KR20120095117A - System and method for data transmitting based on wireless network - Google Patents

Abstract

PURPOSE: A wireless network based data transmission system and a method thereof are provided to operate a battery by optimizing a signal transmission period of a wireless relay device. CONSTITUTION: A wireless relay device(100) converts an operation mode into an active mode according to confirming request event generation in a sleep mode state. The wireless relay device transmits a data transmission confirming request to a terminal device. The wireless relay device receives a transmission request through an antenna. The wireless relay device transmits remote data. The remote data includes one or more location information and state information.

Description

Wireless network-based data transmission system and method thereof {SYSTEM AND METHOD FOR DATA TRANSMITTING BASED ON WIRELESS NETWORK}

The present invention relates to a Ubiquitous Sensor Network (USN) location information and status information transmission scheme, and more specifically, to implement the duplication of the radio relay antenna, and to perform power control through the purpose-directed driving of the redundant antenna, The present invention relates to a wireless network-based data transmission system and method for enabling a wireless relay apparatus to be driven by a battery by optimizing a signal transmission cycle and transmission attempt of the wireless relay apparatus, and a wireless relay apparatus and a method of operating the same.

Conventional location-based systems such as Wi-Fi, ultra-wideband (UWB), ultrasound-based systems, passive RFID systems, and RSSI-based LBS systems Wireless relay devices for implementation exist in a variety of ways, but because there is no obvious alternative to the power consumption of the device has been implemented to be installed and operated only in a limited area to provide power at all times.

That is, in the case of the wireless relay device (AP) applied to the above-described Wi-Fi system, the signal of the tag must always be received, and thus, a constant power source (AC 220V) must be used. However, there is a limit in the place of installation of the radio relay apparatus to apply the constant power, and the apparatus installation cost is paid at a considerably high price. Moreover, when the number of tags existing in one radio relay region increases, traffic is generated high, making it difficult to predict power consumption of the radio relay apparatus.

In addition, the wireless relay device applied to the ultra-high speed short-range wireless communication system also needs to always receive the signal of the tag using the constant power (AC 220V). In this regard, in the case of ultra-high-speed short-range wireless communication, since the frequency band is considerably high, the radio wave environment is more affected than the 2.4Ghz ISM area. Therefore, it is impossible to determine the number of radio relays in each standardized area. Power line construction costs are high.

In addition, in the case of an ultrasound-based device, more ultrasonic wave generators should be installed than the RF method, and this device should also use a constant power supply (AC 220V). In this regard, in the case of ultrasonic waves, there is a distance limitation, so there is a disadvantage in that application is determined depending on the site environment due to the limitation on the installation position of the ultrasonic generator. Moreover, since the error rate is considerably high in the management of facilities and facilities inside a noisy factory, the cost of increasing the power line installation cost and the number of installation devices is very high.

In addition, the RFID tag applied to the passive RFID system, there is an advantage that can be attached freely regardless of the attachment position in a non-powered manner. However, the distance constraint is quite high because the RFID reader produces power through radio waves. Therefore, the risk factor of the inspector is higher than that of other devices because the reader must enter and read the inspection area by using the RFID reader. To solve this problem, RFID reader must be installed in a specific location, but the power consumption is high, so battery power cannot be used and constant power (AC 220V) must be used. In addition, since additional communication facilities (LAN, Wi-Fi, ZigBee, etc.) have to be established in order to transmit RFID tag information to the server, the infrastructure cost of installing the RFID system is also significantly applied.

In addition, the radio relay apparatus applied to the RSSI-based LBS system also needs to maintain a reception standby state in order to receive all signals of tags existing in the area. In addition, the wireless relay device must maintain the maximum transmission power for overcoming the radio wave environment in order to transmit the received tag signal to the server, and because the maximum current consumption time is long by transmitting / receiving switching of RF, it is not always battery power. (AC 220V) must be used.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a redundant antenna by switching an operation mode to an active mode according to a preset confirmation request event occurring in a sleep mode. When the data transmission confirmation request is transmitted through at least one antenna, when the terminal device or the information collection device receives the data transmission confirmation request, the terminal requests the data transmission to the wireless relay device and receives the data. Wireless network-based data transmission system for transmitting the remote data including at least one of the location information and the status information to the terminal device or the information collecting device when the wireless relay device receives the data transmission request, and the device By providing a method, redundancy of the radio relay antenna is realized. And, the to and performing the power control with the desired directional driving of redundant antenna Further, to optimize the signal transmission period and the transmission attempt of the wireless repeater device to enable the operation of the wireless relay apparatus via the battery.

The present invention has been made in view of the above circumstances, and an object of the present invention is to achieve at least one of the dual antennas by switching the operation mode to an active mode according to a preset confirmation request event occurrence in a sleep mode state. The data transmission request is transmitted through the antenna, and in response to the data transmission confirmation request, the data transmission request is received from the terminal device or the information collection device through the corresponding antenna to receive at least one of position information and status information. And a data transmission step of transmitting the remote data to the information collecting device. By providing a wireless relay device and a method of operation thereof, it is possible to realize the redundancy of the wireless relay antenna, to perform power control by driving the purpose of the dual antenna, and to optimize the signal transmission cycle and transmission attempt of the wireless relay device. It is to enable the operation of the wireless repeater through the battery.

According to an aspect of the present invention for achieving the above object is provided a wireless network-based data transmission system: this system, when receiving a request for confirmation of data transmission, requests a data transmission to a specific wireless relay device corresponding thereto, A terminal device for receiving remote data from the wireless relay device in response to the data transmission request; An information collection device for requesting data transmission to a specific wireless relay device corresponding to the request for confirmation of data transmission and receiving remote data from the wireless relay device in response to the data transmission request; And switching the operation mode to the active mode in response to the occurrence of a preset confirmation request event in the sleep mode, and transmitting the data transmission confirmation request to the terminal device or the information collecting device through at least one of the dual antennas. In response to the data transmission request via the corresponding antenna characterized in that it comprises a wireless relay device for transmitting the remote data including at least one of the position information and status information.

According to another aspect of the present invention, a wireless relay device is provided: The device switches data from an active mode to an active mode according to occurrence of a preset confirmation request event in a sleep mode, and transmits data through at least one of the dual antennas. A transmission confirmation request unit for transmitting a transmission request; A data transmission unit for transmitting remote data including at least one of location information and status information when a data transmission request is received from a terminal device or an information collection device through a corresponding antenna in response to the request for confirmation of data transmission; And an antenna switching unit for switching the redundant antennas under the control of the transmission confirmation request unit.

Preferably, the wireless relay device, characterized in that it further comprises a power supply for providing a battery power for driving the wireless relay device.

Preferably, the transmission confirmation request unit, characterized in that for transmitting the data transmission confirmation request through at least one of the antenna of the dual antenna including a directional antenna and a non-directional antenna.

Preferably, the data transmission unit is characterized in that for transmitting the location information to the terminal device via the directional antenna in response to receiving the data transmission request.

Preferably, the data transmitter, in response to receiving the data transmission request, characterized in that for transmitting the status information to the information collecting device through the omni-directional antenna.

Preferably, the data transmission unit, when the data transmission request is not received for a set time in response to the data transmission confirmation request, characterized in that for switching the operation mode to the sleep mode.

According to another aspect of the present invention, there is provided a wireless network-based data transmission method comprising: a mode switching step of a wireless relay device switching an operation mode to an active mode according to occurrence of a preset confirmation request event in a sleep mode; A transmission confirmation request step of transmitting, by the wireless relay device, a request to confirm whether data is transmitted through at least one of the dual antennas; A data transmission request step of requesting data transmission to the wireless relay device when a terminal device or an information collection device receives the data transmission confirmation request; And a data transmission step of transmitting, by the wireless relay device, the remote data including at least one of position information and status information to the terminal device or the information collection device when the data transmission request is received. do.

According to still another aspect of the present invention, there is provided a method of operating a wireless relay apparatus, the method comprising: a mode switching step of switching an operation mode to an active mode according to occurrence of a preset confirmation request event in a sleep mode state; A transmission confirmation request step of transmitting a data transmission confirmation request through at least one of the dual antennas; A data transmission request reception step of receiving a data transmission request from a terminal apparatus or an information collecting apparatus through a corresponding antenna in response to the request for confirming whether the data transmission is performed; And a data transmission step of transmitting the remote data including at least one of position information and status information to the information collection device in response to receiving the data transmission request.

Preferably, the transmission confirmation request step, characterized in that for transmitting the data transmission confirmation request through at least one of the antenna of the dual antenna including a directional antenna and a non-directional antenna.

Preferably, the data transmission step, in response to receiving the data transmission request, characterized in that for transmitting the location information to the terminal device via the directional antenna.

Preferably, the data transmission step, in response to receiving the data transmission request, characterized in that for transmitting the status information to the information collecting device through the omni-directional antenna.

The method may further include a mode returning step of switching an operation mode to the sleep mode when the data transmission request is not received for a set time in response to the data transmission confirmation request. .

According to the wireless network-based data transmission system and method thereof according to the present invention, the power control is performed through the purpose-directed driving of the dual antenna of the wireless relay device, and the signal transmission cycle and transmission attempt of the wireless relay device are optimized. As a result, the battery can be driven, eliminating the need for a power line infrastructure. In addition, by reducing the cost of constructing the power line infrastructure, location-based services can be expanded, and the power supply pointer is unnecessary, so that the shadow inspection area disappears in accordance with the installation cost and the limitation of the installation location, thereby obtaining detailed and precise location or status information. can do.

1 is a schematic block diagram of a wireless network-based data transmission system according to an embodiment of the present invention.
2 is a schematic configuration diagram of a wireless relay apparatus according to an embodiment of the present invention.
3 is a schematic flowchart illustrating a wireless network-based data transmission method according to an embodiment of the present invention.
4 is a schematic flowchart illustrating a method of operating a wireless relay apparatus according to an embodiment of the present invention.

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

1 is a schematic block diagram of a wireless network-based data transmission system according to an embodiment of the present invention.

As shown in FIG. 1, the system transmits a data transmission confirmation request to the information collection device 200 and, when a data transmission request is received in response to the data transmission confirmation request, receives the location information and the status information. The wireless relay device 100 for transmitting the remote data, including the information collection device 200 and the terminal device 300 for requesting data transmission to receive the remote data from the wireless relay device 100. Here, the wireless relay device 100 is driven by a power source of a battery, for example, an industrial large capacity battery, and the information collecting device 200 is driven through a constant power source (AC 220V).

The wireless relay device 100 transmits a request for confirming data transmission to the information collecting device 200 or the terminal device 300 through one of the dual antennas according to a preset confirmation request event occurrence. More specifically, the wireless relay apparatus 100 generates a preset confirmation request event in the sleep mode standby state, for example, operates a real time clock (RTC), and operates the operation mode according to a set period corresponding to the type of information to be transmitted. By switching to the active mode, a request for confirming data transmission is transmitted to the information collecting device 200 or the terminal device 300. In this case, the wireless relay apparatus 100 transmits a request for confirming data transmission of the state information to the information acquisition apparatus 200 through the omnidirectional antenna, and the terminal apparatus 300 through the directional antenna capable of adjusting the radio wave beam angle. A request to confirm whether or not to transmit data about location information is transmitted. Here, the status information may include information such as whether the wireless relay device 100 is operated and the number of terminal devices 300 interoperating with the wireless relay device 100, that is, within the area of the wireless relay device 100. Can be.

In addition, the wireless relay apparatus 100 feeds back the remote data when a data transmission request is received from the information acquisition apparatus 200 or the terminal apparatus 300 through a corresponding antenna in response to a request for confirming the data transmission. More specifically, the wireless relay apparatus 100 transmits the state information to the information collecting apparatus 200 through the omnidirectional antenna in response to the reception of the data transmission request, and transmits the position information to the terminal apparatus through the directional antenna. 300). At this time, the wireless relay device 100 may transmit the remaining battery information of the wireless relay device 100 when the above state information and location information transmission. Meanwhile, when the data transmission request is not received for a set time in response to the data transmission confirmation request, the wireless relay device 100 switches the operation mode to the sleep mode, thereby minimizing the power consumption of the device.

The information collecting device 200 requests data transmission from the wireless relay device 100 and receives remote data from the wireless relay device 100 in response to the data transmission request. More specifically, when the information collection device 200 receives a request for confirmation of data transmission from the wireless relay device 100, in response to the request for data transmission to the wireless relay device 100, and in response to the data transmission request Correspondingly, status information is received through the omni-directional antenna of the wireless relay apparatus 100.

The terminal device 300 requests data transmission from the wireless relay device 100 and receives remote data from the wireless relay device 100 in response to the data transmission request. More specifically, when the terminal device 300 receives a data transmission confirmation request from the wireless relay device 100, the terminal device 300 requests data transmission from the wireless relay device 100 in response to the data transmission request, and responds to the data transmission request. To receive the position information through the directional antenna of the wireless relay device 100.

Hereinafter, with reference to FIG. 2, a more specific configuration of the wireless relay device 100 according to an embodiment of the present invention will be described.

That is, the wireless relay device 100 includes a transmission confirmation request unit 110 for transmitting a data transmission confirmation request through a dual antenna; A data transmission unit 120 for transmitting remote data when a data transmission request is received from the information collection device 200 or the terminal device 300; It includes a power supply unit 130 for providing a battery power for driving the wireless relay device 100 and an antenna switching unit 140 for switching the redundant antenna under the control of the transmission confirmation request unit 110. Has a configuration.

The transmission confirmation request unit 110 transmits a data transmission confirmation request to the information collecting device 200 or the terminal device 300 through one of the dual antennas according to a preset confirmation request event occurrence. More specifically, the transmission confirmation request unit 110 operates a preset confirmation request event, for example, a real time clock (RTC) in a standby state of the sleep mode, and operates in accordance with a period set to correspond to the type of information to be transmitted. To switch to the active mode and transmits a request to confirm whether the data is transmitted to the information collecting device 200 or the terminal device 300. At this time, the transmission confirmation request unit 110 by switching the antenna to correspond to the type of information to be transmitted through the control of the antenna switching unit 140, through the omni-directional antenna to the information acquisition device 200 for the status information It transmits a data transmission confirmation request, and transmits a data transmission confirmation request for the location information to the terminal device 300 through the directional antenna capable of adjusting the radio wave beam angle. Here, the status information may include information such as whether the wireless relay device 100 is operated and the number of terminal devices 300 interoperating with the wireless relay device 100, that is, within the area of the wireless relay device 100. Can be.

The data transmission unit 120 feeds back the remote data when a data transmission request is received from the information acquisition device 200 or the terminal device 300 through a corresponding antenna in response to the request for confirmation of data transmission. More specifically, the data transmitter 120 transmits the state information to the information collecting apparatus 200 through the omnidirectional antenna in response to the reception of the data transmission request, and transmits the position information to the terminal apparatus through the directional antenna. 300). At this time, the data transmission unit 120 may transmit the remaining battery information of the wireless relay device 100 when transmitting the above-described state information and location information. Meanwhile, when the data transmission request is not received during the set time in response to the data transmission confirmation request, the data transmission unit 120 switches the operation mode to the sleep mode to minimize the power consumption of the device.

The power supply unit 130 provides battery power for driving the wireless relay device 100. More specifically, the power supply unit 130 provides battery power, for example, driving power through an industrial large capacity battery, to the wireless relay device 100 so that modulation transmission and reception operations of signals are performed.

As described above, according to the wireless network-based data transmission system according to the present invention, in addition to performing the power control through the purpose-directed drive for the dual antenna of the wireless relay device, the signal transmission cycle and transmission attempt of the wireless relay device By optimizing the power supply, the battery power can be improved, and the investment cost of the power line infrastructure installation can be improved by applying the battery from the constant power supply (AC 220V) to the existing device power supply problem. In addition, by applying the battery, it solves the limitations of the device installation location that occurs when installing the power line infrastructure, so that the device can be installed in various places and desired places, and the movement of the wireless relay device to the place that requires temporary inspection regardless of time. And easy to install and can easily move the device when not needed. In addition, it overcomes the limitation of installation of unspecified area by applying the battery, thereby eliminating the shadow area of the inspection area, and consequently, obtains precise and detailed information in the area where the status information is desired. In addition, since the information can be obtained over a long distance by the radio frequency (RF) method and its location can be confirmed, a device manager or a facility inspector can guarantee safety from an accident risk factor.

Hereinafter, a wireless network-based data transmission method according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4. Here, for the convenience of description, the configuration shown in FIGS. 1 and 2 will be described with reference to the corresponding reference numerals.

First, a method of driving a wireless network-based data transmission system according to an embodiment of the present invention will be described with reference to FIG. 3.

First, the wireless relay device 100 transmits a request for confirming data transmission to the information collecting device 200 or the terminal device 300 through one of the dual antennas according to a preset confirmation request event occurrence (S110-). S150). Preferably, the wireless relay apparatus 100 generates a preset confirmation request event in a standby state of the sleep mode, for example, operates an RTC (Real Time Clock), and operates the operation mode according to a set period corresponding to the type of information to be transmitted. By switching to the active mode, a request for confirming data transmission is transmitted to the information collecting device 200 or the terminal device 300. In this case, the wireless relay apparatus 100 transmits a request for confirming data transmission of the state information to the information acquisition apparatus 200 through the omnidirectional antenna, and the terminal apparatus 300 through the directional antenna capable of adjusting the radio wave beam angle. A request to confirm whether or not to transmit data about location information is transmitted. Here, the status information may include information such as whether the wireless relay device 100 is operated and the number of terminal devices 300 interoperating with the wireless relay device 100, that is, within the area of the wireless relay device 100. Can be.

Then, the information collecting device 200 or the terminal device 300 requests the data transmission to the wireless relay device (100) (S160-S170). Preferably, when the information collection device 200 receives a request for confirmation of data transmission from the wireless relay device 100, the information collecting device 200 requests status information from the wireless relay device 100 in response thereto. In addition, when the terminal device 300 receives a request for confirmation of data transmission from the wireless relay device 100, the terminal device 300 requests location information from the wireless relay device 100 in response thereto.

Subsequently, in response to the request for confirming the data transmission, the wireless relay apparatus 100 feeds back remote data when a data transmission request is received from the information acquisition apparatus 200 or the terminal apparatus 300 through the corresponding antenna (S180). Preferably, the wireless relay device 100 transmits the state information to the information collecting device 200 through the omni-directional antenna in response to the reception of the data transmission request, and transmits the position information to the terminal device through the directional antenna. 300). At this time, the wireless relay device 100 may transmit the remaining battery information of the wireless relay device 100 when the above state information and location information transmission. Meanwhile, when the data transmission request is not received for a set time in response to the data transmission confirmation request, the wireless relay device 100 switches the operation mode to the sleep mode, thereby minimizing the power consumption of the device.

Hereinafter, a method of operating the wireless relay apparatus 100 according to an embodiment of the present invention will be described with reference to FIG. 4.

First, the operation mode is switched according to a preset confirmation request event occurrence (S210-S240, S290-S300). Preferably, the transmission confirmation request unit 110 operates a predetermined confirmation request event, for example, a real time clock (RTC) in a standby state of the sleep mode, and switches the operation mode to the active mode according to the set period.

Then, a request for confirming data transmission is transmitted to the information collecting device 200 or the terminal device 300 through at least one of the dual antennas (S250 and S310). Preferably, the transmission confirmation request unit 110 transmits a data transmission confirmation request to the information collecting device 200 or the terminal device 300 in the active mode switching state. At this time, the transmission confirmation request unit 110 by switching the antenna to correspond to the type of information to be transmitted through the control of the antenna switching unit 140, through the omni-directional antenna to the information acquisition device 200 for the status information It transmits a data transmission confirmation request, and transmits a data transmission confirmation request for the location information to the terminal device 300 through the directional antenna capable of adjusting the radio wave beam angle. Here, the status information may include information such as whether the wireless relay device 100 is operated and the number of terminal devices 300 interoperating with the wireless relay device 100, that is, within the area of the wireless relay device 100. Can be. Furthermore, the above state information and location information may further include remaining battery information of the wireless relay device 100.

Then, in response to the request for checking whether the data is transmitted, a data transmission request is received from the information collecting device 200 or the terminal device 300 through the corresponding antenna (S260-S270, S320-S330). Preferably, the data transmission unit 120 receives a data request for status information from the information acquisition apparatus 200 through the omnidirectional antenna in response to receiving the data transmission request. In addition, the data transmission unit 120 receives a data transmission request for the location information including the remaining battery power from the terminal device 300 through the directional antenna in response to receiving the data transmission request.

Thereafter, in response to receiving the data transmission request, remote data including location information and status information is transmitted (S280 and S340). Preferably, the data transmitter 120 transmits the state information to the information collecting apparatus 200 through the omni-directional antenna in response to receiving the data transmission request, and transmits the position information to the terminal apparatus through the directional antenna. 300). At this time, the data transmission unit 200 may transmit the remaining battery information of the wireless relay device 100 when the above-described state information and location information transmission. Meanwhile, when the data transmission request is not received during the set time in response to the data transmission confirmation request, the data transmission unit 120 switches the operation mode to the sleep mode to minimize the power consumption of the device.

As described above, according to the wireless network-based data transmission method according to the present invention, while performing the power control by driving the purpose-directed to the dual antenna of the wireless relay device, the signal transmission cycle and transmission attempt of the wireless relay device By optimizing the power supply, the battery power can be improved, and the investment cost of the power line infrastructure installation can be improved by applying the battery from the constant power supply (AC 220V) to the existing device power supply problem. In addition, by applying the battery, it solves the limitations of the device installation location that occurs when installing the power line infrastructure, so that the device can be installed in various places and desired places, and the movement of the wireless relay device to the place that requires temporary inspection regardless of time. And easy to install and can easily move the device when not needed. In addition, it overcomes the limitation of installation of unspecified area by applying the battery, thereby eliminating the shadow area of the inspection area, and consequently, obtains precise and detailed information in the area where the status information is desired. In addition, since the information can be obtained over a long distance by the radio frequency (RF) method and its location can be confirmed, a device manager or a facility inspector can guarantee safety from an accident risk factor.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

The wireless network-based data transmission system and method thereof according to the present invention perform power control by driving purpose-directed driving of a redundant antenna of a wireless relay device, and also optimize signal transmission cycle and transmission attempt of the wireless relay device. As the radio relay device can be driven by a battery, the limitation of the existing technology is overcome, so that not only the use of the related technology but also the possibility of marketing or operating the applied device is not only sufficient but also realistically feasible. It is an invention with industrial applicability as it is a degree.

100: wireless repeater
110: transmission confirmation request unit 120: data transmission unit
130: power supply unit 140: antenna switching unit
200: information collecting device
300: terminal device

Claims (13)

A terminal device for requesting data transmission to a specific wireless relay device corresponding to the data transmission request and receiving remote data from the wireless relay device in response to the data transmission request;
An information collection device for requesting data transmission to a specific wireless relay device corresponding to the request for confirmation of data transmission and receiving remote data from the wireless relay device in response to the data transmission request; And
In response to a preset confirmation request event occurring in the sleep mode, the operation mode is switched to the active mode, and the data transmission confirmation request is transmitted to the terminal device or the information collecting device through at least one of the dual antennas. Correspondingly, when the data transmission request is received through a corresponding antenna, the wireless network-based data transmission system, comprising: a wireless relay apparatus for transmitting remote data including at least one of position information and status information. A transmission confirmation request unit which transmits a data transmission confirmation request through at least one of the dual antennas by switching the operation mode to an active mode according to a preset confirmation request event occurrence in the sleep mode state;
A data transmission unit for transmitting remote data including at least one of location information and status information when a data transmission request is received from a terminal device or an information collection device through a corresponding antenna in response to the request for confirmation of data transmission; And
And an antenna switching unit for switching the redundant antennas under the control of the transmission confirmation request unit. The method of claim 2,
The wireless relay device,
Wireless repeater further comprises a power supply for providing a battery power for driving the wireless repeater. The method of claim 2,
The transmission confirmation request unit,
And transmitting the data transmission confirmation request through at least one of the dual antennas including a directional antenna and a non-directional antenna. The method of claim 4, wherein
The data transmission unit,
And transmitting the location information to the terminal through the directional antenna in response to receiving the data transmission request. The method of claim 4, wherein
The data transmission unit,
And in response to receiving the data transmission request, transmitting the state information to the information collecting device through the omnidirectional antenna. The method of claim 2,
The data transmission unit,
And in response to the data transmission confirmation request, when the data transmission request is not received for a set time, the operation mode is switched to the sleep mode. A mode switching step of switching, by the wireless relay device, the operation mode to the active mode according to occurrence of a preset confirmation request event in the sleep mode state;
A transmission confirmation request step of transmitting, by the wireless relay device, a request to confirm whether data is transmitted through at least one of the dual antennas;
A data transmission request step of requesting data transmission to the wireless relay device when a terminal device or an information collection device receives the data transmission confirmation request; And
And a data transmission step of transmitting, by the wireless relay device, the remote data including at least one of position information and status information to the terminal device or the information collection device when the data transmission request is received. Wireless network based data transmission method. A mode switching step of switching an operation mode to an active mode according to occurrence of a predetermined confirmation request event in a sleep mode state;
A transmission confirmation request step of transmitting a data transmission confirmation request through at least one of the dual antennas;
A data transmission request reception step of receiving a data transmission request from a terminal apparatus or an information collecting apparatus through a corresponding antenna in response to the request for confirming whether the data transmission is performed; And
And a data transmission step of transmitting the remote data including at least one of position information and status information to the information collecting device in response to receiving the data transmission request. The method of claim 9,
The transmission confirmation request step,
And transmitting the data transmission confirmation request through at least one of the dual antennas including a directional antenna and an omni directional antenna. 11. The method of claim 10,
The data transmission step,
And in response to receiving the data transmission request, transmitting the location information to the terminal device through the directional antenna. 11. The method of claim 10,
The data transmission step,
And in response to receiving the data transmission request, transmitting the state information to the information collecting device through the omnidirectional antenna. The method of claim 9,
The method comprises:
And a mode returning step of switching an operation mode to the sleep mode when the data transmission request is not received for a set time in response to the request for confirming whether the data transmission is performed.

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