KR100792671B1 - Apparatus and method of control terminal function in wibro system - Google Patents

Abstract

A method and an apparatus for controlling terminal functions in a WiBro system are provided to bolster security by controlling some functions, which can be used for malicious purposes, when a WiBro terminal is located in a specific area such as a security zone. A WiBro system consists of base stations, a control system(500), and WiBro terminals. In case a WiBro terminal enters into a specific zone, the control system(500) outputs a control signal containing control information to control functions of the WiBro terminal. The control system(500) comprises a synchronous clock processing part(540), a control sequence creation part(530), an OFDMA signal processing part(520), and an RF signal processing part(510). The synchronous clock processing part(540) provides a clock to synchronize the control signal with a downlink signal transmitted to the WiBro terminal from a base station. The control sequence creation part(530) creates a control data sequence to control functions of the WiBro terminal. The OFDMA signal processing part(520) executes baseband processing for the created control data sequence according to an OFDMA scheme. The RF signal processing part(510) upconverts the baseband-processed control data sequence and transmits it through an antenna.

Description

Apparatus and method of control terminal function in wibro system

1 is a block diagram illustrating a WiBro network to which the present invention is applied.

2 is a view for explaining a WiBro system according to a preferred embodiment of the present invention.

3 is a block diagram for briefly explaining a control system according to a preferred embodiment of the present invention;

4 is a block diagram illustrating in more detail a control system according to a preferred embodiment of the present invention.

5 is a flowchart illustrating a method of transmitting a control signal for controlling the function of a WiBro terminal according to a preferred embodiment of the present invention.

6 is a block diagram illustrating a WiBro terminal according to a preferred embodiment of the present invention.

7 is a flowchart illustrating a method of controlling a terminal function of a WiBro system according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: WiBro terminal 110: keypad unit

120: display unit 130; Sound output

140: USB connection unit 150: camera unit

160: storage unit 170: wireless connection unit

180: central processing unit 190: security processing unit

200: base station 500: control system

510: RF signal processor 520: OFDMA signal processor

530: control sequence generator 540: synchronous clock processor

551: memory 552: specific sequence generator

553: QAM encoder 554: S / P converter

555: IFFT processor 556: interference processor

557: P / S conversion unit 558: control unit

559: clock unit 560: D / A conversion unit

561: carrier generation unit 562: antenna connection unit

563 switching unit 564 amplifying unit

565: function processing unit 566: frequency synthesis unit

The present invention relates to a method and apparatus for controlling a terminal function of a WiBro system.

As computer, electronic, and communication technologies have made rapid progress, various wireless communication services using wireless networks have been provided. Accordingly, a service provided by a mobile communication system using a wireless communication network is developing not only a voice service but also a multimedia communication service for transmitting data such as circuit data, packet data, and the like.

Recently, IMT-2000 (International Mobile Telecommunication 2000) (eg, CDMA (Code Division Multiple Access) 2000 1X, 3X, EV-DO), a third generation mobile communication system that has been standardized by ITU-R due to the development of information communication. And WCDMA (WideBand CDMA) are commercially available. IMT-2000 is a mobile communication system that aims to implement various application services by combining global direct roaming including personal mobility and service mobility, same call quality as wired telephone, high speed packet data service and wired / wireless network. As a result, as well as improving existing voice and WAP service quality, various multimedia services (AOD, VOD, etc.) may be provided at a higher speed.

However, the mobile communication system has a limitation in providing the high-speed wireless Internet because the base station construction cost is high, the wireless Internet usage fee is high, and the mobile communication terminal has a small screen size.

In addition, Wireless Local Area Network (WLAN) technology has limitations in providing public services due to problems such as radio wave interference and narrow coverage, thereby ensuring portability and mobility, and providing high-speed wireless Internet service at low rates. WiBro (Wireless Broadband Internet), a high-speed portable Internet service that can be used, is emerging. Such WiBro is defined as 'IEEE 802.16e'.

WiBro service uses WiBro terminals (laptop, PDA, Handheld PC, etc.) to access the Internet in the indoor and outdoor stationary environment and mobile environment of walking speed and low to medium speed, and can use various information and contents. In addition, the WiBro system provides mobility of 60 km / h per hour, a downlink transmission rate of 24.8 Mbps, but an uplink transmission rate of 5.2 Mbps, which is an IP (Internet Protocol) based wireless data system having up-down asymmetric transmission characteristics.

WiBro terminal not only supports the wireless Internet function, but also supports various additional functions such as a camera function and a portable storage function.

However, there is no present method for controlling the security function of the WiBro terminal, for example, the function of the WiBro terminal in a secure area where information leakage is concerned.

Accordingly, the present invention has been made to solve the above problems, and when the WiBro terminal of the WiBro system enters a specific area (security area), the terminal function control method of the WiBro system that can control the function of the WiBro terminal and The object is to provide the device.

According to an aspect of the present invention, a WiBro system includes a plurality of base stations connecting a WiBro terminal connected to a core network for providing a wireless Internet service, and controlling a function of the WiBro terminal in a specific area. A control system for transmitting a control signal including control information, setting function mode information corresponding to the control information, and when a control signal is received from the control system, setting a function mode corresponding to the control information included in the control signal. It includes a plurality of WiBro terminal.

The control system according to the present invention includes a synchronization clock processor for providing a clock for synchronizing a control signal with a downlink signal for transmitting a signal to a WiBro terminal by a base station, and generating a control data sequence for controlling the function of the WiBro terminal. A control sequence generation unit, an OFDMA signal processor for performing baseband processing of the control data sequence according to the OFDMA scheme, and an RF signal processing unit for up-converting the baseband processed control data sequence to a high frequency to be transmitted through an antenna.

The control sequence generation unit according to the present invention generates a control data sequence using an undefined data value among identification data for identifying a base station in a WiBro system.

The control system according to the present invention includes a memory unit for storing control data values and frequency offset information, a sequence generator for generating a control data sequence based on the control data values stored in the memory unit, and a generated control data sequence in parallel. A signal processor for converting a scheme, loading a parallel control data sequence on a subcarrier to output simultaneously, and outputting an analog control signal, a carrier generator for generating a carrier according to frequency offset information stored in a memory, and control A plurality of frequency synthesizers for up-converting the signal to a high frequency based on a carrier wave, a function controller for adjusting an output frequency of a control signal according to a manufacturer or installation environment of a WiBro terminal, and a downlink period of a base station Switching to output the control signal to the antenna during Contains wealth.

The control system according to the present invention includes an antenna connection unit for physically connecting an antenna and outputting a control signal, an amplifying unit for amplifying the control signal to a predetermined size, and a synchronization of the downlink signal and the control signal in the downlink period to match. A clock unit for providing a clock and a control unit for controlling each unit to control the control signal is sent during the downlink period.

The amplifier according to the present invention is characterized in that when the bias voltage is applied from the control unit, the control signal is transmitted, and when the bias voltage is not applied, the output of the control signal is stopped.

The signal processor according to the present invention comprises an encoder for encoding a control data sequence, an S / P converter for converting a control data sequence in a parallel manner, and a Fourier transform for parallel control data sequence to generate a subcarrier and simultaneously output the same. An IFFT processing unit, an interference processing unit for minimizing interference between each control data sequence, a P / S converter for converting the control data sequence in a serial manner, and a D / A converter for converting the control data sequence in an analog manner. .

The control signal according to the present invention is generated by modulating undefined control data out of 1016 data values used to identify a base station with a pilot offset frequency.

The WiBro terminal according to the present invention includes a wireless connection unit for wirelessly connecting with a base station, a keypad unit having a plurality of keys and providing a key signal according to a user's operation, and a control included in a control signal received from a control system. A storage unit for storing function mode information corresponding to the information, a wireless Internet function for connecting to the core network through a wireless connection unit at the request of a user, a camera function for capturing an image, or a portable storage function for exchanging data with a USB memory device; And a central processor configured to set a function mode corresponding to the control information when a control signal is received from the control system.

The WiBro terminal according to the present invention includes a camera unit for capturing an image and providing image information, a USB connection unit connected to a USB memory through a USB interface, a display unit for outputting image information or image information, and outputting sound information. The apparatus further includes a sound output unit.

The central processing unit according to the present invention includes a security processing unit for setting function mode information corresponding to the control information included in the control signal when the control signal is received.

The security processing unit according to the present invention checks whether a control signal is received through the wireless connection unit when a key signal is received from the keypad unit in an idle state not connected to the base station through the wireless connection unit.

The security processing unit according to the present invention, when the function mode information corresponding to the control information included in the control signal received in the idle state is an OFF information of the function requested by the user through the keypad unit, an alarm message indicating that the function cannot be provided. Output and set the function to the OFF mode.

According to another aspect of the present invention, there is provided a method for controlling a terminal function of a WiBro system, the control system transmitting a control signal including control information for controlling the functions of a plurality of WiBro terminals, and whether the WiBro terminal receives a control signal. And a step of setting, by the WiBro terminal, a function mode corresponding to the control information included in the control signal received from the control system.

The transmitting of the control signal according to the present invention may include generating, by the control system, a control data sequence using an undefined data value among identification data for identifying a base station in a WiBro system, and paralleling the control data sequence. Converting and loading a parallel control data sequence on a subcarrier to be output simultaneously, outputting an analog control signal, generating a carrier according to preset frequency offset information, and generating a control signal based on a carrier Up-converting the control signal; adjusting the output frequency of the control signal to a frequency used according to the manufacturer or installation environment of the WiBro terminal; and outputting the control signal to the antenna during the downlink period of the base station. .

The transmitting of the control signal according to the present invention may include: checking whether an output signal is applied from a manager of the control system, a) if so, and transmitting the control signal during the downlink period, and b) if not, the control signal. It does not include sending a step.

The step of confirming whether or not the control signal according to the present invention is received, checks whether the current state of the WiBro terminal is in the idle state, c) if not in the idle state, and whether the control signal is received from the control system, d) if idle, checking whether there is a function request from the user, and if there is a function request, checking whether a control signal is received from the control system.

The step of confirming whether or not the control signal according to the present invention is received, if the WiBro terminal has a function request from the user in the idle state, the function mode information corresponding to the control information included in the received control signal of the function requested by the user If the information is OFF, the method may further include outputting an alarm message indicating that the function cannot be provided.

In the setting of the function mode according to the present invention, the WiBro terminal sets the camera function ON / OFF mode or the portable storage function ON / OFF mode according to the function mode information corresponding to the control information.

Hereinafter, a method and a device for controlling a terminal function of a WiBro system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a WiBro network to which the present invention is applied.

As shown in FIG. 1, the WiBro terminal 100 wirelessly communicates with the base station 200, and the base station 200 is connected to the core network of the operator by wire.

WiBro terminal 100 may correspond to a terminal such as a laptop, PDA, smart phone.

In the core network of the WiBro network, as in the case of a wireless LAN, an AAA (Authentication Authorization Accounting) server 300 for user and terminal authentication is connected, and a DHCP server for allocating an IP address to the WiBro terminal 100 is connected.

When the WiBro terminal 100 enters the service area of the base station 200, the WiBro terminal 100 accesses the core network through the base station 200 and provides the WiBro service to the subscriber.

2 is a view for explaining a WiBro system according to a preferred embodiment of the present invention.

As shown in Figure 2, the WiBro system according to the present invention is provided with a control system 500 for controlling the function of the WiBro terminal 100 in the security area.

The control system 500 transmits a control signal for controlling a function to the WiBro terminal 100 entering a predetermined area (eg, a conference room, a laboratory, etc.) that is determined as a security area.

2 illustrates an example in which a radius of a service area of one base station 200 is formed in kilometers according to an environment, and a security area is narrower than a radius of a service area of the base station 200. If the radius is wider than the radius of the base station 200 may be similarly configured.

In addition, when the security area is a very large area (for example, the entire factory), the control system 500 may be installed by setting an entrance area in which subscribers carry and move the WiBro terminal 100 as the security area. In this case, the control system 500 may separately transmit the OFF control signal for turning off the function of the WiBro terminal 100 and the ON control signal for turning on the function.

The control system 500 transmits a control signal including control information for controlling a function of the WiBro terminal 100 (for example, a camera function, a portable storage function, and the like) in the security area.

The control information of the control signal transmitted by the control system 500 may include function OFF information for turning off the function of the terminal 100 and function ON information for turning on the function of the terminal 100. In addition, the control information of the control signal transmitted by the control system 500 is a sound output function that can damage the surrounding people in a public facility such as a library, that is, the function of the sound output unit for outputting the sound of the WiBro terminal 100 This can be the sound ON / OFF information to turn ON or OFF.

3 is a block diagram for briefly explaining a control system according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the control system 500 according to the present invention includes a synchronization clock processor 540, an orthogonal frequency division modulation / multiplexing access (OFDMA) signal processor 530, a control sequence generator 520, and an RF. The signal processor 510 is included.

The synchronization clock processor 540 generates / provides a synchronization clock for synchronizing a downlink signal and a control signal transmitted from the base station 200 to the WiBro terminal 100.

The control sequence generator 530 generates a control sequence, that is, a control signal, by using an undefined spare signal among downlink signals transmitted from the base station 200 to the WiBro terminal 100.

The control sequence generator 530 generates a control signal using, for example, a pilot signal transmitted from the base station 200 to the WiBro terminal 100.

That is, the control sequence generation unit 530 modulates a control signal by modulating an unused specific data value (hereinafter, “control data”) among 1016 data values used for identifying the base station 200 in the WiBro system to a pilot offset frequency. Create

The OFDMA signal processor 520 performs baseband processing of the control signal generated according to the OFDMA scheme. That is, the OFDMA signal processor performs baseband processing for transmitting the control signal according to the OFDMA method, which is a signal processing method of the WiBro system.

The RF signal processor 510 up-converts the baseband processed control signal to an RF frequency, amplifies the signal to a predetermined size, and transmits the same through an antenna.

4 is a block diagram for explaining in more detail the control system according to an embodiment of the present invention.

Referring to FIG. 4, the control system 500 according to the present invention includes a memory unit 551, a specific sequence generator 552, a quadrature amplitude modulation (QAM) encoder 553, and a series / parallel (S / P). Converter 554, inverse fast fourier tramsform (IFFT) processor 555, interference processor 556, P / S converter 557, controller 558, clock 559, D / A (digital / analog conversion unit 560, carrier generation unit 561, a plurality of frequency synthesizing unit 566, a plurality of function processing unit 565, amplifying unit 564, switching unit 564 and antenna connection unit 562 Include.

The memory unit 551 stores unused control data values among the data values used to identify the base station 200 and frequency offset information for generating a pilot carrier of the OFDMA scheme.

The clock unit 559 provides a clock to the carrier generator 561 or the controller 558 so that the downlink signal and the control signal of the base station 200 are synchronized with each other.

The specific sequence generator 552 generates a control data sequence for generating a control signal by using the control data value stored in the memory unit 551.

The specific sequence generator 552 generates a 48-bit control data sequence.

The QAM encoder 553 encodes the control data sequence according to a quadrature amplitude modulation (Qadrature Amplifier Modulation) scheme.

The S / P converter 554 converts the serial control data sequence into a parallel control data sequence.

The IFFT processor 555 performs Fourier transform on the control data sequence in order to simultaneously transmit the parallel control data sequences, thereby generating respective subcarriers.

The IFFT processor 555 simultaneously loads the control data sequence on the generated subcarrier.

The interference processor 556 minimizes interference between control data sequences output from the IFFT processor 555. That is, the interference processor 556 generates a Cylcic Prefix and adds it to the control data sequence.

The P / S converter 557 converts the parallel control data into a serial control data sequence.

The D / A converter 560 converts a digital control data sequence into an analog control signal.

The carrier generator 561 generates a specific carrier offset frequency by using the frequency offset information stored in the memory unit.

The carrier generation unit 561 generates a carrier offset frequency so that the analog control signal is up-converted.

The plurality of frequency converters 566 up-converts the control signals analog-converted by the D / A converter 560 to RF signals using the carriers generated by the carrier generator 561.

Each function processor 565 adjusts the output frequency of the control signal according to the manufacturer (factory automation: FA) of the WiBro terminal 100 or the use frequency for each installation environment.

The amplifier 564 amplifies the voltage of the control signal up-converted into the RF signal to a predetermined magnitude.

The amplifier 564 turns on / off the transmission of the control signal in accordance with the bias voltage input from the manager. That is, the manager applies a bias voltage to the amplifier 564 when the control signal needs to be transmitted, and if the control signal is not transmitted, the manager does not apply the bias voltage to the amplifier 564. So that control signals are not sent.

The switching unit 564 switches so that the control signal is not transmitted during the uplink period of the WiBro terminal 100 and switches so that the control signal is transmitted during the downlink period.

The antenna connection unit 562 may be physically connected to the antenna for transmitting the control signal so that the control signal is transmitted through the antenna.

In addition, the controller 558 controls each component of the control system 500 so that the control signal is transmitted during the downlink period of the WiBro terminal 100.

In addition, the controller 558 controls to simultaneously transmit a plurality of control signals corresponding to output frequencies that vary according to the manufacturer (factory automation (FA)) or installation environment of the WiBro terminal 100 according to a manager's operation.

5 is a flowchart illustrating a method of transmitting a control signal for controlling the function of a WiBro terminal according to a preferred embodiment of the present invention.

Referring to FIG. 5, the control system 500 for controlling the function of the WiBro terminal 100 in a secure area includes an unused control data value and an OFDMA pilot carrier of data values used to identify the base station 200. Set frequency offset information for generating a (S 100).

The control system 500 generates a control data sequence using the control data value (S110).

The control system 500 encodes the generated control data sequence and converts the generated control data sequence in a parallel manner (S 120), performs a Fourier transform on the control data sequence, and simultaneously generates and outputs each subcarrier to transmit the control data sequence (S). 130).

The control system 500 converts the parallel control data sequences into a serial method and then converts them into an analog control signal (S 140).

In addition, the control system 500 generates a specific carrier offset frequency to transmit the control signal, and up-converts the RF frequency (S 150).

In addition, the control system 500 adjusts the output frequency such that the control signal is output according to the manufacturer (factory automation: FA) of the WiBro terminal 100 or the use frequency for each installation environment (S 160).

The control system 500 amplifies the voltage of the up-converted control signal to a predetermined magnitude (S 170).

Then, the control system 500 checks whether the control signal transmission is set from the manager, that is, whether or not the output signal is applied from the manager (S 180), and if applied, outputs the control signal through the antenna (S 190). If not applied, the control signal is not output (S 200).

At this time, the control system 500 transmits a control signal during the downlink period of the WiBro system, and does not transmit the control signal during the uplink period.

6 is a block diagram illustrating a WiBro terminal according to a preferred embodiment of the present invention.

Referring to FIG. 6, the WiBro terminal 100 according to the present invention includes a wireless connection unit 170, a storage unit 160, a keypad unit 110, a display unit 120, a sound output unit 130, and a camera unit ( 150, a USB connection unit 140, and a central processing unit 180, and the central processing unit 180 includes a security processing unit 190.

In the following detailed description of the present invention, for example, a case in which the WiBro terminal 100 supports a camera function and a portable storage function in addition to the wireless Internet access function will be described. can do.

The wireless access unit 170 is wirelessly connected to the base station 200 and connected to the core network. The wireless access unit 170 receives a signal from the base station 200 or the control system 500 or transmits a signal generated to provide a wireless Internet service. 200).

The storage unit 160 has a function mode corresponding to program information for providing a wireless Internet service, program information for providing a camera function, and a portable storage function, and control information included in a control signal received from the control system 500. The information is stored.

The function mode information stored in the storage 160 may correspond to ON / OFF mode information of a camera function, ON / OFF mode information of a portable storage function, and the like.

The keypad 110 includes a plurality of keys and provides a key signal according to a user's key manipulation to the central processing unit 180. That is, a user manipulates keys of the keypad 110 to use a wireless Internet service, a camera function, and a portable storage function.

The display unit 120 displays image information according to data received through the core network, that is, image information for providing a wireless Internet service or image information captured by the camera unit 150.

The sound output unit 140 outputs sound (voice) information for providing a wireless Internet service.

The camera unit 150 captures an image of the front surface of the photographing lens and provides image information.

The USB connection unit 140 is connected to a USB storage device (eg, USB memory) through a USB interface.

The central processing unit 180 connects to the core network through the wireless connection unit 170 at the request of the user, and provides the wireless Internet service to the user. When the camera function is requested, the central processing unit 180 controls the camera unit 150 to display images It provides a camera function to capture an image and store the image information in the storage unit 160 or transmit it to the core network.

Meanwhile, when the portable storage function is requested, the central processing unit 180 stores data in a USB memory connected through the USB connection unit 140 or reads data from the USB memory and stores the data in the storage unit.

The security processor 190 of the central processing unit 180 determines whether a control signal is received, and when the control signal is received, sets the function mode corresponding to the control information included in the control signal.

For example, if the function mode information corresponding to the control information of the received control signal is the camera OFF mode information, the security processor 190 turns off the camera function.

In addition, if the function mode information corresponding to the control information of the received control signal is the portable storage OFF mode information, the security processing unit 190 turns off the portable storage function to prevent data exchange with the USB memory connected through the USB connection unit 1400. Let's do it.

The WiBro terminal 100 may move in the state connected to the core network through the base station 200 to enter the security area, or may enter the security area in the idle state not connected to the core network.

First, when the WiBro terminal 100 enters a secure area in a state in which the WiBro terminal 100 is connected to the core network, since the WiBro terminal 100 is receiving a downlink signal through the downlink period, the control signal from the control system 500 is controlled. Receive

On the other hand, when the WiBro terminal 100 enters the security area in the idle state, since it does not receive the round link signal from the base station 200, the camera function and the portable storage function cannot be controlled.

Therefore, when the WiBro terminal 100 operates the keypad unit 110 of the user in an idle state not connected to the base station 200, that is, when the security processing unit 190 receives a key signal from the keypad unit 110, The wireless connection 170 is activated to check whether a control signal is received from the control system 500.

That is, when the WiBro terminal 100 does not access the core network and the user requests a camera function or a portable storage function, a control signal is received from the control system 500 to check whether the user enters the security area. Check whether or not.

When a control signal is received from the control system 500, the security processing unit of the WiBro terminal 100 sets a function mode corresponding to the control information included in the control signal.

For example, when a camera function is requested from a user, the security processing unit of the WiBro terminal 100 checks whether a control signal is received. When the control signal is received, the control information included in the control signal is the camera function OFF mode information. In this case, the camera function is turned off, and the camera enters the security area through the display unit 120 or the sound output unit 130 and outputs an alarm message indicating that the camera function cannot be used.

FIG. 7 is a flowchart illustrating a method of controlling a terminal function of a WiBro system according to an exemplary embodiment of the present invention.

Referring to FIG. 7, the administrator installs the control system 500 at a position set as a security area (S300).

The control system 500 transmits a control signal to the WiBro terminal 100 entering the set security area (S 310).

The control system 500 may transmit a control signal including function OFF information for turning off the function of the WiBro terminal 100 and function ON information for turning on the function of the terminal 100.

In addition, the control system 500 uses control data values that are not used among the data values used to identify the base station 200 in the WiBro system and frequency offset information for generating a pilot carrier of the OFDMA scheme. It may generate an included control signal.

WiBro terminal 100 checks whether the current state is the idle state (S 320).

If the WiBro terminal 100 is currently connected to the core network, the WiBro terminal 100 enters a security area and checks whether a control signal is received from the control system 500 (S330).

The WiBro terminal 100 sets a function mode corresponding to the control information included in the control signal received from the control system 500 (S 340).

On the other hand, if the WiBro terminal 100 is in the idle state, it checks whether or not the user's operation. That is, the WiBro terminal 100 checks whether there is a request for a camera function or a portable storage function from the user (S 350).

If there is a request from the user, the WiBro terminal 100 checks whether a control signal is received from the control system 500 (S360).

If the WiBro terminal 100 does not receive a control signal, that is, if the state has not entered the security area, the WiBro terminal 100 provides a function requested by the user (S370).

When the control signal is received, the WiBro terminal 100 sets a function mode corresponding to the control information included in the control signal (S380).

At this time, the WiBro terminal 100 enters the security area and outputs an alarm message indicating that it cannot provide the requested function.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the present invention, and such modifications and modifications belong to the appended claims.

As described above, according to the present invention, when the WiBro terminal of the WiBro system enters a specific area (security area), the security can be improved by controlling a function that can be used for malicious purposes.

In addition, by controlling the sound output function of the WiBro terminal within a specific area, to ensure courtesy in public facilities such as libraries.

Claims (19)

In the WiBro system, A plurality of base stations connecting wirelessly connected WiBro terminals to a core network providing a wireless Internet service; A control system for transmitting a control signal including control information for controlling a function of the WiBro terminal to a specific area; And And a plurality of WiBro terminals for setting function mode information corresponding to control information and setting a function mode corresponding to control information included in the control signal when the control signal is received from the control system. The control system, A synchronization clock processor configured to provide a clock for synchronizing a downlink signal for transmitting a signal to the WiBro terminal with the control signal by the base station; A control sequence generator for generating a control data sequence for controlling a function of the WiBro terminal; An OFDMA signal processor for performing baseband processing on the control data sequence according to an OFDMA scheme; And And an RF signal processor configured to up-convert the baseband processed control data sequence to a high frequency signal and transmit the RF signal through an antenna. delete The method of claim 1, wherein the control sequence generator, And generating the control data sequence using an undefined data value among identification data for identifying a base station in the WiBro system. The method of claim 1, wherein the control system, A memory unit for storing control data values and frequency offset information; A sequence generator generating a control data sequence based on the control data value stored in the memory unit; A signal processor for converting the generated control data sequence into a parallel scheme, loading the parallel control data sequence on a subcarrier to simultaneously output the control data sequence, and outputting an analog control signal; A carrier generation unit generating a carrier according to the frequency offset information stored in the memory unit; A plurality of frequency synthesizers configured to up-convert the control signal to a high frequency based on the carrier; A function controller configured to adjust an output frequency of the control signal to be used according to a manufacturer or installation environment of the WiBro terminal; And And a switching unit for switching the control signal to be output to the antenna during the downlink period of the base station. The method of claim 4, wherein the control system, An antenna connection unit physically connected to the antenna and outputting the control signal; An amplifier for amplifying the control signal to a predetermined size; A clock unit configured to provide a clock to synchronize the downlink signal in the downlink period with the control signal; And And a control unit for controlling the respective units to control the control signal to be transmitted during the downlink period. The method of claim 5, wherein the amplifying unit, And transmit a control signal when a bias voltage is applied from the controller, and stop transmitting the control signal when the bias voltage is not applied. The method of claim 4, wherein the signal processing unit, An encoder for encoding the control data sequence; An S / P converter converting the control data sequence in a parallel manner; An IFFT processor for performing Fourier transform of the parallel control data sequence to generate a subcarrier and simultaneously output the subcarrier; An interference processor which minimizes interference between the control data sequences; A P / S converter converting the control data sequence in a serial manner; And And a D / A converter converting the control data sequence into an analog method. The method of claim 1, wherein the control signal, WiBro system generated by modulating the undefined control data of the 1016 data values used to identify the base station to a pilot offset frequency. The method of claim 1, wherein the WiBro terminal, A wireless connection unit for wirelessly connecting with the base station; A keypad unit having a plurality of keys and providing a key signal according to a user's operation; A storage unit which stores function mode information corresponding to the control information included in the control signal received from the control system; At the request of the user, a wireless Internet function for connecting to the core network through the wireless connection, a camera function for capturing an image, or a portable storage function for exchanging data with a USB memory, and receiving the control signal from the control system. And a central processor configured to set a function mode corresponding to the control information. The method of claim 9, wherein the WiBro terminal, A camera unit for capturing an image to provide image information; A USB connection unit connected to a USB memory through a USB interface; A display unit for outputting image information or image information; And And a sound output unit for outputting sound information. The method of claim 9, wherein the central processing unit, And a security processor configured to set function mode information corresponding to the control information included in the control signal when the control signal is received. The method of claim 11, wherein the security processing unit, And when the key signal is received from the keypad in an idle state not connected to the base station through the wireless connection, checking whether the control signal is received through the wireless connection. The method of claim 12, wherein the security processing unit, If the function mode information corresponding to the control information included in the control signal received in the idle state is OFF information of a function requested by the user through the keypad, an alarm message indicating that the function cannot be provided is output, and WiBro system to set the function to OFF mode. In the terminal function control method of the WiBro system, Transmitting, by the control system, a control signal including control information for controlling the functions of the plurality of WiBro terminals to a specific area; Confirming, by the WiBro terminal, whether the control signal is received; And setting, by the WiBro terminal, a function mode corresponding to the control information included in the control signal received from the control system. Sending the control signal, Generating, by the control system, a control data sequence using an undefined data value among identification data for identifying a base station in the WiBro system; Converting the control data sequence into a parallel scheme, loading the control data sequence into a subcarrier to simultaneously output the parallel data, and outputting an analog control signal; Generating a carrier according to preset frequency offset information; Upconverting the control signal to a high frequency based on the carrier; Adjusting an output frequency of the control signal according to a use frequency according to each manufacturer or installation environment of the WiBro terminal; And And outputting the control signal to the antenna during the downlink period of the base station. delete The method of claim 14, wherein the transmitting of the control signal comprises: Check whether the output signal is applied from the manager of the control system, a) if applied, sends the control signal during the downlink period, b) if not authorized, comprising the step of not transmitting the control signal. The method of claim 14, wherein checking whether the control signal is received comprises: The WiBro terminal determines whether the current state is an idle state, c) if not in the idle state, confirms whether the control signal is received from the control system, d) checking whether there is a function request from a user in the idle state, and if there is the function request, checking whether the control signal is received from the control system. The method of claim 17, When the WiBro terminal receives a function request from the user in the idle state, it is notified that the function cannot be provided if the function mode information corresponding to the control information included in the received control signal is OFF information of the function requested by the user. The terminal function control method of the WiBro system further comprising the step of outputting an alarm message. The method of claim 14, wherein the setting of the function mode comprises: And controlling the camera function ON / OFF mode or the portable storage function ON / OFF mode according to the function mode information corresponding to the control information.

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