JP4275662B2 - Mobile communication terminal - Google Patents

Description

  The present invention relates to a portable communication terminal, and more particularly to a portable communication terminal having a remote control function for remotely controlling an electronic device such as a television or an air conditioner.

As a conventional terminal of this type, one disclosed in Patent Document 1 is known. This conventional technique has a plurality of buttons respectively corresponding to a plurality of electronic devices, and stores a plurality of remote control codes respectively corresponding to the plurality of electronic devices in a memory. When a button corresponding to a desired electronic device among the plurality of buttons is pressed, a remote control code corresponding to the electronic device is read from the memory, and infrared rays corresponding to the read remote control code are transmitted. As a result, the desired electronic device can be remotely controlled by the mobile communication terminal.
JP 2003-78977 A [H04Q 9/00, F24F 11/02, H04N 5/00]

    However, in the prior art, only electronic devices registered in advance can be remotely controlled, but if they are registered devices, they can be easily remotely controlled even if they are electronic devices in another person's house.

  Therefore, a main object of the present invention is to provide a portable communication terminal capable of remotely controlling an electronic device existing under a desired position condition.

  The mobile communication terminal according to the invention of claim 1 is a communication means (14) for executing communication processing with a base station (ST1, ST2,...) And information for detecting identification information of a base station that can communicate with the communication means. Detection means (S1), registration means (S45) for registering identification information detected by the information detection means under a desired position condition, identification information and registration means detected by the information detection means after registration processing by the registration means Discriminating means (S13) for discriminating whether or not the matching condition is satisfied with the identification information registered by the electronic device (50, 80, around) when the discrimination result of the discriminating means is affirmative 82,...), And a display unit (S63) for displaying an operation screen for remotely controlling the electronic device detected by the device detection unit.

  Communication processing with the base station is performed by communication means. The identification information of the base station that can communicate with the communication means is detected by the information detection means. The identification information detected by the information detection means under the desired position condition is registered by the registration means. The discriminating unit discriminates whether or not a matching condition is satisfied between the identification information detected by the information detecting unit after the registration processing by the registration unit and the identification information registered by the registration unit. If this determination result is affirmative, an electronic device existing in the vicinity is detected by the device detection means. An operation screen for remotely controlling the electronic device detected by the device detection means is displayed by the display means.

  In other words, the operation screen for remotely controlling the electronic devices existing around the mobile communication terminal satisfies the matching condition between the identification information detected by the information detection means and the identification information registered by the registration means. When displayed. Since the registration means registers identification information detected under a desired position condition, the operation screen is displayed when the mobile communication terminal is in the desired position condition. As a result, an electronic device existing under a desired position condition can be remotely controlled by the mobile communication terminal.

  The portable communication terminal according to the invention of claim 2 is dependent on claim 1, the base station repeatedly transmits a PN (Pseudo Noise) signal, and the information detecting means pays attention to the PN signal transmitted from the base station.

  The plurality of PN signals respectively transmitted from the plurality of base stations have different frequencies. By paying attention to such a PN signal, a communicable base station can be identified.

  A mobile communication terminal according to the invention of claim 3 is dependent on claim 1 or 2, wherein the electronic device has a wireless tag (66) for storing device identification information, and the device detection means is a device identification stored in the wireless tag. A reading means (32) for reading information is included.

  The electronic device includes a wireless tag that stores device identification information, and the device detection means detects the electronic device existing in the surroundings by reading the device identification information stored in the wireless tag by the reading device. Can do.

  A portable communication terminal according to the invention of claim 4 is dependent on any one of claims 1 to 3, and is created by a creation means (S53) for creating a control signal suitable for an electronic device detected by the device detection means, and created by the creation means Transmitting means (S57) for transmitting the received control signal to the processor (60) of the electronic device detected by the device detecting means, and response device detecting means for detecting the electronic device in response to the control signal transmitted by the transmitting means (S59) is further provided, and the display unit changes the display mode of the operation screen according to the detection result of the response device detection unit.

  A control signal suitable for the electronic device detected by the device detection means is created by the creation means. The transmission means transmits the control signal created by the creation means to the processor of the electronic device detected by the device detection means. The electronic device responding to the control signal transmitted by the transmission unit is detected by the response device detection unit. The display unit changes the display mode of the operation screen according to the detection result of the response device detection unit.

  A control signal suitable for the detected electronic device is generated, and the generated control signal is transmitted to the processor of the detected electronic device. Thereby, an electronic device in an on state or a standby state is detected. The operation screen displayed by the display means is a screen for remotely controlling the electronic device in the on state or the standby state. With such an operation screen, it is possible to accurately remotely control electronic devices existing in the vicinity.

  Note that when the electronic device is in an off state, communication with the processor of the electronic device is impossible, whereas communication with a wireless tag included in the electronic device is possible even when the electronic device is in an off state. Accordingly, in the invention of claim 4 that is dependent on claim 3, first, the electronic device is detected by communication with the wireless tag, a control signal suitable for the detected electronic device is generated, and the generated control signal is detected. It is sent to the processor of the electronic equipment that has been released. In this way, when an electronic device in the off state changes to the on state by detecting the electronic device in the off state and transmitting a control signal to the processor of the electronic device in the off state, the electronic device Can be accurately controlled remotely.

  The portable communication terminal according to the invention of claim 5 is dependent on claim 4, and the transmission means repeatedly transmits the control signal.

  By repeatedly transmitting the control signal, it is possible to cope with a change in the state of the electronic device.

  A portable communication terminal according to the invention of claim 6 is dependent on claim 4 or 5, and obtains device control information for remotely controlling the electronic device detected by the device detection device using the communication device. S51), and the creation means creates a control signal based on the device control information acquired by the acquisition means.

  Device control information for remotely controlling the electronic device detected by the device detection unit is acquired by the acquisition unit using the communication unit. The creation means creates a control signal based on the device control information acquired by the acquisition means.

  By acquiring device control information using the communication means, it is possible to remotely control electronic devices other than pre-registered devices.

  The device control program according to the invention of claim 7 communicates with a processor (26) of a portable communication terminal (10) having communication means (14) for executing communication processing with a base station (ST1, ST2,...). Information detection step (S1) for detecting identification information of a base station that can communicate by means, registration step (S45) for registering identification information detected by the information detection step under a desired position condition, registration processing by registration step A determination step (S13) for determining whether or not a matching condition is satisfied between the identification information detected by the information detection step and the identification information registered by the registration step, and the determination result of the determination step is positive A device detection step (S55 to S61) for detecting an electronic device present in the surroundings, and a display step (S for displaying an operation screen for remotely controlling the electronic device detected by the device detection step (S 63) is executed.

  According to the present invention, an electronic device existing under a desired position condition can be remotely controlled with a mobile communication terminal.

  The above object, other objects, features and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

  Referring to FIG. 1, a mobile communication terminal 10 of this embodiment includes a telephone processing circuit 14 that realizes a call function in cooperation with a mobile communication system. Note that the call function is always activated as long as the power is turned on. When a dial operation is performed by the call operation panel 36, the CPU 26 instructs the telephone processing circuit 14 to perform call processing. The telephone processing circuit 14 executes a calling process, and as a result, a calling signal is transmitted to a desired call partner. With the start of the calling process, the state of the mobile communication terminal 10 shifts from the non-calling state to the calling attempt state.

  On the other hand, when a call signal is received through the antenna 12, the telephone processing circuit 14 generates a voice message notifying the incoming call. With the start of such incoming call notification processing, the state of the mobile communication terminal 10 shifts from the non-call state to the call trial state. The generated voice message passes through the amplifier 18 and is output from the speaker 20.

  If no off-hook operation is performed on the incoming notification, the call connection will fail. The state of the mobile communication terminal 10 returns from the call trial state to the non-call state. On the other hand, if an off-hook operation is performed for the incoming call notification, the call connection is successful. The state of the mobile communication terminal 10 shifts from a call trial state to a call ready state.

  When the call-ready state is entered, the uttered voice captured by the microphone 16 is emitted from the antenna 12 through the modulation processing by the telephone processing circuit 14. The emitted speech voice is transmitted toward the communication terminal of the other party. The received voice sent from the other party is received by the antenna 12 and demodulated by the telephone processing circuit 14. The demodulated received voice passes through the amplifier 18 and is output from the speaker 20. When one speaker performs an off-hook operation, the call connection is interrupted. The state of the mobile communication terminal 10 shifts from a call ready state to a non-call state.

  The telephone processing circuit 14 also realizes a communication function for communicating with a server (not shown) on the Internet in cooperation with the mobile communication system.

  By the way, the portable communication terminal 10 also functions as a remote controller for remotely controlling electronic devices such as a television and an air conditioner with infrared rays at a pre-registered place such as a home. Whether or not the current position corresponds to the registered place is determined with reference to a PN (Pseudo Noise) signal. For identification of electronic devices, an IC tag and an IC tag reader are used.

  Here, the PN signal is a signal transmitted from a base station for mobile communication, and its value (frequency) differs for each base station. Further, the intensity of the detected PN signal attenuates as the current position moves away from the base station. Therefore, the detected PN signal whose intensity is less than the threshold is excluded, and the value of the remaining PN signal, that is, the value of the PN signal whose intensity is equal to or greater than the threshold (hereinafter referred to as “PN value”) is used for position determination. .

  First, regarding the position determination function, the CPU 26 periodically executes a PN detection process for detecting a PN signal. When a PN registration operation is performed via the operation panel 36 at a certain location, the CPU 26 registers the PN value detected at that time in the register 30 r formed in the flash memory 30. Thereafter, by comparing the PN value periodically detected with the PN value registered in the register 30r, it is possible to determine at any time whether or not the current position matches the registered place.

  Specifically, referring to FIG. 4, there are four base stations ST1 to ST4 in area E1 including home H1 and friend's house H2. “18”, “21”, “22”, and “25” are assigned as PN values to the base stations ST1 to ST4, respectively. If portable communication terminal 10 is located at home H1, the result shown in FIG. 5A, that is, the value (PN) and the intensity of each of the four PN signals are obtained by PN detection. If the mobile communication terminal 10 is located at the friend's house H2, the result of the PN detection is as shown in FIG.

  The PN detection result is temporarily stored in the RAM 28 and overwritten with a new detection result. Accordingly, the RAM 28 always holds the latest PN value.

  When the PN registration operation is performed at home H1, the CPU 26 discards the PN whose intensity is less than the threshold value (= 3) among the four PNs shown in FIG. The PNs, that is, “21”, “25”, and “22” are registered in the register 30r as the PN value “PN1” at the home H1 (see FIG. 3).

  Thereafter, every time the remote control mode is selected, the CPU 26 determines whether or not the latest PN value in the RAM 28 matches the PN value in the register 30r, and activates the remote control function when it is determined that they match. . Here, “match” means that the combination of PN values completely matches between the RAM 28 side and the register 30r side. In other words, any PN value in the RAM 28 exists in the register 30r and any PN value in the register 30r. The value also exists in the RAM 28.

  Therefore, when the remote control mode is selected at home H1, it is determined that the PN matches (see FIGS. 3 and 5A), and the remote control function is activated. On the other hand, if the remote control mode is selected at the friend's house H2, “18” out of “18,” “21” and “22” in the RAM 28 does not exist in the register 30r, and therefore PN mismatch (see FIGS. 3 and 5B). ) And the remote control function is not activated.

  Next, regarding the remote control function, the mobile communication terminal 10 further includes an infrared light receiving / emitting circuit 38 that receives and emits infrared light, and an IC tag reader 32 for reading identification information from an IC tag embedded in an electronic device. On the other hand, an electronic device to be controlled needs to include a similar infrared light receiving and emitting circuit and an IC tag in which identification information (for example, manufacturer name, model name, model number, etc.) of the device is stored. A configuration of a television which is an example of such a device is shown in FIG.

  Referring to FIG. 2, television 50 includes an infrared light receiving / emitting circuit 62 and an IC tag 66. The IC tag 66 includes a ROM 66a. The ROM 66a stores identification information of the television 50. When the transmission / reception circuit 66b receives a request signal from the IC tag reader 32 by the antenna 66c, the transmission / reception circuit 66b transmits the identification information stored in the ROM 66a to the IC tag reader 32 from the antenna 66c. The transmitted identification information is received by the IC tag reader 32 through the antenna 34. Note that the remote control function pauses when the main power of the television 50 is off, but the IC tag 66 operates even when the main power of the television 50 is off.

  When the IC tag reader 32 reads the identification information from the IC tag 66 in this way, the CPU 26 of the mobile communication terminal 10 can transmit a remote control signal (infrared code) suitable for the television 50. The infrared light receiving / emitting circuit 62 gives the CPU 60 the infrared code transmitted from the mobile communication terminal 10. The CPU 60 returns a response signal through the infrared light receiving and emitting circuit 62 and gives a command corresponding to the given infrared code to the tuner 54.

  The response signal returned from the infrared light receiving / emitting circuit 62 is received by the infrared light receiving / emitting circuit 38 and is given to the CPU 26. If the response signal cannot be received immediately after transmitting the infrared code (for example, within 1 second), the CPU 26 of the mobile communication terminal 10 excludes the television 50 from the control target.

  The tuner 54 selects a channel instructed by the CPU 60 and supplies a broadcast signal of the selected channel to the signal processing circuit 56. The signal processing circuit 56 converts a given broadcast signal into a program video signal and a program audio signal, and adjusts the level of the program audio signal according to a command from the CPU 26. The program video signal and the program audio signal are output to the TV monitor 58.

  Next, a procedure for remotely controlling the television 50 by operating the mobile communication terminal 10 at home H1 will be described. With reference to FIG. 6, in addition to television 50, lighting 80 and air conditioner 82 are installed at home H1. Each of the lighting 80 and the air conditioner 82 also has an IC tag, and can be controlled by the mobile communication terminal 10. However, for the air conditioner 82, the main power supply is in an off state, and the infrared code cannot be transmitted / received.

  Referring to FIGS. 1 and 2, when an operation for calling a main menu screen is performed by operation panel 36 of mobile communication terminal 10, the main menu screen shown in FIG. 7A is displayed on LCD monitor 24. When “remote control” is selected on the operation panel 36 here, it is determined whether or not PN registration has already been performed. If it has not been registered, a PN registration guidance screen shown in FIG. 7B is displayed on the LCD monitor 24. Is done.

  When “Yes” is selected on the PN registration guidance screen, device detection processing is executed. In the device detection process, first, the IC tag reader 32 transmits a request signal for requesting the IC tag 66 to transmit identification information. If there is a device having the IC tag 66 within the reach of the request signal, the IC tag reader 32 can receive the attribute information returned from the IC tag 66.

  When the identification information is received by the IC tag reader 32, the CPU 26 registers the received identification information in the device list in the RAM 28 (see FIG. 8). Then, the remote control application corresponding to the registered identification information is activated. In the example of FIG. 6, the TV 50, the illumination 80, and the air conditioner 82 are detected, and three remote control applications corresponding to these three devices are activated. If the corresponding remote control application is not stored in the flash memory 30, the communication function is activated and a process of downloading the corresponding remote control application from the Internet is executed.

  Next, the CPU 26 transmits a test signal through the infrared light receiving / emitting circuit 38. Each of the television 50 and the illumination 80 receives the test signal and returns a response signal. The CPU 26 excludes the air conditioner 82 from the control target, and displays the remote control enabled device list screen shown in FIG. 9A on the LCD monitor 24. The screen in FIG. 9A includes three tabs corresponding to the television 50, the illumination 80, and the air conditioner 82, respectively. Of these, “air conditioner” is not controllable at the present time, so it is displayed semi-transparently.

  When a channel selection operation or volume adjustment operation is performed via the operation panel 36 with “TV” selected on the remote control enabled device list screen, an infrared code corresponding to the operation is transmitted by the TV remote control application. . The transmitted infrared code is received by the television 50, and the television 50 performs processing corresponding to the infrared code, that is, channel selection processing and volume adjustment processing.

  After PN registration is performed at home H1 as described above, when the remote control mode is selected at home H1, the screen of FIG. 9A is displayed immediately, and a desired remote control operation can be performed.

  The operation of the mobile communication terminal 10 at the friend's house H2 is as follows. With reference to FIG. 6 (B), television 84, video 86, and air conditioner 88 are installed in friend's house H2. Any device has an IC tag 66 and can be controlled by the mobile communication terminal 10.

  When the remote control mode is selected at the friend's house H2, since the PN is not registered at the friend's house H2, the PN registration guidance screen shown in FIG. 7B is displayed first. If “No” is selected here, the screen in FIG. 7B is updated by the standby screen in FIG. 9B. That is, unless the PN registration is performed at the friend house H2, the remote control function cannot be used at the friend house H2. As a result, activation of the remote control function outside the home can be restricted.

  If the remote control function is to be used also at the friend's house H2, PN registration may be performed at the friend's house H2 with the permission of the friend. That is, when “Yes” is selected on the screen of FIG. 7B, “18”, “21” and “22” are further registered in the register 30r as the PN value “PN2” in the friend's house H2. Next, a device detection process is executed, a remote control application corresponding to the detected device is activated, and a remote controllable device list screen similar to FIG. 9A is displayed. This screen includes three tabs corresponding to the television 84, the video 86, and the air conditioner 88, that is, "TV", "video", and "air conditioner", respectively. Next, a test signal is transmitted, and it is determined whether or not remote control is possible depending on the presence or absence of a response. The tabs of devices that are determined to be uncontrollable are displayed translucently. The user can perform a remote control operation as a desired device on the remote control enabled device list screen. If the PN registration is performed by the friend H2, the remote control operation can be performed immediately by selecting the remote control mode at the friend's house H2.

  In relation to the remote control function as described above, the CPU 26 of the mobile communication terminal 10 controls the PN detection task shown in FIG. 10, the flag (α) control task shown in FIG. 11, under the control of a multitask OS such as μITRON. 12 and the main task (remote control mode) shown in FIG. 13 and the remote control app (eg, TV remote control app, lighting remote control app) shown in FIG. 14 are executed in parallel. Note that the same number of remote control apps are activated as the number of detected electronic devices. On the other hand, the CPU of each electronic device, for example, the CPU 60 of the television 50 executes the remote control processing task shown in FIG.

  Note that the PN detection task is always activated as long as the power is turned on. The flag (α) control task and the main task are activated when the remote control mode is selected, and are ended when another mode is selected or when the power is turned off. The remote control app is activated by the main task and is terminated when a mode other than the remote control is selected or when the power is turned off.

  On the other hand, the remote control processing task on the electronic device side is always in the activated state as long as the main power supply of the electronic device is in the on state.

  A control program corresponding to the flowcharts of FIGS. 10 to 13 is stored in the flash memory 30. A control program corresponding to the flowchart of FIG. 15 is stored in the ROM 64.

  First, referring to FIG. 10, in step S1, a plurality of PN signals respectively transmitted from a plurality of base stations (ST1 to ST4: see FIG. 4) are detected through the telephone processing circuit. In step S3, the detection result (PN information) is held in the RAM 28 (see FIGS. 5A and 5B). In step S5, it is determined whether or not a predetermined time (for example, 1 second) has elapsed since the previous PN detection. If YES, the process returns to step S1.

  Referring to FIG. 11, in step S <b> 11, a PN value whose intensity is greater than or equal to a threshold value (= 3) is fetched from RAM 28. For example, if the PN information as shown in FIG. 5A is held in the RAM 28, “21”, “25”, and “22” are captured as PN values.

  In step S13, it is determined whether or not the captured PN value matches the PN value registered in the register 30r. Here, the match means a complete match between the combination of the PN values on the register 30r side and the combination of the PN values fetched from the RAM 28. Therefore, if no PN value is registered in the register 30r, it is determined that there is a mismatch. Also, assuming that “PN1 = 21, 25, and 22” is registered in the register 30r (see FIG. 3), the captured PN values are “21”, “25”, and “22” (see FIG. 5A). ), It is determined as a match, and if the captured PN values are “18”, “21” and “22” (see FIG. 5B), it is determined as a mismatch.

  If “YES” in the step S13, the process shifts to a step S15 to set “TRUE” in the flag α. If “NO” in the step S13, the process shifts to a step S17 to set “FALSE” in the flag α. After setting, the process proceeds to step S19. In step S19, it is determined whether or not a predetermined time (for example, 5 seconds) has elapsed since the previous PN acquisition. If YES, the process returns to step S11.

  Referring to FIG. 12, in step S31, it is determined whether or not a PN value is registered in register 30r. If NO, the process proceeds to step S35. If “YES” in the step S31, it is determined whether or not the flag α is “TRUE” in a step S33, and if “YES” here, the process proceeds to a step S47. If α = FALSE, NO is determined in the step S33, and the process shifts to a step S35.

  In step S35, the character generator 22 is instructed to display the PN registration guidance screen. In response, the character generator 22 displays a PN registration guidance screen on the LCD monitor 24 (see FIG. 7B). In steps S37 and S39, it is determined whether or not to perform PN registration. When “NO” on the PN registration guidance screen is selected by operating the operation panel 36, the process proceeds to step S41 to instruct the character generator 22 to display the standby screen. In response, the character generator 22 displays a standby screen on the LCD monitor 24 (see FIG. 9B). Then, this task itself (remote control mode) is terminated.

  On the other hand, if “Yes” is selected, a PN value having an intensity greater than or equal to the threshold value (= 3) is fetched from the RAM 28 in step S43, and the fetched PN value is registered in the register 30r in step S45 (see FIG. 3). Then, the process proceeds to step S47.

  In step S47, a device detection process is executed. In the device detection process, the IC tag reader 32 is instructed to transmit a request signal for requesting the IC tag 66 to return the identification information. When the identification information is received by the IC tag reader 32, the received identification information is registered in the device list in the RAM 28 (see FIG. 8).

  In step S49, it is determined whether or not a remote control application corresponding to the detected device exists in the flash memory 30, and if “YES” here, the process proceeds to a step S53. If there is no compatible remote control application, an application download process is executed in step S51. In the application download process, the Internet connection process is executed in cooperation with the telephone processing circuit 14 and a network controller (not shown), the server providing the corresponding remote control application is accessed, and the corresponding remote control application is flashed from the server. Download to memory 30. After downloading, the process proceeds to step S53.

  In step S53, the corresponding remote control application is activated. For example, when the current position is home H1 (see FIG. 6A) and the TV 50, the lighting 80, and the air conditioner 82 are detected, the TV remote control application, the lighting remote control application, and the air conditioner remote control application are activated. After activation, the process proceeds to step S55.

  Referring to FIG. 13, in step S55, the translucent flag is reset. This reset is for all devices registered in the device list. In step S57, a test signal is transmitted through the infrared light receiving and emitting circuit 38. This transmission is also for all devices. In step S59, it is determined whether or not there is a non-response device. If “NO” here, the process proceeds to a step S63. If “YES” in the step S59, that is, if there is a device that does not respond to the test signal, the process proceeds to a step S61 to set a translucent flag in the non-responding device (see FIG. 8). Then, the process proceeds to step S63.

  In step S63, the character generator 22 is instructed to display a remote controllable device list screen corresponding to the device list. Responsively, the character generator 22 displays a remote control capable device list screen on the LCD monitor 24 (see FIG. 9A). On this screen, the tab corresponding to the device for which the translucent flag is set is translucent. In this way, a test signal is transmitted to all devices, and if there is an unresponsive device, the tab of the device is made translucent so that the user can quickly confirm that the remote control operation of the device is impossible. Can be recognized. As a result, useless remote control operations can be reduced.

  After the display instruction, a loop of steps S65 and S67 is entered. While the screen of FIG. 9A is being displayed, the remote control application corresponding to the desired device (device “i”) among the remote control apps activated in step S53 receives the remote control operation and transmits the microcomputer signal. Is called. In step S65, it is determined whether or not a remote control signal (infrared code for device i) addressed to the device “i” has been transmitted. In step S67, has a predetermined time (for example, 10 seconds) elapsed since the previous test signal transmission? Determine whether or not.

  When transmission of the remote control signal is executed by the remote control application for device “i” (see FIG. 14), “YES” is determined in the step S65, and the process proceeds to a loop of steps S69 and S71. In step S69, it is determined whether or not there is a response signal from the device “i”. In step S71, it is determined whether or not a predetermined time (for example, 1 second) has elapsed since the transmission of the remote control signal. If “YES” in the step S69, the process returns to the loop of the steps S65 and S67.

  If “YES” in the step S71, the process shifts to a step S73 to set a translucent flag in the device “i”. Then, the process returns to step S63. In step S63 this time, since the translucent flag is set for the device “i”, the tab of the device “i” in the remote controllable device list screen is displayed translucently.

  In this way, the presence or absence of a response to the transmission of the remote control signal to each device is confirmed, and if there is no response, the tab of the device is made translucent so that the user cannot operate the remote control of the device. You can quickly recognize that As a result, useless remote control operations can be reduced.

  Referring to FIG. 14, in step S81, it is determined whether or not device “i” is selected on the remote control possible device list screen (see FIG. 9A). If it is selected, the remote control is determined in step S83. Determine if there is an operation. If a remote control operation is performed via the operation panel 36, “YES” is determined in the step S83, and the process proceeds to a step S85. In step S85, a remote control signal corresponding to the performed remote control operation is transmitted through the infrared ray receiving / issuing circuit 38. Then, the process returns to step S81.

  Referring to FIG. 15, on the device “i” side that is remotely controlled by mobile communication terminal 10, CPU 60 determines the presence or absence of a remote control signal or a test signal. When a remote control signal or a test signal is received through the infrared light receiving / emitting circuit 62, the process proceeds to step S93, and a response signal is returned through the same infrared light receiving / emitting circuit 62. In step S95, a process corresponding to the received remote control signal is executed, and then the process returns to step S91.

  As is apparent from the above, in this embodiment, the CPU 26 receives four PN signals respectively transmitted from the four base stations ST1, ST2, ST3 and ST4 through the telephone processing circuit 14 and receives the received four PN signals. The current position of the mobile communication terminal 10 is periodically detected based on the signal (S1, S3, S5).

  When a registration operation is accepted via the operation panel 36, the detection position is registered in the register 30r (see FIG. 3) (S45). When a remote control start operation is accepted via the operation panel 36 after registration, it is determined whether or not the detected position matches the registered position (S13). If the determination result is affirmative, the electronic device (50, 80, 82, ...) is detected (S47). The remote control signal is transmitted to one of the electronic devices thus detected through the infrared light receiving / emitting circuit 38.

  Accordingly, the mobile communication terminal 10 detects an electronic device only when the mobile communication terminal 10 is present at the registered position, and the remote control targets of the mobile communication terminal 10 are appropriately limited.

  Further, when displaying a plurality of characters respectively corresponding to the detected plurality of electronic devices on the LCD monitor 24, the CPU 26 determines whether there is a response to the test signal, that is, whether remote control by the mobile communication terminal 10 is possible or not. As shown in FIG. 9A, the transparency of each character is changed (S59, S61, S63). Thereby, it is possible to know which of the detected plurality of electronic devices, that is, the plurality of devices that should be remotely controlled, is actually remotely controllable. As a result, it is possible to select a desired device from among electronic devices that can actually be remotely controlled.

  Whether or not remote control is possible is determined collectively and periodically by transmitting a test signal to all detected electronic devices, and each time a remote control signal is transmitted, the destination of the signal is determined. It is performed for an electronic device.

  In this embodiment, the current position is detected using a plurality of PN signals respectively transmitted from a plurality of base stations, but transmitted from other signals, for example, a plurality of GPS (Global Positioning System) satellites. Position detection can also be performed using a plurality of GPS signals.

  Further, whether or not the detected position matches the registered position is specifically determined based on whether or not the combination of PN values on the RAM 28 side and the register 30r side completely match. You may discriminate | determine by whether it corresponds completely.

It is a block diagram which shows the structure of one Example of this invention. It is a block diagram which shows the structural example of the apparatus controlled by FIG. 1 Example. It is an illustration figure which shows the PN value registered into FIG. 1 Example. It is an illustration figure which shows an example of the movement area of FIG. 1 Example. (A) is an illustration figure which shows an example of PN information detected by FIG. 1 Example, (B) is an illustration figure which shows another example of PN information detected by FIG. 1 Example. (A) is an illustration figure which shows the electronic device which exists in the home in FIG. 4 area, (B) is an illustration figure which shows the electronic device which exists in the friend's house in FIG. 4 area. (A) is an illustration figure which shows an example of the screen displayed by FIG. 1 Example, (B) is an illustration figure which shows another example of the screen displayed by FIG. 1 Example. It is an illustration figure which shows an example of the apparatus list hold | maintained by FIG. 1 Example. (A) is an illustration figure which shows another example of the screen displayed by FIG. 1 Example, (B) is an illustration figure which shows other another example of the screen displayed by FIG. 1 Example. . It is a flowchart which shows a part of CPU operation | movement of FIG. 1 Example. It is a flowchart which shows a part of other CPU operation | movement of FIG. 1 Example. It is a flowchart which shows a part of other CPU operation | movement of FIG. 1 Example. FIG. 11 is a flowchart showing yet another portion of the behavior of the CPU in the embodiment in FIG. 1. It is a flowchart which shows a part of other CPU operation | movement of FIG. 1 Example. 2 is a flowchart showing a part of the CPU operation of the device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Mobile communication terminal 12, 34, 52, 66 ... Antenna 14 ... Telephone processing circuit 22 ... Character generator 24 ... LCD monitor 26, 60 ... CPU
30 ... Flash memory 32 ... IC tag reader 36 ... Operation panel 38, 62 ... Infrared light emitting / receiving circuit 50 ... Television (electronic equipment)
66 ... IC tag

Claims (7)

A communication means for executing communication processing with a base station;
Information detecting means for detecting identification information of a base station capable of communicating by the communication means;
Registration means for registering identification information detected by the information detection means under a desired position condition;
Discriminating means for discriminating whether or not a matching condition is satisfied between the identification information detected by the information detecting means after the registration processing by the registration means and the identification information registered by the registration means;
Device detecting means for detecting an electronic device existing around when the determination result of the determining means is affirmative; and display means for displaying an operation screen for remotely controlling the electronic device detected by the device detecting means A portable communication terminal. The base station repeatedly transmits a PN signal,
The mobile communication terminal according to claim 1, wherein the information detection unit pays attention to a PN signal transmitted from the base station. The electronic device has a wireless tag that stores device identification information,
The portable communication terminal according to claim 1 or 2, wherein the device detection means includes reading means (32) for reading the device identification information stored in the wireless tag. Creating means for creating a control signal suitable for the electronic device detected by the device detecting means;
Transmitting means for transmitting the control signal created by the creating means to the processor of the electronic device detected by the device detecting means;
Further comprising response device detection means for detecting an electronic device responding to the control signal transmitted by the transmission means,
The portable communication terminal according to claim 1, wherein the display unit changes a display mode of the operation screen according to a detection result of the response device detection unit.   The mobile communication terminal according to claim 4, wherein the transmission unit repeatedly transmits the control signal. An acquisition means for acquiring, using the communication means, device control information for remotely controlling the electronic device detected by the device detection means,
The mobile communication terminal according to claim 4 or 5, wherein the creating means creates the control signal based on the device control information obtained by the obtaining means. In a processor of a portable communication terminal provided with a communication means for executing communication processing with a base station,
An information detecting step of detecting identification information of a base station capable of communicating by the communication means;
A registration step of registering the identification information detected by the information detection step under a desired position condition;
A determination step of determining whether or not a matching condition is satisfied between the identification information detected by the information detection step and the identification information registered by the registration step after the registration process by the registration step;
A device detecting step for detecting an electronic device existing in the surroundings when the determination result of the determining step is affirmative; and a display step for displaying an operation screen for remotely controlling the electronic device detected by the device detecting step. Device control program to be executed.

Images