KR101280034B1 - Location―based bi―directional q＆a and real―time audience response acquisition and alerting system - Google Patents

Abstract

The present invention relates to a network system and a method thereof. More specifically, real-time attendance management supporting a function of collecting and managing an automatic attendance and problem response service by unit space using a sensor network-based location recognition technology and an asynchronous message transmission technology. A sensor network system and method thereof are provided.
To this end, the present invention provides a plurality of first mobile terminals; A second mobile terminal performing two-way wireless communication with the first mobile terminal; And automatically authenticating the first mobile terminal and the second mobile terminal to relay the two-way wireless communication, and requesting the second mobile terminal to transmit a web server or learning material necessary for learning by the first mobile terminal and the second mobile terminal. It includes a gateway that provides real-time to the mobile terminal.

Description

Location-based Bidirectional Q & A and Real-Time Student Response Aggregation Notification System {LOCATION-BASED BI-DIRECTIONAL Q & A AND REAL-TIME AUDIENCE RESPONSE ACQUISITION AND ALERTING SYSTEM}

The present invention relates to a network system and a method thereof. More specifically, real-time attendance management supporting a function of collecting and managing an automatic attendance and problem response service by unit space using a sensor network-based location recognition technology and an asynchronous message transmission technology. A sensor network system and method thereof are provided.

Recently, many infrastructures for various services using wireless sensor networks have been established.

Sensor networks are widely used to provide various services, from simple functions such as collecting and transmitting environmental information to a server or generating an alarm sound when a danger occurs, to a location recognition system using a sensor network.

Of course, such a service may use a wireless network such as WiFi or RFID technology, but there are various problems such as limited resources of the mobile terminal, battery consumption rate, difficulty in providing location recognition service for a system composed of a large-scale mobile device, and difficulty in real-time location tracking.

In addition, in case of a mobile terminal having a lot of movements in a conventional sensor network for bidirectional communication, there is a problem in that the performance of the network is deteriorated due to frequent message exchange for routing. There was a problem that is more difficult.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention, in particular, automatic based on a real-time course management technology for large-scale mobile object and asynchronous message transmission method technology using such location information It is to provide a real-time course management sensor network system and method for providing attendance management and problem response management system.

To this end, the real-time attendance management sensor network system according to the present invention includes a plurality of first mobile terminals; A second mobile terminal performing two-way wireless communication with the first mobile terminal; And automatically authenticating the first mobile terminal and the second mobile terminal to relay the two-way wireless communication, and requesting the second mobile terminal to transmit a web server or learning material necessary for learning by the first mobile terminal and the second mobile terminal. It includes a gateway that provides real-time to the mobile terminal.

Preferably, the first mobile terminal comprises: an LCD interface manager for displaying information including a test question transmitted from the gateway; A key input unit for responding to the test question; A first data manager for transmitting the response; A first data storage for storing the response; A first network manager for transmitting the response; And an external interface manager including a vibration motor or an LED to inform a user of externally detected call information.

In addition, the second mobile terminal preferably comprises a communication interface for receiving lecture information from the gateway, and periodically transmitting location recognition information; A second data processor for processing information transmitted and received to and from the gateway; And a second data storage unit for storing the information processed by the second data processing unit, and is mounted on an external device in the form of a USB dongle to receive power.

The gateway includes a network interface unit for transmitting and receiving information from the first mobile terminal and the second mobile terminal; A second network manager for dividing the information into location information of the first mobile terminal and the second mobile terminal and asynchronous message data generated by an event; A third data management unit for collecting and processing information transmitted from the second network management unit; and a third data storage unit for storing information processed by the third data management unit; A web server manager for organizing the processed data into a web server screen; And a dedicated program manager for exclusive use in an external device.

Preferably, the real-time attendance management sensor network system includes at least one fixed node for extending the wireless communication area of the gateway; And an external server for extending the information providing function of the gateway.

In addition, for this purpose, the real-time course management sensor network method according to the present invention comprises the steps of receiving lecture information and attendance list; Comparing the identification numbers of the attendance unit list with the identification numbers of the plurality of first mobile terminals and authenticating the identification numbers; Confirming attendance of the authenticated first mobile terminal and managing whether the mobile terminal exists within a designated space for a designated time; Authenticating the second mobile terminal; And transmitting lecture information to the second mobile terminal.

Preferably, the process of authenticating the first mobile terminal comprises: activating the first mobile terminal; Continuously receiving, by the first mobile terminal, a beacon message from a plurality of nodes; Selecting a candidate of a parent node according to the received signal strength of the beacon message; And transmitting the identification number of the first mobile terminal.

The managing may include transmitting a course approval message to the authenticated first mobile terminal; Determining, as a parent node, a node having the largest received signal strength among candidates of the selected parent node; Transmitting a location information message of the first mobile terminal; And transmitting a attendance confirmation message to the first mobile terminal to request to change the attendance mode.

The authenticating of the second mobile terminal may include selecting a parent node according to the received signal strength of the second mobile terminal; Transmitting the identification number of the second mobile terminal to the selected parent node; And comparing the identification number with a previously stored identification number.

In addition, the real-time attendance management sensor network method according to the present invention for this purpose, the real-time attendance management sensor network communication method, the problem type selection process of the first mobile terminal; An answer selection process according to the input of the first mobile terminal; Transmitting the answer; And displaying the scoring result of the answer on each of the first mobile terminals.

Preferably, the problem type includes a subjective or multiple choice, and the input is performed by adjusting the up, down, left, and right cursor keys provided in the first mobile terminal.

The real-time enrollment management sensor network communication method may include searching for mobile terminals existing in a radio wave coverage area of a fixed node and delivering a notice to a plurality of searched mobile terminals.

In addition, in response to the announcement, the method may include transmitting a questionnaire response, receiving a result of the questionnaire response from the plurality of mobile terminals, and configuring a screen for the result.

According to various embodiments of the present disclosure, there is an effect of enabling real-time location recognition based on fast and accurate location recognition technology in a mobile sensor network including mobile terminals held by numerous students or instructors.

According to various embodiments of the present disclosure, by using the acquired location awareness table, response data for a problem may be transmitted by using an automatic attendance management system based on real-time location recognition in a classroom and an asynchronous message transmission technique having high reliability. It also has the effect of providing services to check and manage learners' immediate learning results or survey results.

Accordingly, according to various embodiments of the present disclosure, there is also an effect that can provide various application services of the wireless sensor network by using asynchronous message transmission technology having a relatively high reliability based on the location information.

1 is a block diagram showing a real-time attendance management sensor network system according to an embodiment of the present invention,
2 is a block diagram showing a real-time attendance management sensor network system according to another embodiment of the present invention;
3 is a block diagram illustrating a first mobile terminal 130 according to an embodiment of the present invention.
4 is a block diagram illustrating a second mobile terminal 140 according to an embodiment of the present invention.
5 is a block diagram illustrating a gateway 110 according to an embodiment of the present invention.
6 is a block diagram illustrating a fixed node 120 according to an embodiment of the present invention.
7 is a flowchart illustrating a real-time course management sensor network method according to an embodiment of the present invention;
8 is a flowchart illustrating a one-way problem response method 700 of the real-time attendance management sensor network method according to an embodiment of the present invention;
9 is a flowchart illustrating a bidirectional problem response method 800 of a real-time attendance management sensor network method according to an embodiment of the present invention;
10 is a detailed exemplary view showing in detail the first mobile terminal (130A, 130B) for student possession consisting of an LCD and buttons,
FIG. 11 is an exemplary diagram illustrating a message capable of responding to the first mobile terminals 130A and 130B of FIG. 10.
12 is a flow diagram for delivering announcements between a plurality of specific mobile terminals and performing remote surveys.

Hereinafter, a real-time attendance management sensor network system and method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The same reference numerals are used for the same members in FIGS. 1 to 10.

The basic principle of the present invention is that a plurality of first and second mobile terminals perform bidirectional communication by relaying a gateway.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The same reference numerals are used for the same members in FIGS. 1 to 10.

1 is a block diagram showing a real-time attendance management sensor network system according to an embodiment of the present invention, Figure 2 is a block diagram showing a real-time attendance management sensor network system according to another embodiment of the present invention.

First, referring to FIG. 1, the real-time attendance management sensor network system 100 according to an exemplary embodiment of the present invention may be configured to perform two-way wireless communication with a plurality of first mobile terminals 130 and first mobile terminals 130. 2 mobile terminal 140, and the first mobile terminal 130 and the second mobile terminal 140 is automatically authenticated to relay the two-way wireless communication, the web server required for learning at the request of the second mobile terminal 140 B) the gateway 110 for transmitting the learning material to the first mobile terminal 130 and the second mobile terminal 140 in real time.

Referring to the operation of the real-time attendance management sensor network system according to an embodiment of the present invention configured as shown in Figure 1 as follows.

First, the plurality of first mobile terminals 130 performs two-way wireless communication with the second mobile terminal 140 via the gateway 110.

In detail, the gateway 110 provided in the unit space a may automatically recognize the positions of the plurality of first mobile terminals 130 and the second mobile terminals 140.

For example, the gateway 110 may detect a distance or a location through received signal strength indications (RSSI) of the first mobile terminal 130 and the second mobile terminal 140.

Preferably, the first mobile terminal 130 and the second mobile terminal 140 can also continuously receive the beacon message broadcasted by the gateway 110 to recognize the distance from the gateway 110 by the received signal strength.

Then, the gateway 110 may authenticate the detected mobile terminals, check the identification numbers (ID) of the authenticated mobile terminals, and perform attendance recording by determining that the user of the authenticated mobile terminal has attended.

That is, the plurality of mobile terminals 130 and 140 possessed by the instructor and the learners first select candidate parent nodes by a real-time location recognition method according to the received signal strength of the message transmitted by the gateway 110 through broadcast, and then the learner and the instructor are authenticated. After the process, the final parent node for data transmission and reception is selected.

On the other hand, such authentication process is performed only once the first time.

Thereafter, the instructor may download a web server or learning material necessary for learning from the gateway 110 connected to the second mobile terminal 140 and transmit the real time to the first mobile terminal 130 of the learner to increase the efficiency of the lecture. .

In this case, the gateway 110 also acts as a relay.

Preferably, since the first mobile terminal 130 is provided with an LED or a vibration motor, the specific second mobile terminal b may be called through the second mobile terminal 140.

For example, when a specific second mobile terminal b is called through the second mobile terminal 140, the provided vibration motor may be shaken or the LED blinks to recognize whether the user senses itself.

In addition, when the instructor questions the quiz through the second mobile terminal 140, the students can answer the quiz of the instructor using his first mobile terminal 130.

As such, when the first mobile terminal 130 and the second mobile terminal 140 are authenticated, real time location recognition and a problem response message transmission / reception operation are performed thereafter.

2 is a block diagram showing a real-time attendance management sensor network system according to another embodiment of the present invention.

Referring to FIG. 2, the real-time attendance management sensor network system 200 according to another embodiment of the present invention may include a plurality of first mobile terminals 130 and a second mobile terminal for bidirectional communication with the first mobile terminal 130. 140, the gateway 110 and the gateway 110 for performing bi-directional communication by automatically detecting the plurality of first mobile terminals 130 and the second mobile terminals 140 to collect, manage, and process data of each other. The fixed node 120 for extending the radio wave coverage of the, and the external server 150 for expanding the data collection, management, processing function of the gateway 110.

Referring to the real-time attendance management sensor network system 200 according to another embodiment of the present invention configured as shown in FIG. 2 in detail as follows.

First, it is assumed that the radio wave coverage of the gateway 110 is a region d.

 Since the radio wave coverage of the gateway 110 is a region d, other means are required to cover the radio wave shading area.

In another embodiment of the present invention, in consideration of the cost of the gateway, a fixed node 120 having a radio wave coverage c is provided in the radio shadow area to extend the radio wave coverage of the gateway 110.

Accordingly, the plurality of first mobile terminals 130 and the second mobile terminals 140 may perform bidirectional communication via the gateway 110 and the fixed node 120.

Meanwhile, the gateway 110 may further include an external server 150 to extend the functions of the gateway 110, such as managing collected data, downloading learning materials, and connecting to an external network.

Therefore, as described above in FIG. 1, when the gateway 110 authenticates the recognized mobile terminals through the gateway 110 and the fixed node 120, the gateway 110 determines that the user corresponding to the identification number of the authenticated mobile terminals is present. Perform the record.

The plurality of mobile terminals 130 and 140 possessed by the instructor and the participants first select candidates of the parent node by a real-time location recognition method according to the received signal strength of the message transmitted through the broadcast from the gateway 110 and the fixed node 120. After the course and the instructor certification process, the final parent node for data transmission and reception is selected.

Similarly, this authentication process is only performed once.

Thereafter, the instructor downloads a web server or learning material necessary for learning from the gateway 110 connected to the second mobile terminal 140 from the external server 150 and transmits the lecture to the first mobile terminal 130 of the student in real time. Can increase the efficiency.

Preferably, the first mobile terminal 130 is provided with an LED or a vibration motor, it is possible to call a specific first mobile terminal (b) through the second mobile terminal 140.

In addition, when the instructor questions the quiz through the second mobile terminal 140, the students can answer the quiz of the instructor using his first mobile terminal 130.

The answers written by the students through the first mobile terminal 130 may be stored and managed in the external server 150.

As described above, when the plurality of first and second mobile terminals 130 and 140 are authenticated, real time location recognition and a problem response message transmission / reception operation are performed thereafter.

3 is a block diagram illustrating a first mobile terminal 130 according to an embodiment of the present invention.

Referring to FIG. 3, the first mobile terminal 130 according to an embodiment of the present invention includes an LCD interface manager 131 for displaying information including a test question transmitted from the gateway 110, and for responding to a test question. Key input unit 132, the first data management unit 133 for transmitting the response, the first data storage unit 134 for storing the response, the first network management unit 135 for transmitting the response, and externally detected External interface management unit 136 including a vibration motor or LED to inform the user of the called information.

The first mobile terminal 130 periodically transmits location information to the parent node such as the fixed node 120 or the gateway 110 through the first network interface unit 137.

In addition, according to the problem type of the multiple choice or the subject received from the parent node, the data to be output through the LCD interface manager 131 is shown to the user through the LCD screen. Then, the user selects the desired multiple choice answer on the LCD screen through the key input unit 132 or, in the case of the short answer, writes the desired answer and then presses the OK button.

The key input unit 132 transmits the key data input by the user to the first data management unit 133 and stores it in the first data storage unit 134 as needed, or via the first network management unit 135. Transfer to the parent node through the interface unit 137.

In addition, according to the state of the first mobile terminal 130 or the data received from the parent node, the first data manager 133 is via an LED or vibration motor through the external interface manager 134 or through the LCD interface manager 131. The LCD screen informs the user of the necessary information.

Meanwhile, the sensor monitor 138 monitors data such as an acceleration sensor included in the first mobile terminal 130 and transmits the data to the parent node when necessary.

4 is a block diagram illustrating a second mobile terminal 140 according to an embodiment of the present invention.

Referring to FIG. 4, the second mobile terminal 140 according to an exemplary embodiment of the present invention receives lecture information from the gateway 110 and transmits and receives a communication interface 141 to periodically transmit location recognition information. And a second data processor 142 for processing information, and a second data storage unit 143 for storing information processed by the second data processor 142.

First, the second communication interface unit 141 of the second mobile terminal 140 transmits its own information for location recognition at regular intervals or receives information necessary for lectures from the gateway 110.

The second data processor 142 processes the transmitted and received data and stores the received data in the second data storage unit 143.

In addition, the second mobile terminal 140 may be mounted in the form of a USB dongle in a notebook or computer for convenience and supplied with necessary power.

5 is a block diagram illustrating a gateway 110 according to an embodiment of the present invention.

Referring to FIG. 5, the gateway 110 according to an exemplary embodiment of the present invention may include a network interface unit 111 for transmitting and receiving information from the first and second mobile terminals 130 and 140, and the first and second mobile terminals from the information. A second network manager 112 for separating location information of the 130 and 140 and asynchronous message data generated by an event, a third data manager 113 for collecting and processing information transmitted from the second network manager 112, And a third data storage unit 114 for storing the information processed by the third data management unit 113, wherein the third data management unit 113 configures the processed data as a web server screen. 115, and a dedicated program manager 116 for exclusive use in an external device.

The operation of the gateway 110 according to the embodiment of the present invention configured as shown in FIG. 5 is as follows.

First, the network interface 111 receives sensor network data from the fixed node 120 or the first and second mobile terminals 130 and 140.

Then, the second network manager 112 transmits the sensor network data to the third data manager 113.

The second network manager 112 periodically distinguishes and transmits the location information data transmitted from the network interface 111 and the asynchronous message data generated by the specific event to the third data manager 113.

 In addition, data used to manage the entire system environment such as a data transmission cycle transmitted from the external server 150 is also classified and transmitted to the third data manager 113.

Then, the third data management unit 113 processes the collected data, and manages the necessary data using the third data storage unit 114.

In addition, the third data manager 113 manages the location information table by using the location information data transmitted from the second network manager 112, collects data generated by a specific event, generates statistics, and derives the results. .

In addition, the system environment data transmitted from the external server 150 may be prepared in the form of the protocol required by the network interface unit 111 and transmitted to the second network management unit 112. 120 and the first and second mobile terminals 130 and 140.

Meanwhile, the result data to be transmitted to the external server 150 is again transmitted to the external server 150 through the second network manager 112 using the Ethernet communication network.

At this time, the second network manager 112 transmits the result data to the external server 150 via the wired / wireless network interface unit 117.

The third data manager 113 transmits the result of processing the collected data to the web server manager 115 or a dedicated program manager 116 capable of PUSH / PULL to configure a web server screen or may be used by a system dedicated program. Dedicated in the form of data is transmitted to the notebook 160 or smartphone 170 using a dedicated program.

Similarly, in this case, the data is transmitted to the devices 16 and 170 via the wired / wireless network interface unit 117.

In addition, the notebook 160 or the smart phone 170 is used to transmit data such as the attendance required for the lecture through a dedicated program or a web server page, and stores and utilizes the data storage unit 114 inside the gateway 110. .

At this time, the web server manager 115 and the dedicated program manager 116 are electrically connected to the external device through the external device connection unit 117 capable of wired or wireless networking.

6 is a block diagram illustrating a fixed node 120 according to an embodiment of the present invention.

Referring to FIG. 6, the fixed node 120 according to an exemplary embodiment of the present invention provides a second network interface unit to the fixed node 120 that is a parent node joined by the first and second mobile terminals 130 and 140. The location information is transmitted through 121.

Then, the third network manager 122 transmits the transmitted information to the fourth data manager 123.

Thereafter, the fourth data manager 123 stores the information in the fourth data storage 124 and transmits the information to the gateway 110 as well.

Similarly, asynchronous messages transmitted from the first and second mobile terminals 130 and 140 are received through the second network interface unit 121, and the corresponding data is transmitted to the gateway 110 again.

In addition, the sensor monitoring unit 125 for sensing environmental information included in the fixed node 120 is provided to monitor various sensors and transmit them to the unit gateway 110 when necessary.

7 is a flowchart illustrating a real-time attendance management sensor network method according to an embodiment of the present invention.

Referring to Figure 7, the operation of the real-time attendance management network method 700 according to an embodiment of the present invention is as follows.

In FIG. 7 to FIG. 9, there are a plurality of first mobile terminals 130 as student's mobile terminals. Here, two of the first mobile terminals 130 are shown to simplify the flow of signals transmitted and received to and from the gateway 110 and the fixed node 120. It was.

Also preferably, the second mobile terminal 140 refers to an instructor mobile terminal.

First, according to the lecture time, the external server 150 transmits information necessary for the lecture, such as the lecture number, the lecturer, and the attendance list, to the gateway 110 (S711).

Then, the gateway 110 transmits the attendance list to the fixed node 120 (S712).

Preferably, the gateway 110 serves as a server in a classroom consisting of one unit space, and serves as a gateway for delivering data to an external server 150 and a fixed node 120 for location recognition of mobile terminals. do.

The fixed node 120 or the gateway 110 constructs a list of attendance units consisting of identification numbers of the first mobile terminals 130A and 130B required for attendance (S713).

The attendance list may be transmitted to a plurality of fixed nodes 120 existing in the same unit space, so that the course approval process may be performed in each of the fixed nodes 120.

Thereafter, the activated first mobile terminals 130A and 130B set one of the gateway 110 and the fixed node 120 as candidates of the parent node based on the received signal strength (S714).

Here, the gateway 110 and the plurality of fixed nodes 120 broadcast a plurality of lecture beacon messages for a course approval process and location recognition of the first mobile terminals 130A and 130B at regular intervals during the lecture time.

In addition, a plurality of mobile terminals receive lecture beacon messages transmitted from the gateway 110 and the fixed node 120 after starting each, and, like the second mobile terminal 140, a plurality of mobile terminals receive a plurality of beacon messages according to reception strength. After selecting the parent node candidate, it transmits its identification number.

Then, the first mobile terminal (130A, 130B) transmits its identification number to the candidate of the parent node, and also the fixed node 120 receiving the identification number also transmits the received identification number to the gateway 110. (S715).

Then, the gateway 110 compares the identification numbers received from the first mobile terminals 130A and 130B with each other (S716), and determines the course attendance approval and disapproval (S717).

That is, the gateways 110 and the fixed nodes 120 that have received the IDs of the first and second mobile terminals 130A, 130B, and 140 are compared with the identification numbers of the current course attendance list to determine the course approval or disapproval. After that, the result is transmitted to the mobile terminal.

In a next step, the first mobile terminals 130A and 130B determine one parent node by checking received signal strength of nodes set as candidates of the parent node in step S714 (S718).

Thereafter, the first mobile terminal 130A or 130B transmits the location information message to its parent node, and the fixed node 120 which has received the location information message also transmits the location information message to the gateway 120 (S719). ).

Accordingly, the gateway 110 stores and manages the positions of the first mobile terminals 130A and 130B (S720).

An example of management here is that if there is no identification number approved for the course during the designated time, it is not recognized as attendance, or the identification number approved after the course start time is treated as late.

Preferably, the gateway 110 may transmit the received location information to the server 150 (S721).

The first mobile terminals 130A and 130B, which have been authenticated through such a series of processes, are displayed in the attendance mode at the same time as the attendance confirmation is displayed (S722).

Then, the gateway 110 constructs an attendance list (S723).

That is, the mobile terminal receiving the lecture registration approval message from the plurality of fixed nodes 120 and the unit gateway 110 selects the parent node according to the received signal strength, transfers the location information to its parent node, and then switches to the lecture mode. do.

The fixed node 120 receiving the location information from the mobile terminal transmits the location information message to the gateway 110 again. The gateway 110 constructs an attendance list using the received location information message, and delivers the message to the external server 150 again. Attendance list configured in the gateway 110 can be confirmed through a web service or a self-provided program provided by the gateway 110 using a networked laptop or smartphone.

On the other hand, the external server 150 stores and manages location recognition information of all mobile terminals, and can send a simple message such as an announcement to the mobile terminals when necessary.

The mobile terminal, which has already received the course approval and entered the course mode, does not need to go through the approval process for the lecture beacon message received afterwards, and merely performs the location recognition process (e).

The following describes the approval process of the second mobile terminal 140, which is an instructor mobile terminal.

Similarly, after the second mobile terminal 140 selects a parent node according to the received signal strength (S701), and transmits an identification number to the gateway 110 (S702), the gateway 110 authenticates it (S703) and the gateway. After transmitting the unit classroom management information including the IP to the second terminal 140 (S704), the second mobile terminal 140 sets the unit classroom management (S705).

That is, the gateway 110 receiving the identification number of the second mobile terminal 140 receives the IP address and the lecture information of the gateway 110 to be used as the external server 150 of the unit lecture room after confirming the instructor certification of the second mobile terminal. Transmit to 140.

Here, the second mobile terminal 140 is mounted on a laptop or computer to receive a lecture beacon message, selects a plurality of parent node candidates according to the reception strength, and transmits its identification number.

Therefore, the second mobile terminal 140 sets the environment required for the lecture on the mounted notebook or computer using the received lecture information.

As a result, the instructor ends the preparation necessary for the lecture by connecting the second mobile terminal 140 to the notebook without any other operation.

8 is a flowchart illustrating a one-way problem response method 800 of the real-time attendance management sensor network method according to an embodiment of the present invention.

Referring to FIG. 8, when a timer is started by pressing a problem response start button through a web service or a self-provided program provided by the gateway 110 (S810), the user presses any button of the first mobile terminal 130. The first mobile terminals 130A and B which are in the sleep mode are activated (S811), and a multiple choice or subjective question type mode suitable for the currently submitted problem is selected (S812).

Depending on the problem type mode selected, select the answer that can be selected in the multiple choice form on the LCD screen of the first mobile terminal 130A or B, or use the up, down, left, right, or select buttons on the keyboard for text input in the case of the short answer. After configuring the short answer, if the user selects Send, the problem response data is transmitted to the parent node (S813).

When the problem response time is over, the gateway 110 transmits the received problem response result data (S814). Accordingly, the first mobile terminals 130A and B constitute a response result screen (S815).

Finally, the gateway 110 statistically constructs a problem response result (S816).

Preferably, the response result screen configured in the gateway 110 may be confirmed through a web service provided by the gateway 110 or its own program using a laptop or a smart phone connected to a network. In addition, the result of the problem response is transmitted to the first mobile terminals (130A, B) it is possible to check the result through the LCD screen or LED, vibration motor.

9 is a flowchart illustrating a bidirectional problem response method 900 of a real-time attendance management sensor network method according to an embodiment of the present invention.

As in the unidirectional method of FIG. 7, when a timer is started by pressing a problem response start button through a web service or a self-provided program provided by the gateway 110 (S910), a plurality of fixed nodes 120 exist in the same unit space. The problem type of the multiple choice or the short answer is transmitted to (S911).

Unlike the unidirectional method, in which the user needs to configure and transmit the multiple choice or the direct answer, the bidirectional method transmits a problem type from the external server 150 first, and the first mobile terminal 130A or 130B automatically displays the multiple choice or subjective screen. It is composed.

The user presses any button of the first mobile terminal 130A, 130B to switch the sleep mode to the start mode (S912).

The activated first mobile terminal 130A or 130B receives a problem type message from its parent node, the gateway 110 or the fixed node 120 (S913).

Multiple fixed nodes 120 send problem type messages in broadcast.

According to the type of problem transmitted, selectable answers are displayed on the LCD screens of the first mobile terminals 130A and 130B, and a keyboard for inputting characters is displayed on the LCD screen.

After selecting a multiple-choice answer, or using the up, down, left, right, selection buttons in the keyboard to compose a short answer (S914), if you choose to send the problem response data is transmitted to the parent node (S915). When the problem response time ends (S916), the gateway 110 transmits the received problem response result data (S917).

Then, the first terminal 130A, 130B can check the response result (S918).

Finally, the gateway 110 configures statistics of the transmitted problem response result data (S919).

The statistics screen of the problem response result data configured in the gateway 110 may be confirmed through a web service or a self-provided program provided by the gateway 110 using a laptop or a smartphone connected to a network.

In addition, the result of the problem response is transmitted to the first mobile terminals 130A and 130B, and the result can be confirmed through the LCD screen or the LED or the vibration motor.

10 is a detailed exemplary view showing in detail the first mobile terminal (130A, 130B) for student possession consisting of an LCD and a button.

Referring to FIG. 10, the LCD screen displays a number that can be selected in the case of a multiple-choice problem or 'Yes' or 'No' in the case of a multiple-choice problem. do.

The user can operate the buttons as needed to compose and send or cancel the answer to the corresponding problem. In addition, LEDs and vibration motors can be used to inform the user of the current status intuitively.

FIG. 11 is an exemplary diagram illustrating a message capable of responding to the first mobile terminals 130A and 130B of FIG. 9.

Referring to FIG. 11, a letter or number is selected using a cursor provided in the first mobile terminals 130A and 130B of FIG. 10, and then transmitted to the second mobile terminal 140 by pressing a selection confirmation button.

12 is an exemplary diagram for delivering a notice to a plurality of specific mobile terminals and performing a remote survey. If it is necessary to deliver announcements to specific students, the gateways installed in each unit space (classroom or corridor, etc.) in a system in which a real-time sensor network infrastructure is established to find specific students at the server 150 or a specific gateway ( A search request is made to the mobile terminal 110A, 110B (S1201a, S1201b).

At this time, all the gateways 110A and 110B including the server 150 are connected to each other by Ethernet. The gateways 110A and 110B that have received the mobile terminal search requests S1201a and S1201b search for a specific mobile terminal in their unit space (S1202a and S1202b). After that, the result of the location of the mobile terminal is transmitted as a response message (S1203a, S1203b).

The announcement message is transmitted to each of the gateways 110A and 110B based on the received location result (S1104). The gateways 110A and 110B check the location of the mobile terminal in their area and transmit a notice message (S1205a and S1205b).

In addition, remote surveys are possible in the above system. If the announcement message requires a survey, the survey can be performed after the message is confirmed.

First, the specific mobile terminals 130A and 130B are notified that the survey starts, and accordingly, the user who uses the mobile terminal writes the survey response. The mobile terminal 130A and 130B transmits the completed questionnaire response (S1206a and S1206b). Each gateway 130A, 130B collects the respective results (S1207a, S1207b). The collected survey results are transmitted to a server (or a specific gateway) (S1208a, S1208b). Screens for the collected survey results are configured (S1209a and S1209b).

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill 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. This is possible.

Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of the appended claims as well as the appended claims.

110: gateway 120: fixed node
130: first mobile terminal 140: second mobile terminal
150: external server

Claims (12)

A plurality of first mobile terminals;
A second mobile terminal performing two-way wireless communication with the first mobile terminal; And
The first mobile terminal and the second mobile terminal are automatically authenticated to relay the two-way wireless communication, and the first mobile terminal and the second mobile terminal transmit a web server or learning material necessary for learning at the request of the second mobile terminal. Gateway to provide in real time to the terminal; including;
At least one of the plurality of first mobile terminals and the second mobile terminal,
For the automatic authentication, the candidate parent node is selected by a real-time location recognition method according to the received signal strength of the message transmitted from the gateway to the broadcast,
Real-time attendance management sensor network system, characterized in that the final parent node for data transmission and reception after the process of authenticating learners and instructors using the plurality of first mobile terminal and the second mobile terminal. The method of claim 1, wherein the first mobile terminal,
An LCD interface manager for displaying information including a test question transmitted from the gateway;
A key input unit for responding to the test question;
A first data manager for transmitting the response;
A first data storage for storing the response;
A first network manager for transmitting the response; And
Real-time course management sensor network system comprising a; external interface management unit including a vibration motor or LED to inform the user of the call information detected from the outside. The method of claim 1, wherein the second mobile terminal,
A communication interface unit for receiving lecture information from the gateway and periodically transmitting location recognition information;
A second data processor for processing information transmitted and received to and from the gateway; And
And a second data storage unit for storing the information processed by the second data processing unit.
Real-time attendance management sensor network system, characterized in that the power supply is mounted to an external device in the form of a USB dongle. The gateway according to claim 1,
A network interface unit configured to transmit and receive information from the first mobile terminal and the second mobile terminal;
A second network manager for dividing the information into location information of the first mobile terminal and the second mobile terminal and asynchronous message data generated by an event;
A third data manager for collecting and processing information transmitted from the second network manager; and
And a third data storage unit for storing the information processed by the third data management unit.
The third data manager comprises a web server manager for organizing the processed data into a web server screen; And
Real-time attendance management sensor network system comprising a; dedicated program management unit for use exclusively in the external device. The method according to any one of claims 1 to 4, wherein the real-time attendance management sensor network system,
At least one fixed node for extending a wireless communication area of the gateway; And
Real-time attendance management sensor network system further comprises an external server for extending the information providing function of the gateway. In the real-time course management sensor network method of a plurality of nodes relaying communication between the instructor and the student's mobile terminal,
Receiving lecture information and an attendance list;
Comparing the identification numbers of the attendance unit list with the identification numbers of the plurality of first mobile terminals and authenticating the identification numbers;
Confirming attendance of the authenticated first mobile terminal and managing whether the mobile terminal exists within a designated space for a designated time;
Authenticating the second mobile terminal; And
And transmitting lecture information to the second mobile terminal.
The process of authenticating the first mobile terminal and the process of authenticating the second mobile terminal,
Selecting a candidate parent node by a real-time location recognition method according to a received signal strength of a message transmitted from the plurality of nodes by broadcast;
Real-time attendance management sensor network method characterized in that the final parent node for data transmission and reception after the process of authenticating the learner and instructor using the plurality of first mobile terminal and the second mobile terminal. The method of claim 6, wherein the authenticating of the first mobile terminal comprises:
Starting the first mobile terminal;
Continuously receiving, by the first mobile terminal, a beacon message from the plurality of nodes;
Selecting a candidate of a parent node according to the received signal strength of the beacon message; And
Transmitting the identification number of the first mobile terminal; Real-time attendance management sensor network method comprising a. The process of claim 6, wherein
Transmitting a course approval message to the authenticated first mobile terminal;
Determining, as a parent node, a node having the largest received signal strength among candidates of the selected parent node;
Transmitting a location information message of the first mobile terminal; And
Real-time attendance management sensor network method comprising the step of requesting the attendance mode switch by transmitting an attendance confirmation message to the first mobile terminal. The method of claim 6, wherein the authenticating of the second mobile terminal comprises:
Selecting a parent node according to the received signal strength of the second mobile terminal;
Transmitting the identification number of the second mobile terminal to the selected parent node; And
And comparing the identification number with a previously stored identification number. delete delete delete

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