KR100514642B1 - System and Method for Remote-Controlling Camera Function through Radio Wave in Mobile Communication Terminal - Google Patents

Abstract

According to the present invention, when a user carries a portable communication device that is equipped with a small camera or is connected to a user, when the user is located in a specific area where the use of the camera is restricted, the portable communication device may be used without affecting basic communication functions. The present invention relates to a method and system for remotely controlling a camera function of a portable communication device using radio waves for automatically controlling a camera operation function in a synchronous manner of communication.

The camera function remote control system 200 of the portable communication device using the radio wave according to the present invention includes a mobile terminal 210, a wireless base station 220, a mobile communication switching center 230, a radio transmitter 240 and the like.

According to the present invention, it is possible to prevent illegal use of a camera function provided in a portable communication device that can provide a cause of information leakage. In addition, when the camera function of the portable communication device is controlled in a specific region where photography is prohibited, the camera function control can be continuously maintained even with the reset operation of the portable communication device.

Description

System and Method for Remote-Controlling Camera Function through Radio Wave in Mobile Communication Terminal}

The present invention relates to a method and system for remotely controlling a camera function of a portable communication device using radio waves. More specifically, when a user carries a portable communication device that is equipped with a small camera or is connected to a user, when the user is located in a specific area where the use of the camera is restricted, the portable communication device may be affected without affecting basic communication functions. The present invention relates to a method and system for remotely controlling a camera function of a portable communication device using radio waves for automatically controlling a camera operation function in a synchronous manner of communication.

As mobile phone technology is developed and its functions are diversified, the technology of mounting a small camera to a portable communication device such as a mobile phone or connecting it to photograph a subject and storing it as an image, and sometimes transferring the captured image via a communication network, has become common. It is becoming.

Such a function enables a user to use a still image, a video transmission, a video call, etc. in a portable communication device. However, when a user uses the portable communication device in a restricted area of use of a camera, a third party may not easily identify whether the user uses a communication function or photographs with a camera.

In the case of a camera mounted on a mobile phone, it is relatively easy to take a picture without being noticed by others, so a user carrying the portable communication device equipped with the camera may use a public place, a theater or a library, a church, a music room, or an art gallery. There is a problem of using a camera secretly in a place such as a bath, a research institute, or the like. Therefore, in the case of the portable communication device, a function for restricting the camera function is required in a specific region such as a region where photography is prohibited.

In the case of controlling some functions of the portable communication device in a public place, as described in Patent Application No. 10-1998-0034681, the ring tone output mode of the portable communication device is automatically switched to the vibration mode in a place requiring a quiet atmosphere. A way of doing so has been filed.

1 is a view schematically illustrating the concept of a portable communication device having a conventional mode switching function and a mode switching control system.

In the conventional mode switching control system 100, a radio wave generator 120 is installed at a doorway 110 in a public place such as a library, a theater, a lecture room, a conference room, a church, a temple, a music listening room, or an art gallery. The radio wave generator 120 is a mode switching signal generating means for generating radio waves in a frequency band that can be recognized by the portable communication device 130 such as a mobile phone. The wave generator 120 may be installed on the inner top or the outer top, the bottom, the side of the entrance 110, and the like.

In the conventional mode switching control system 100 configured as described above, when the user carrying the portable communication device 130 approaches the doorway 110, the radio wave generating apparatus 120 receives a mode switching signal of a specific frequency band. Will radiate. The portable communication device 130 receives the mode switch signal from the radio wave generator 120 and switches the ring tone output mode to the vibration mode based on the mode switch signal.

In the case of the conventional mode switching control system 100, the ring tone output of the portable communication device is automatically switched to the vibration mode in a specific public place where the radio wave generator 110 is installed, but the user is set to the vibration mode. In case of resetting by turning off the power and turning it on again, it returns to the original ringtone output mode. That is, even if the door 110 automatically controls the portable communication device 130, the reset operation returns to the original operation mode, so that the function of automatically controlling the device is useless.

Therefore, while controlling the camera function of the portable communication device in a specific area where photography is prohibited, there is a demand for a function of continuously maintaining the camera control despite the above-described reset operation.

In order to solve the above problems and to meet the above-mentioned demands, the present invention provides a mobile communication device equipped with a small camera or connected to a mobile communication device. The present invention provides a method and system for remotely controlling a camera function of a portable communication device using a radio wave which automatically controls the camera operation function in a synchronous manner of communication used by the portable communication device without affecting the basic communication function. have.

In order to achieve the above object, the present invention provides a system for remotely controlling a camera function using radio waves, and includes a small camera for photographing a subject, and receives a specific control signal for controlling a camera function through wireless communication. A portable communication device for stopping a function, and using the same frequency band as the portable communication device, generating a specific control signal for controlling the camera function in synchronization with the communication used in the portable communication device to wirelessly transmit to the portable communication device. It characterized in that it comprises a radio transmitter for transmitting.

In addition, according to another object of the present invention, a method of remotely and automatically control the camera function of a portable communication device equipped with a small camera by using radio waves, (a) the radio wave transmitter using a wireless communication network reference of the pilot signal for controlling camera functions Obtaining a reference timing synchronization to use as time; (b) the radio wave transmitter generating a transmission signal including the pilot signal for controlling the camera function and transmitting the signal wirelessly; (c) wirelessly receiving the transmission signal at the portable communication device; (d) searching for, by the portable communication device, a pilot signal for controlling the camera function among the transmitted signals; (e) driving, by the portable communication device, an attachment control timer according to the pilot signal for controlling a camera function; (f) the portable communication device stopping the camera operation function of the small camera.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

The portable communication device according to the present invention may be not only a mobile terminal such as a mobile phone, but also a PDA terminal, a Bluetooth module equipped terminal, a wireless LAN equipped terminal, and the embodiments of the present invention will be described using a code division multiple access method as an example. .

2 is a block diagram schematically showing the configuration of a camera function remote control system of a portable communication device using radio waves according to an embodiment of the present invention.

The camera function remote control system 200 according to the present invention includes a mobile terminal 210, a wireless base station 220, a mobile communication switching center 230, a radio transmitter 240 and the like.

The mobile terminal 210 has a small camera function for photographing a subject, and performs data communication including a phone call with a counterpart mobile terminal through a mobile communication network, and in particular, a specific control signal for controlling a camera function from the radio transmitter 240. Receipt will stop the camera operation. At this time, the specific control signal is a signal including a predetermined specific pseudo-random number (PN) sequence. Here, the small camera attached to the mobile terminal 210 may be built-in or may be an external type that can be attached and detached.

The wireless base station 220 includes a base station transmission system (BTS) 222, a base station controller (BSC) 224, a repeater (Cell Enhancer), and the like.

Here, the base station transmitter 222 is disposed in units of cells and transmits a call request generated from the mobile terminal 210 to the mobile communication switching center 230 or exists in a cell area under its control ( Location registration to determine the location of the 210 is performed. The base station transmitter 222 may obtain information such as latitude and longitude at which the base station transmitter 222 is located from a global positioning system (GPS) (not shown), and transmits the position information of the base station transmitter 222 to the downlink call channel. The system parameter message is transmitted to the mobile terminal 210. The mobile terminal 210 may register new location information by calculating the moving distance of the mobile terminal 210 using the location information of the base station transmitter 222 of the cell to which the mobile terminal 210 belongs.

Location registration is a processing procedure for informing the mobile communication switching center 230 of the location, status, identifier, slot period, and other features of the mobile terminal 210 through the base station transmitter 222. This is a procedure for effectively calling the mobile terminal 210 when the incoming call is to be set at 210. The location registration of the mobile terminal 210 may be performed when the mobile terminal 210 is turned on or off, when the mobile terminal 210 moves between the mobile communication switching centers 230, and the parameters of the mobile terminal 210. Is carried out when is changed.

The base station controller 224 controls and manages a plurality of base stations, and performs various functions required for radio call processing such as handoff. The base station controller 224 also transmits subscriber information of the location registered mobile terminal 210 to the mobile communication switching center 230.

The mobile communication switching center 230 has a control function for allowing the wireless base stations 220 to operate efficiently and an interworking function with an exchange of a public telephone network. When the mobile communication switching center 230 registers the location of the mobile terminal 210 through the wireless base station 220, the visitor location register (VLR) in the mobile communication switching center 230 is referred to as a 'VLR'. After temporarily storing the subscriber information of the mobile terminal 210 in the (234), and requests the location registration of the mobile terminal 210 to the Home Location Register (HLR: hereinafter referred to as 'HLR') 232 do.

Here, the HLR 232 is a database that stores a service profile regarding the subscriber information of the user of the mobile terminal 210, including a subscriber's telephone call, and a mobile identification number (MIN) of the mobile terminal 210. It has information about the Electronic Serial Number (ESN) and the type of service. The HLR 232 stores a subscriber information including information of the wireless base station 220 and the mobile switching center 230 in which the mobile terminal 210 is located. The mobile communication switching center 230 includes a control unit, a call path unit, and a peripheral device, and also has a charging data collection function for the mobile terminal 210.

The radio wave transmitter 240 wirelessly transmits a specific control signal to the mobile terminal using the same frequency band as that of a synchronous downlink channel (also referred to as forward) in which the radio base station 220 transmits a radio signal to the mobile terminal 210. In this way, all mobile devices of the synchronous method can receive a specific control signal. At this time, the radio wave transmitter 240 transmits by adding a specific PN sequence offset to the pilot channel of the downlink channel to control the mobile terminal of the synchronous method.

Of course, the radio wave transmitter 240 may transmit a specific control signal wirelessly to the portable communication device by using a separate frequency band without using the frequency band of the mobile communication network, and the portable communication device also radio wave transmitter 240 at this time The same frequency band as used shall be used.

The radio wave transmitter 240 is installed to cover a whole area such as a place where photography is prohibited, for example, a theater, a library, a church, a music listening room, an art gallery, a bath, a research institute, and the like. Therefore, when a user having a portable communication device equipped with a camera enters the above-mentioned place, a specific control signal is transmitted from the radio transmitter 240 to the portable communication device to stop the camera function of the portable communication device.

3 is a block diagram schematically illustrating an internal configuration of a portable communication device including the mobile terminal 210.

The mobile terminal 210 according to the embodiment of the present invention as a portable communication device includes an antenna 302, a modulator demodulator 304, a digital modulator demodulator 306, a signal processor 308, a voice processor 310, a speaker 312. ), A microphone 314, a keypad 316, a key input processing unit 318, a central processing unit 320, a liquid crystal processing unit 322, a display unit 324, an additional device processing unit 326, a camera 328, The data storage unit 330, the specific receiver 340, the searcher 350, and the like are configured.

The transceiver 304 transmits and receives a wireless signal through the antenna 302, and the modulator 306 functions to demodulate and amplify a received RF signal or to modulate and amplify a signal to be transmitted as an RF signal. In addition, the modulation / demodulation unit 306 functions to convert the received analog signal into a digital signal or convert the transmitted digital signal into an analog signal. The digital signal processor 308 encodes or decodes a voice signal, performs an equalization function to remove multipath noise, and performs an acoustic data processing function.

The voice processor 310 converts digital voice data into a voice signal or converts a voice signal into digital data. The speaker 312 outputs a voice signal as an audible sound, and the microphone 314 inputs a user's voice as a voice signal.

The keypad 316 is provided with a plurality of key buttons for inputting a number or selecting a menu for a telephone call, and the key input processing unit 318 inputs data corresponding to key input from the keypad 316. do.

The central processing unit 320 processes an operation related to a telephone call using a mobile communication network, and when a specific control signal is received through a pilot channel, the central processing unit 320 controls the accessory processing unit 326 to stop the operation of the camera 328. Perform the function. The specific control signal is a signal including a camera function control PN offset value. When the received pilot signal includes the camera function control PN offset, the central processing unit 320 deactivates the additional device processor 326. .

The central processing unit 320 has a mode state memory (not shown) internally to control activation or deactivation of the accessory processing unit 326. That is, the mode state memory is normally set to '1', which is an activation mode of the additional device processor 326. The deactivation mode of the attachment processing unit 326 is set to '0'.

The liquid crystal processing unit 322 converts digital data for displaying and outputting the operation status of the device on the liquid crystal screen into liquid crystal screen display data. The display unit 324 visually displays and outputs the operation status of the device for the user to recognize.

The additional device processing unit 326 is for processing a function additionally connected or mounted to the mobile terminal 210. For example, the additional device processing unit 326 may provide a data input / output processing function for an additional device having a digital camera function, a camcorder function, an audio function, and the like. Perform. The camera 328 may be mounted or connected inside the mobile terminal 210 in a configuration including a small lens, and inputs an image photographing a subject as data.

The data storage unit 330 temporarily stores wirelessly received data or temporarily stores image data input from the camera 328, and temporarily stores control data of the central processing unit 320.

The specific receiver 340 is used when the mobile terminal 210 receives a specific control signal from the radio wave transmitter 240 using an independent frequency band without using the frequency band of the mobile communication network. In this case, the frequency band of the radio transmitter 240 that transmits a specific control signal should be the same frequency band as the frequency band used by the specific receiver 340 of the mobile terminal 210.

The searcher 350 is a PN sequence phase search device that functions to detect a specific PN offset for controlling camera functions from a received signal received by the mobile terminal 210. That is, the searcher 350 performs an operation of despreading by multiplying the PN sequence value generated by the mobile terminal 210 with respect to the received signal, accumulating the output of the despreading during the integration period, and receiving PN sequence by the accumulated value. Calculate the detected energy according to the correlation. Subsequently, the searcher 350 compares the detected energy with the threshold energy, and reports the comparison result to the central processing unit 320. That is, the central processing unit 320 determines that a reliable PN sequence phase is captured when the detected energy is greater than the threshold energy.

4 is a block diagram schematically showing the internal configuration of the radio wave transmitter 240 in terms of functions.

The radio wave transmitter 240 illustrated in FIG. 4 includes a receiver 402, a modulator 404, a controller 406, an output power setting unit 408, a transmitter 410, a pilot channel generator 412, and a data memory. 414, input / output processing unit 416, input / output device 418, and the like.

The receiver 402 receives a signal of a frequency band used in the mobile communication network, and when the mobile terminal 210 uses a specific frequency band through the specific receiver 340, the receiver 402 receives a signal of a specific frequency band. Preferably, it is possible to receive not only the frequency band signals of all mobile communication systems transmitted from the wireless base station 220 but also the signals of the frequency bands allocated to all mobile communication service providers.

In addition, the receiver 402 converts a signal received from the base station 220 through a antenna into a baseband signal.

The modulator 404 converts the baseband signal transmitted from the receiver 402 into digital data and transmits the digital signal to the controller 406, or obtains a system time from the baseband signal to generate a pilot channel generator 412. To pass). Here, 'system time' means synchronization time information necessary for synchronization between the base station and the base station or the base station and the mobile terminal. In addition, the modulation / demodulation unit 404 performs a function of converting data for transmission into a transmission signal.

When the control unit 406 receives an arbitrary signal from the modulation and demodulation unit 404 as baseband data, the control unit 406 internally calculates a specific PN offset value, and based on this, calculates a pilot channel signal having the specific PN offset value. It generates and transmits to the mobile terminal 210.

The control unit 406 has its own internal memory, and has a specific PN offset value for controlling camera functions in the internal memory, a frequency band used for a base station and a neighboring base station currently located, and a PN offset value for a pilot channel in use in the frequency band. Store information such as the level of a received signal. These information are obtained from pilot channel signals, sync channel signals, and paging channel signals transmitted from the wireless base station 220 of the sector or cell in which the radio transmitter 240 is currently located.

The specific PN offset is preferably a camera function control PN offset that is not used at the base station among the 512 offsets and is specifically allocated only for camera function control.

 The PN offset value may be a value previously defined or stored in the internal memory by the controller 406 by performing an operation. That is, the specific PN offset is shifted by a predetermined value from the PN offset value used by the currently located wireless base station 220, and is calculated so as not to overlap with the PN offset values of all pilot channels that the mobile terminal 210 can receive. Can be.

The output power setting unit 408 is for manually adjusting the power strength of the pilot signal for controlling camera functions radiated through the antenna from the outside. Thus, the user can easily adjust the emission range of the pilot signal.

The transmitter 410 converts a baseband pilot signal transmitted from the pilot channel generator 412 into a signal of a communication frequency band so as to propagate through an antenna.

The pilot channel generator 412 receives the periodic signal generation control from the controller 406, generates a pilot channel signal having the specific PN offset value according to the system time from the modulator 404, and transmits the pilot channel signal to the transmitter 410. do.

The pilot signal for controlling camera functions transmitted to the transmitter 410 is made of an RF signal according to a frequency band of the mobile communication system in the transmitter 410 and is radiated to the air through an antenna.

The data memory 414 temporarily stores data, and also stores a CDMA protocol defined in IS-95 / IS-95A / B / C in a certain storage area. Accordingly, the controller 406 controls the receiver 402, the modulator 404, and the transmitter 410 according to the CDMA protocol stored in the data memory 414 to acquire synchronization through a pilot channel, and the sink channel. It acquires the configuration and time information of the system through the paging channel and processes the paging channel message through the paging channel.

The input / output device 418 includes a device for inputting data such as a keypad and a device for displaying an operation state. The input / output processing unit 416 inputs data corresponding to key input from the input / output device 418 or performs a function of converting data for output into an output signal.

Next, an operation of the camera function remote control system of the portable communication device using the radio wave configured as described above will be described in detail with reference to FIGS. 5 and 6.

The radio wave transmitter 240 according to the present invention is located in a cell area controlled by the wireless base station 220 and receives a downlink (forward) channel signal from the wireless base station 220.

Up to seven frequency channels (Frequency Assignment (FA)) can be operated in one cell, and these frequency channels are divided into three sectors each, resulting in one cell operating in total of 21 sub-cells. Each sector can operate up to 32 channels, and these channels are based on the CDMA method and are divided into a forward channel and a reverse channel according to the role of the channel, and a pilot in the forward channel. There are Synchronous, Paging, and Traffic Channels, and the Reverse Channel contains Access and Traffic Channels. Among these, pilot, synchronization, paging, and access channels except traffic channels are called overhead channels.

Each channel is controlled by a device called a channel element (CE). The channel element performs modulation / demodulation and multiplexing / demultiplexing of signals according to a predetermined code.

Each base station of the cellular system using the CDMA method transmits a carrier using a pilot channel. The mobile terminal uses the pilot carrier to find out the synchronization of the initial system from the base station by tracking the correct time, frequency, and phase signals. Always track the pilot signal.

The sync channel carries only one message, called a sync channel message, through which the mobile terminal is provided with system parameters.

The most important parameters here are the pilot PN, Sequence Timing and Paging Channel Data Rate of the base station in relation to the system time. A paging channel transfers information from a base station to a mobile terminal through a message. There are four important messages: overhead, paging, command and channel allocation. The cellular system configuration can be different for different environments, and information about the system configuration is conveyed through four overhead messages. These overhead messages include system parameter messages, connection parameter messages, neighbor base station list messages and CDMA channel list messages. An access channel is an overhead channel that is used to attempt a call from a terminal to a base station on a reverse channel.

5 is a flowchart illustrating a process of transmitting a specific control signal having a specific PN offset from the radio transmitter 240 in the method for remotely controlling a camera function of a portable communication device using radio waves according to the present invention.

First, when power is applied to the radio wave transmitter 240, the control unit 406 disables the driving of the output amplifier (not shown) in the transmitter 410. In addition, the controller 406 blocks the inter-base station synchronization signal (system time) transmitted from the modulation / demodulation unit 404 to the pilot channel generator 412. When the blocking of the output amplifier and the synchronization signal is completed, the controller 406 activates the receiver 402 to set the reception mode to receive the forward channel signal transmitted from the base station (S510).

With the reception mode set, the control unit 406 obtains pilot channel synchronization from the first channel operated by one specific mobile communication service provider according to the CDMA protocol, and also obtains system configuration and time information from the subsequent sink channel. A paging channel message is obtained through the paging channel (S520).

The control unit 406, from the neighbor list message (Neighbor List Message) of the paging channel message, the CDMA Channel List Message (CDMA Channel List Message), the frequency band currently used in the base station and the neighboring base station, and the pilot being used in the corresponding frequency band The PN offset value and the received signal level of the channel are extracted and stored in the internal memory of the controller 406 (S530).

At this time, if the CDMA channel number or the specific PN offset value is changed or a new frequency band is added, the controller 406 automatically updates and corrects the previously stored CDMA channel number and the specific PN offset value.

Subsequently, the control unit 406 transmits a system time that is a synchronization signal between base stations to the pilot channel generator 412 through the modulation / demodulation unit 404. Herein, the 'synchronization signal' refers to an inter-base station synchronization signal required for the mobile terminal 210 to perform handoff with the wireless base station 220. This synchronization signal (system time) is used as a reference time of the pilot signal for camera function control generated by the pilot channel generator 412 (S540).

In a state in which a synchronization criterion for the camera function control signal is established, the controller 406 stops the operation of the receiver 402, activates the function of the transmitter 410, and switches to a transmission mode (S550).

In addition, the controller 406 activates a control signal transmission timer (not shown) (S560). Here, the control signal transmission timer counts time for transmitting a pilot signal having a specific PN offset at a predetermined time, and is set such that, for example, a pilot signal having a specific PN offset is transmitted at an interval of 80 ms. The predetermined time may be set to be shorter than a camera function initialization time or an accessory device control time of the portable communication device.

When the control unit 406 reaches a predetermined time counted by the control signal transmission timer, that is, 80 ms (S570), the controller 406 generates a pilot signal having a specific PN offset value for controlling camera functions, and then wirelessly transmits the data through the transmitter 410. (S580).

6 is a flowchart illustrating a method for automatically remotely controlling a camera function of a portable communication device using radio waves according to the present invention.

The radio signal transmitted from the radio transmitter 240 is received by the antenna 302 of the mobile terminal 210. The received signal is input to the transceiver unit 304 through the antenna 302, demodulated through the modulation / demodulator 306, and converted into digital data by the digital signal processor 308. The received signal input to the transceiver unit 304 is applied to the demodulator 306 as well as to the searcher 350. The received signal includes a specific PN offset for camera function control. The searcher 350 searches for a specific PN offset in the received signal applied from the transceiver 304 (S610).

The central processing unit 320 activates the attachment processing unit 326 by setting the internal mode state memory '1' so that the user can use the camera 328 at normal times.

The searcher 350 multiplies the received signal by the PN sequence value to despread, calculates the detected energy according to the correlation of the received PN sequence, and compares the detected energy with the threshold energy. The searcher 350 transmits the comparison result to the CPU 320 (S620). In other words, when the detection result is large, the searcher 350 searches for a specific PN offset for controlling camera functions.

When the received PN signal is not a predetermined specific PN offset, the central processing unit 320 attempts to receive an overhead message corresponding to the pilot channel PN offset. If the radio transmitter 240 transmits a PN that is not duplicated with neighboring base stations for control, the mobile terminal 210 does not know this fact and recognizes it as a normal pilot signal transmitted from the base station and processes it. However, since the pilot PN offset to be transmitted from the radio transmitter 240 does not have an additional header message, the mobile terminal 210 recognizes this as a signal for controlling the camera. That is, even if a pilot signal of a certain intensity or more is received, if the overhead message information does not exist or if the currently detected pilot is not defined as a neighbor cell list in the overhead message received from a normal base station, the mobile terminal 210 controls the PN. It is recognized as an offset and processed.

When the central processing unit 320 receives a comparison result from the searcher 350 in which a specific control signal exists (S630), the central processing unit 320 drives an additional device control timer for operating the additional device (S640). The auxiliary device control timer is for maintaining the operation state while the additional device control timer counts the time when the central processing unit 320 activates or deactivates the additional device processing unit 326.

In addition, the central processing unit 320 drives the attachment control timer and stops the operation of the attachment processing unit 326 to deactivate it (S650). That is, the central processing unit 320 sets '1' in the internal mode memory to '0'.

The set counting time of the attachment control timer may basically count a time of 1 hour or more, or less. In addition, each time a specific control signal is received from the radio wave transmitter 240 of the attachment control timer, it is restarted.

The central processing unit 320 determines whether the counted time of the accessory control timer exceeds the set counting time, and when the set 1 hour is exceeded (S660), setting the internal mode state memory to '0' from ' Set to 1 'and activate the operation of the additional device processing unit 326 (S670).

On the other hand, activation of the attachment processing unit 326 may be provided with a specific key button for activating the camera function on the keypad 316 or a key input (for example, # 77) so that the user can perform the key input. .

According to an embodiment of the present invention, when a user carries a portable communication device that is equipped with a small camera or is connected to a user, when the user is located in a specific area where the use of the camera is restricted, the basic communication function is not affected. The camera operation function can be remotely controlled automatically by the synchronous method of communication used by the portable communication device. In addition, even if a user performs a reset operation of turning on and then turning off the mobile terminal 210, since a specific control signal is continuously transmitted from the radio wave transmitter 240, the camera function is continuously stopped.

In the above embodiment, the synchronous CDMA mobile communication system has been described as an example, but the same may be applied to the case of using a WLAN, Bluetooth, or a separate frequency band.

That is, in the case of a portable communication device having a wireless LAN communication function, in a coverage accommodated by one access point, a specific field for camera control is defined and inserted into a control signal of the access point, and the portable communication is performed. After the device receives this, it controls the operation of the additional device according to the field value.

In the communication using a separate frequency band, it is necessary to install a separate receiving device for the control frequency band. The service coverage of the radio wave transmitter 240 may be used by adjusting the output power, and the portable communication device receiving the control signal drives the camera operation control timer to the enabled state when receiving the control signal. The portable communication device receiving the control signal at a predetermined period maintains the enabled state of the camera operation prohibition function for a predetermined time by restarting the camera operation control timer. If the user leaves a specific area where the use of the camera function is prohibited, the portable communication device enables the camera function by disabling the camera operation prohibition function.

In addition, the portable communication device according to the present invention may be used in various wireless communication technologies such as mobile communication, wireless LAN, and Bluetooth, and two or more communication technologies may be applied and operated. In this case, information for controlling an additional device may be differently transmitted for each air interface due to various causes. That is, since the camera operation prohibition function may be differently enabled or disabled for each interface of the additional device, these results may be used in combination using an OR operation.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, it is possible to prevent illegal use of the camera function provided in the portable communication device that can provide the cause of information leakage.

In addition, when the camera function of the portable communication device is controlled in a specific region where photography is prohibited, the camera function control can be continuously maintained even with the reset operation of the portable communication device.

1 is a view schematically illustrating the concept of a portable communication device having a conventional mode switching function and a mode switching control system;

2 is a configuration diagram schematically showing the configuration of a camera function remote control system of a portable communication device using radio waves according to an embodiment of the present invention;

3 is a block diagram schematically illustrating an internal configuration of a portable communication device;

4 is a block diagram schematically showing the internal structure of the radio wave transmitter mainly in terms of functions;

5 is a flowchart illustrating a process of transmitting a specific control signal having a specific PN offset from a radio transmitter;

6 is a flowchart illustrating a method for automatically remotely controlling a camera function of a portable communication device using radio waves according to the present invention.

<Description of Symbols for Main Parts of Drawings>

100: mode switching control system 110: entrance

120: radio wave generator 200: camera function remote control system

210: mobile terminal 220: wireless base station

230: mobile communication switchboard 240: radio wave transmitter

302: antenna 304: transceiver

306: modulation and demodulation unit 308: digital signal processing unit

310: voice processing unit 320: central processing unit

326: additional device processing unit 328: camera

330: data storage unit 340: specific receiver

402: receiver 406: controller

408: output power setting unit 410: transmission unit

412: pilot channel generator 414: data memory

416: input and output processing unit 418: input and output device

Claims (22)

A system that remotely controls the camera function of a portable communication device using radio waves, A portable communication device having a small camera for photographing a subject, and stopping a camera operation function when receiving a specific control signal for controlling a camera function through wireless communication, and A radio wave transmitter using the same frequency band as that of the portable communication device, generating a specific control signal for controlling the camera function and transmitting it wirelessly to the portable communication device in synchronization with the communication time used in the portable communication device; A portable communication device communicates with the radio transmitter using a frequency band of a mobile communication network, and is a specific pseudo-random number for controlling camera functions that can be recognized as a signal for controlling a camera by a predefined procedure or a separate procedure from the radio transmitter. ) A remote control system for a camera function of a portable communication device using a radio wave, characterized in that when the sequence is received, the camera operation function is stopped. delete The method of claim 1, The radio transmitter transmits a control signal with a PN offset defined for camera control of the portable communication device or transmits a PN offset that is not duplicated based on neighbor base station information collected by the radio transmitter as a control signal. When the mobile terminal receives a signal having a defined PN offset or receives a valid pilot PN without additional information through an header message, the mobile terminal recognizes the signal as a control signal. Function remote control system. The method of claim 1, And the portable communication device and the radio transmitter communicate with each other using a wireless LAN. The method of claim 1, The portable communication device and the radio wave transmitter is a camera function remote control system of a portable communication device using a radio wave, characterized in that to communicate with each other using Bluetooth (Bluetooth). The method of claim 1, The portable communication device is a mobile terminal using a code division multiple access (CDMA) mobile communication network, The radio wave transmitter transmits a pilot signal including a specific PN offset for controlling camera functions to the mobile terminal in synchronization with a received signal received through a forward channel from a base station of the mobile communication network. Camera function remote control system. 7. The radio wave transmitter according to claim 1 or 6, wherein the radio transmitter A receiver which receives the signal of the same frequency band through an antenna and converts the received signal into a baseband signal; A demodulation unit for converting the baseband signal transmitted from the receiving unit into digital data or converting data for wireless transmission into a transmission signal, and obtaining synchronization time information from the baseband signal; When receiving an arbitrary signal as the baseband data, the operation is performed internally to calculate a specific PN offset value, to generate a pilot channel signal having a specific PN offset value and to control the function to transmit to the portable communication device Control unit; An output power setting unit for manually adjusting the power intensity of the pilot signal for controlling the camera function from the outside; A pilot channel generator configured to generate a pilot signal having the specific PN offset value according to the synchronization time information of the modulation / demodulation unit under periodic signal generation control from the controller; A transmitter for converting and transmitting the pilot signal generated by the pilot channel generator into a signal of a communication frequency band so as to propagate through the antenna; A data memory for temporarily storing data and storing a code division multiple access (CDMA) protocol in a predetermined storage area; And Input / output device including device for data input and device for displaying operation status Camera function remote control system of a portable communication device using a radio wave comprising a. The method of claim 6, wherein the mobile terminal Transmitting and receiving unit for transmitting and receiving a wireless signal to the antenna; A demodulation and demodulation unit configured to demodulate and amplify a received wireless signal or to modulate and amplify a signal to be transmitted as a wireless signal; A digital signal processor for converting a received analog signal into a digital signal or converting a transmitted digital signal into an analog signal, coding or decoding a voice signal, and performing an equalization function to remove multipath noise; A voice processor for converting digital voice data into voice signals or converting voice signals into digital data; A speaker for outputting an audio signal as an audible sound; A microphone for inputting a user's voice as a voice signal; A keypad having a plurality of key buttons for inputting a number or selecting a menu for a telephone call; A key input processing unit for inputting data corresponding to key input from the keypad; A central processing unit that processes an operation related to a telephone call using the mobile communication network and stops a camera operation function when the specific control signal including a PN offset value for controlling a camera function is received through a pilot channel; A liquid crystal processing unit for converting digital data into liquid crystal display data to display and output an operation state of the device on a liquid crystal display; A display unit which visually displays and outputs an operation state of the device so that a user can recognize the same; An additional device processing unit configured to perform a data input / output processing function for processing a function of the additional device additionally connected or mounted to the mobile terminal; The camera is a camera including a small lens mounted or connected to the inside of the mobile terminal, the camera for inputting an image photographing the subject as data; A data storage unit for temporarily storing wirelessly received data or temporarily storing image data input from the camera, and temporarily storing control data of the central processing unit; A specific receiver configured to receive the specific control signal when the mobile terminal uses a separate frequency band without using a frequency band of a mobile communication network; And Searcher performing a function of detecting a specific PN offset for controlling the camera function from the received signal received by the mobile terminal. Camera function remote control system of a portable communication device using a radio wave comprising a. The method of claim 7, wherein The control unit has its own internal memory, Information including a specific PN offset value for controlling the camera function in the internal memory, a frequency band used for a base station and an adjacent base station where the radio transmitter is located, a PN offset value for a pilot channel in use in the frequency band, and a level of a received signal; Save it. And the information is obtained from a pilot channel signal, a sync channel signal, and a paging channel signal transmitted from a base station of a sector or cell in which the radio transmitter is located. The method of claim 8, The central processing unit internally includes a mode state memory for controlling activation or deactivation of the attachment processing unit. The mode state memory is normally set to an activation mode of the attachment processing unit. When the CPU receives the specific control signal, the mode state memory sets the mode state memory to an inactive mode. Remote control system for camera functions of portable communication devices. The method of claim 8, The searcher is a PN sequence phase search device, and performs an operation of despreading the received signal by multiplying the PN sequence value generated in the mobile terminal. Computing the detection energy according to the correlation of the PN sequence, comparing the detected energy and the threshold energy, and reports the comparison result to the central processing unit, the camera function remote control system using a radio wave. The method of claim 9, The specific PN offset is a camera function control PN offset that is specifically allocated only for camera function control without being used by a base station among 512 offsets. The specific PN offset is shifted by a certain value from the PN offset value used by the base station that is in charge of the area where the radio transmitter is located, and calculated to not overlap with the PN offset values of all pilot channels that the mobile terminal can receive. Remote control system for a camera function of a portable communication device using radio waves, characterized in that. As a method of remotely and automatically controlling the camera function of a portable communication device equipped with a small camera using radio waves, (a) acquiring, by a radio transmitter, a reference timing synchronization to be used as a reference time of a pilot signal for controlling a camera function using a wireless communication network; (b) the radio wave transmitter generating a transmission signal including the pilot signal for controlling the camera function and transmitting the signal wirelessly; (c) wirelessly receiving the transmission signal at the portable communication device; (d) searching for, by the portable communication device, a pilot signal for controlling the camera function among the transmitted signals; (e) driving, by the portable communication device, an attachment control timer according to the pilot signal for controlling a camera function; (f) the portable communication device stopping the camera operation function of the small camera, In the step (a), the radio wave transmitter disables driving of the output amplifier in the transmitter, blocks the base station synchronization signal transmitted from the demodulator to the pilot channel generator, and forwards the signal transmitted from the base station of the mobile communication network. After enabling the receiver to receive the channel signal and set it to the receive mode, Acquire pilot channel synchronization from the first channel operated by one specific mobile communication service provider according to the code division multiple access (CDMA) protocol, obtain system configuration and time information from the subsequent sink channel, and use the paging channel to process paging channel messages. To obtain Received and received frequency bands used in base stations and neighboring base stations, pilot channel PN offset values used in the corresponding frequency bands from neighbor list messages and CDMA channel list messages in the paging channel messages. Remote control method for a camera function of a portable communication device using radio waves, characterized in that the signal level is extracted and stored in the internal memory. delete The method of claim 13, In step (b), the radio transmitter In a state in which a synchronization reference for the camera function control signal is established by transferring an inter-base station synchronization signal to be used as a reference time of the pilot signal for controlling the camera function to a pilot channel generator through a modulation / demodulation unit After stopping the operation of the receiver, activating the function of the transmitter to switch to the transmission mode, and activating the control signal transmission timer to reach a predetermined time counted by the control signal transmission timer, a pilot having a specific PN offset value for camera function control. Remote control method for a camera function of a portable communication device using a radio wave, characterized in that for generating a signal and transmitting it wirelessly through the transmitter. The method of claim 13, The control signal transmission timer counts time to transmit a pilot signal having a specific PN offset at a predetermined time, and is basically set so that a pilot signal having the specific PN offset is transmitted at a predetermined time interval. And the predetermined time is shorter than a camera function initialization time or an additional device control time of the portable communication device. The method of claim 13, The step (c) is a remote control method for a camera function of a portable communication device using radio waves, characterized in that the portable communication device wirelessly receives the transmission signal transmitted from the radio transmitter using Bluetooth communication. The method of claim 13, The step (c) is a remote control method for a camera function of a portable communication device using radio waves, characterized in that the portable communication device wirelessly receives the transmission signal transmitted from the radio wave transmitter (Wireless LAN). . The method of claim 13, wherein steps (c) and (d) The transmission signal is input to the transceiver unit through the antenna of the portable communication device as a reception signal, the reception signal is applied to the modulation and demodulation unit, and is supplied to the searcher, the received signal includes a specific PN offset for controlling the camera function, The searcher multiplies the received signal by the PN sequence value, despreads, calculates the detected energy according to the correlation of the received PN sequence, and compares it with the threshold energy to search for a specific PN offset in the received signal, Remote control method for a camera function of a portable communication device using a radio wave, characterized in that for transmitting the searched results to the central processing unit of the portable communication device. The method of claim 19, The central processing unit of the portable communication device determines that a specific PN offset for controlling the camera function is found when the detection energy is large, Remote control method for a camera function of a portable communication device using radio waves, characterized in that performing the step (e) and the step (f). The method of claim 20, The central processing unit of the portable communication device sets a mode for deactivating the accessory processing unit in an internal mode state memory to stop the camera function. And setting the additional device processor deactivation mode of the mode state memory to an activation mode when the setting time of the additional device control timer elapses. The method of claim 21, Activating or deactivating the attachment processing unit for the camera function may be selectively performed by a user's key input.