IR repeater installed indoors;
A drive signal receiver for receiving a drive signal transmitted from the smartphone or relay home server, an infrared signal generator for generating an infrared signal corresponding to a custom code and a control command of a digital device constituting the received drive signal, and the infrared ray An IR repeater including an infrared signal transmitter for transmitting a signal toward a digital device, and a wireless communication unit for forming a gateway for receiving the driving signal;
The relay home server includes a smart phone communication unit consisting of a Wi-Fi module for receiving a drive signal transmitted from an external smart phone, and a repeater communication unit for transmitting a drive signal received from the smart phone to an IR repeater located indoors Configured;
When the IR repeater is provided with a Bluetooth module, the repeater communication unit is also configured as a Bluetooth module, and when the IR repeater is equipped with a Wi-Fi module, the repeater communication unit is also configured as a Wi-Fi module capable of Wi-Fi communication;
The smartphone authentication unit authenticates the access rights to the format database by authenticating the user connected from the wireless communication network, and the remote controller format of digital devices provided by domestic and foreign manufacturers, or the users learn the infrared signal and generate and upload the user interface. Infrared signal using a smart phone, characterized in that it further comprises a format database that stores the interface and the like, and a format transmission unit for transmitting the remote control format and the user interface selected by the user to the smart phone of the authenticated user Digital device control system for learning. The method of claim 5,
In the smartphone,
An infrared signal learning unit for receiving and storing an infrared signal of a new digital device transmitted from the IR repeater; And
A UI setting unit configured to form an interface of a smart phone user for manipulating a function of a newly learned infrared signal, and to match and store a function of a control command to each button constituting the user interface;
The IR repeater,
Learning signal receiving unit for receiving an infrared signal transmitted from a remote control device of a new digital device; And
Capturing the infrared signal received by the learning signal receiving unit and transmitting to the smartphone and infrared signal learning using a smartphone, characterized in that it further comprises a micom for receiving and storing the infrared code transmitted from the smartphone Possible digital device control system. The method according to claim 6,
The infrared signal learning unit includes a pattern analyzer configured to receive an infrared signal of a new digital device transmitted after being captured by the IR repeater, and to analyze, compress, and store the pattern of the infrared signal. Digital device control system capable of signal learning. The method according to claim 6,
The infrared signal learning unit stores an infrared signal storing a form in which codes such as a lead code, a custom code, a data code, and an inverted data code, which form a captured infrared signal of a new digital device transmitted from the IR repeater, are integrated together. Digital device control system capable of learning infrared signals using a smart phone, characterized in that the unit comprises a. The method according to claim 6,
The UI setting unit may further include a sensor recognizer configured to match an operation function of a digital device to motion information of the smartphone recognized by an acceleration sensor or a direction sensor included in the smartphone and store the same as a user interface. Digital device control system capable of learning infrared signal using phone. The method according to claim 6,
The smart phone further includes a UI transmitter for transmitting and receiving a user interface stored in the smart phone after the user is set by the UI setting unit by generating a gateway for transmitting and receiving data between smart phones having a digital device control application is installed Digital device control system capable of learning infrared signals using a smart phone, characterized in that configured to. The method according to claim 6,
The smartphone uploads the infrared signal pattern of the digital device, which is learned through the infrared signal learning unit and analyzes the pattern, to the format server through a wireless communication network, and is uploaded by a remote controller format or a manufacturer of the digital device already uploaded by another user. Infrared signal learning system using a smart phone, characterized in that it further comprises a format down unit connected to the format server on the wireless communication network to download the remote control format from the format server. The method of claim 11,
Infrared signal using a smart phone characterized in that it further comprises a function matching unit for storing the function on the infrared signal pattern, which is a remote control format downloaded through the format down unit and matching with the display button on the user interface set in the smart phone Digital device control system for learning. The method according to claim 6,
The relay home server is located in the interior and comprises a personal computer equipped with a communication means for receiving a drive signal transmitted through a 3G network or Wi-Fi (Wi-Fi) using a base station from an external smartphone. Digital device control system capable of learning infrared signals using a smartphone. The method of claim 13,
The relay home server includes a DDNS matching unit that implements a Dynamic Domain Name System (DDNS) service by matching a dynamic IP with a host domain and automatically updating a DNS database whenever an IP address is newly given by an Internet service provider. Digital device control system capable of learning infrared signals using a smart phone, characterized in that the configuration. The method of claim 6, wherein
The relay home server is a digital device control system capable of learning infrared signals using a smart phone, characterized in that configured as an IP sharer equipped with a Wi-Fi module that can receive a drive signal transmitted via Wi-Fi communication through a local network. The method according to claim 6,
The infrared signal transmitter is a digital device control system capable of learning infrared signals using a smart phone, characterized in that consisting of a plurality of infrared light emitting diodes disposed radially on the outer peripheral surface of the IR repeater. The method according to claim 6,
The IR repeater further comprises a multi-control processing unit for generating a plurality of infrared signals according to the custom code and data code included in each driving signal transmitted from a plurality of smartphones, and then transmits them to control a plurality of digital devices. Digital device control system capable of learning infrared signals using a smartphone.

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