JP2007110350A - System, device, and method for remote control - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow easy control of target equipment, with no selective operation for the same. <P>SOLUTION: The equipment that is controlled by a remote control device is provided with an information presenting means that presents equipment discrimination information specific to the equipment. The remote control device takes in the equipment discrimination information, and discriminates the equipment based on the equipment discrimination information that has been taken in, for transmitting the remote control signal for the equipment that has been identified. With no selective operation for the equipment to be controlled, the remote control signal corresponding to the equipment can be transmitted only by performing remote control operation by directing the remote control device to the target equipment. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a remote control system, a remote control device, and a remote control method. Specifically, device identification information unique to the controlled device is presented on the controlled device side controlled by the remote control device, and when the remote control device determines that a user operation has been performed, the captured device identification information is A remote control signal used in the controlled device shown is generated and transmitted according to a user operation.

  Various household appliances are used in ordinary households, and these household appliances include many appliances that can be easily controlled from a remote location using a remote control device. However, as the number of devices that can be controlled using a remote control device increases, the number of remote control devices becomes enormous. When a desired device is to be controlled, a remote control device corresponding to the desired device must be used each time. The operation becomes complicated. In addition, the operation key layout and the functions assigned to the operation keys are not standardized in each remote control device, which further complicates the operation. For this reason, a remote control device that is configured in advance so as to transmit a remote control signal corresponding to a plurality of controlled devices, a so-called preset remote controller is provided.

  The preset remote controller can designate a controlled device by a switch operation of a slide switch or a predetermined key operation. Further, for example, operation keys used in main operations such as volume adjustment and channel switching are configured to be used in common regardless of the selected controlled device. For this reason, the user can easily perform main operations regardless of which controlled device is selected by becoming familiar with key operations using the preset remote controller. Further, it is not necessary to use a remote control device corresponding to the controlled device to be controlled each time. However, in the preset remote control, if the controlled device is not specified correctly, a remote control signal corresponding to the controlled device different from the desired controlled device is transmitted, and the desired controlled device is controlled correctly. I can't. Moreover, there is a possibility that a controlled device different from the desired controlled device may be erroneously controlled.

  In order to solve such a problem, in the invention of Patent Document 1, the light intensity of the transmitted remote control signal is received and compared by each device, and the device that received the stronger signal is operated. . In the invention of Patent Document 2, an inquiry signal is transmitted from the remote control device, and a list of devices that have responded is displayed on the display means so that the user can select. Further, in the invention of Patent Document 3, the presence of each device in a room is transmitted from a set top box or the like to a remote control device, and a list is displayed on the remote control device side to facilitate device selection. Yes.

JP 2003-32760 A JP-A-10-164673 JP-A-8-18813

  By the way, when the remote control system is configured so that a device that receives a stronger signal operates, if the controlled device is provided at a remote position and other devices are provided nearby, Even if a remote control signal is transmitted toward the control device, the signal strength in the controlled device provided nearby becomes stronger than the signal strength in the controlled device, and the controlled device cannot be controlled. . Also, since the received signal strength is compared between the devices, it is necessary to exchange information between the devices using some method, and a remote control system cannot be constructed easily and easily.

  When an inquiry signal is transmitted from the remote control device to display a list of responding devices and allow the user to select a device, the user needs to select a controlled device from the displayed device list Therefore, it cannot be said that the interface is really easy to use.

  Furthermore, when the presence of each device in the room is transmitted from the set top box or the like to the remote control device and displayed as a list on the remote control device side, it takes time and effort for the user to select the controlled device with the remote control device.

  Therefore, in the present invention, a remote control system can easily control a desired controlled device by transmitting a remote control signal corresponding to the desired controlled device without performing a selection operation of the controlled device. And a remote control device and a remote control method.

  In this invention, the controlled device controlled by the remote control device includes information presenting means for presenting device identification information unique to the controlled device, for example, an information transmitting device or RFID tag for transmitting the device identification information as a radio signal, A bar code indicating device identification information is provided. The remote control device is provided with information capturing means for capturing the device identification information presented by the information presenting means. For example, a light receiving module that receives device identification information transmitted as an infrared signal, an RFID reader that receives radio waves from an RFID tag and obtains device identification information, a barcode reader that reads a barcode, and the like are provided. Here, when the remote control device determines that the user operation has been performed based on the operation signal, the remote control signal used in the controlled device indicated by the device identification information captured by the information capturing unit is determined according to the operation signal. Generate and transmit as a radio signal.

  According to the present invention, when it is determined that a user operation is performed based on the operation signal, a remote control signal used in the controlled device indicated by the device identification information captured by the information capturing unit is generated according to the operation signal. And transmitted as a radio signal.

  For this reason, when the remote control device performs a key operation in the direction of the information presenting means provided in the desired controlled device, for example, the device identification information indicating the desired controlled device is captured, and this desired controlled device is obtained. A remote control signal used in the control device is generated and transmitted in response to a key operation, and a desired controlled device can be easily controlled without performing a selection operation of the controlled device.

  In addition, the remote control signal used in the desired controlled device can be generated according to the key operation simply by pointing the remote control device in the direction that can capture the device identification information of the desired controlled device. Since it can be transmitted, it is possible to perform a comfortable remote control operation that is intuitive and easy for the user to understand. In addition, operational errors can be reduced.

  Embodiments of the present invention will be described below. In the remote control system of the present invention, information presenting means for presenting device identification information unique to the controlled device is provided in the controlled device controlled by the remote control device. In addition, the remote control device is provided with an information capturing unit that captures device identification information, and is used by a controlled device indicated by the device identification information captured by the information capturing unit when a user operation is performed. A control signal is generated and transmitted in response to a user operation.

  Here, the device identification information is presented regardless of the operation of the remote control device. Alternatively, it is presented when a signal indicating a request for device identification information is supplied from the remote control device. The device identification information is presented in a wireless manner using light or radio waves. In addition, a code image indicating device identification information, for example, a so-called one-dimensional barcode in which the information recording direction is only one direction, or a so-called two-dimensional barcode in which the information recording direction is a horizontal direction and a vertical direction is provided. The device identification information can be obtained by reading the code image with the remote control device. Hereinafter, each case will be described in detail with reference to the drawings.

  FIG. 1 shows a schematic configuration of the first embodiment. The remote control system 10a shows a case where device identification information is presented using infrared light regardless of the operation of the remote control device. FIG. 1 shows a case where the two controlled devices 21 and 22 are individually operated by the remote control device 40a.

  The controlled device 21 is provided with an identification information transmitting device 31 that transmits device identification information of the controlled device 21 as a radio signal as information presenting means. Further, the controlled device 21 is provided with a remote control signal receiving unit 211 for receiving an infrared remote control signal IRm transmitted from the remote control device 40a.

  The controlled device 22 is provided with an identification information transmitting device 32 that transmits device identification information of the controlled device 22 as a radio signal as information presenting means. The controlled device 22 is provided with a remote control signal receiving unit 221 for receiving an infrared remote control signal IRm transmitted from the remote control device 40a.

  The identification information transmission device 31 always repeatedly transmits the infrared information signal IRe1 generated based on the device identification information. The identification information transmitting device 32 always transmits the infrared information signal IRe2 generated based on the device identification information repeatedly. The identification information transmitting devices 31 and 32 are in this state when the controlled devices 21 and 22 are in an operation state in which the infrared remote control signal IRm can be received, for example, in a standby state or a power-on state. During the period, the infrared information signals IRe1 and IRe2 may be always transmitted repeatedly.

  The remote control device 40a receives the infrared information signal indicating the device identification information of the desired controlled device, captures the device identification information, and transmits the remote control signal used in the controlled device indicated by the captured device identification information. It is generated according to the operation signal and transmitted as an infrared remote control signal IRm.

  FIG. 2 shows the configuration of the identification information transmitting device 31 and the remote control device 40a in the first embodiment. The identification information transmitting device 32 is configured in the same manner as the identification information transmitting device 31, and the description of the identification information transmitting device 32 is omitted.

  The identification information transmission device 31 includes an information signal generation unit 311 and a communication unit 312. The memory 311 a of the information signal generator 311 stores device identification information DE of the controlled device 21. This device identification information DE is information that makes it possible to determine what format of the remote control signal is used in the controlled device 21. For example, the manufacturer information of the controlled device 21, and the controlled device 21 is a television set. Category information indicating which category the device belongs to, such as a device or disk device. If the model information is also included, the controlled device 21 can be determined in detail, so that even if the function differs for each model, the remote control corresponding to each model is possible. The signal can be generated by a remote control device.

  The microcomputer 311b of the information signal generation unit 311 reads the device identification information DE stored in the memory 311a, generates an information signal RE based on the read device identification information, and supplies the information signal RE to the communication unit 312.

  FIG. 3 illustrates an information signal format. The start bit portion BS of the information signal indicates the start of the frame in the information signal, and the end bit portion BE indicates the end of the frame. The information bit portion BI indicates device identification information. For example, the manufacturer information bit portion BIm indicating manufacturer information of the controlled device, the category bit portion BIc indicating the category of the controlled device, and the controlled device's category. It has a type bit part BIt indicating the model.

  In FIG. 2, the communication unit 312 includes a driver 312a and a light emitting element 312b. The driver 312a is configured using a transistor, a resistor, or the like, and drives the light emitting element 312b based on the information signal RE. The light emitting element 312b is composed of an infrared light emitting diode or the like, and is driven by a driver 312a to output an infrared information signal IRe1. For example, the transmission of the information signal RE is repeated with a time interval of 50 ms. Note that only when the controlled device 21 can receive the infrared remote control signal IRm by supplying a signal indicating that the controlled device 21 is in a standby state, a power-on state, or the like to the microcomputer 311b. The communication unit 312 may output the infrared information signal IRe1.

  The remote control device 40a includes an information capturing unit 410a, an operation unit 420, a signal generation unit 430a, and a transmission unit 440.

  The information capturing unit 410a is configured using a light receiving module 411 that receives an infrared information signal transmitted from the identification information transmitting device. The light receiving module 411 is configured using a photodiode (not shown) and a signal processing unit (not shown) that performs level adjustment, waveform shaping, and the like of a signal generated by the photodiode. In the light receiving module 411, a signal generated by a photodiode when an infrared signal is received is processed by a signal processing unit, and the signal obtained by the signal processing unit is used as a reception signal RS to be a microcomputer of the signal generating unit 430a. 432a.

  In addition, the light receiving module 411 is provided in the remote control device 40a so as to receive an infrared information signal transmitted from a radiation direction of an infrared remote control signal IRm transmitted from a transmitter 440 described later.

  Further, the light receiving module 411 is configured to be able to widen or narrow the directivity when capturing the device identification information, that is, when receiving the infrared information signal from the device information transmitting apparatus.

  FIG. 4 shows the configuration of the light receiving module 411 in which the directivity can be switched. For example, a narrow-directional photodiode 411a having a small half-value angle and a wide-directional photodiode 411b having a large half-value angle are provided, and a signal generated by any one of the photodiodes is selected by the selection switch 411c. The switching control of the selection switch 411c is performed based on the control signal SC supplied from the signal generation unit 430a. The signal processing unit 411d performs processing such as signal level adjustment and waveform shaping on the signal supplied from the selection switch 411c, and supplies the processed signal to the microcomputer 432a as a reception signal RS. In this way, the directivity characteristic of the light receiving module 411 can be switched to either the half-value angle θa or the half-value angle θb.

  The operation unit 420 includes a plurality of operation keys, generates an operation signal PS corresponding to a user's key operation, and supplies the operation signal PS to the microcomputer 432a.

  The signal generation unit 430a includes a memory 431 and a microcomputer 432a. The memory 431 stores a data code DM corresponding to the operation key for each controlled device controlled by the remote control device 40a. The microcomputer 432a generates the control signal SC based on the received signal RS and supplies the generated light receiving module 411 to switch the directivity. In addition, the device identification information is extracted from the received signal RS to determine the controlled device. Further, the data code DM is read from the memory 431 based on the determination result of the controlled device and the operation signal PS from the operation unit 420, and the remote control signal RM is generated using the read data code DM to transmit the transmission unit. 440 is supplied. That is, a remote control signal used in the controlled device indicated by the device identification information captured by the information capturing unit is generated in accordance with the key operation of the operation unit and supplied to the transmission unit 440.

  The transmission unit 440 includes a driver 441 and a light emitting element 442. The driver 441 is configured using a transistor, a resistor, and the like, and drives the light emitting element 442 based on the remote control signal RM supplied from the signal generation unit 430a. As the light emitting element 442, for example, an infrared light emitting diode is used and is driven by a driver 441 to output an infrared remote control signal IRm.

  Next, the operation of the remote control device according to the first embodiment will be described with reference to FIG. In step ST1, the microcomputer 432a determines whether or not a key operation has been performed. Here, when it is determined that the key operation has been performed based on the operation signal PS of the operation unit 420, the process proceeds to step ST2. If it is not determined that a key operation has been performed, the process returns to step ST1.

  In step ST2, the microcomputer 432a captures device identification information by setting the directivity characteristics of the information capturing unit 410a widely, and proceeds to step ST3. For example, when the light receiving module 411 is configured as shown in FIG. 4 described above, the microcomputer 432a supplies the control signal SC to the selection switch 411c of the light receiving module 411 and generates it with the wide directivity photodiode 411b. The selected signal is selected.

  In step ST3, the microcomputer 432a determines whether or not only device identification information for one controlled device is obtained from the received signal RS. If only the device identification information for one controlled device is not obtained, the process proceeds to step ST4. If only the device identification information for one controlled device is obtained, the process proceeds to step ST7. Here, as shown in FIG. 4 described above, the identification information transmitting devices 31 and 32 are included in the directivity range Wb of the photodiode 411b, and the controlled device 21 and the controlled device 22 are based on the received signal RS. When the device identification information is obtained, or when the signals transmitted from the identification information transmission device 31 and the identification information transmission device 32 interfere with each other and neither device identification information of the controlled devices 21 and 22 can be obtained. The process proceeds to step ST4. Further, also when the identification information transmitting device is not included in the directivity range Wb of the photodiode 411b, the process proceeds to step ST4.

  In step ST4, the microcomputer 432a captures device identification information by setting the directivity to be narrow, and proceeds to step ST5. That is, when the light receiving module 411 is configured as shown in FIG. 4 described above, the microcomputer 432a supplies the control signal SC to the selection switch 411c of the light receiving module 411 and generates it with the narrow-directional photodiode 411a. The selected signal is selected.

  In step ST5, the microcomputer 432a determines whether or not only device identification information for one controlled device is obtained from the received signal RS. If only the device identification information for one controlled device is not obtained, the process proceeds to step ST6. If only the device identification information for one controlled device is obtained, the process proceeds to step ST7. Here, when the light receiving module is configured as shown in FIG. 4, only the identification information transmitting device 31 is included in the directivity range Wa of the photodiode 411a by selecting the narrow-directional photodiode 411a. Thus, only the device identification information about the controlled device 21 is obtained, and the process proceeds to step ST7. Further, although not shown, the device identification for one controlled device is performed when the identification information transmitting device is not included in the directivity range Wa of the photodiode 411a or when a plurality of identification information transmitting devices are included. If only information cannot be obtained, the process proceeds to step ST6.

  In step ST6, the microcomputer 432a displays a warning indicating that the controlled device operated by the remote control device cannot be specified, and returns to step ST1. In this warning display, when a display unit (not shown) is provided in the remote control device 40a, this display unit is used. In addition, when a light emitting element indicating that the remote control signal is transmitted is provided, the light emitting element may emit light in a color different from that at the time of transmitting the remote control signal to display a warning. . Further, a light emitting element that performs warning display may be provided separately.

  In step ST7, the microcomputer 432a determines the controlled device based on the device identification information, and proceeds to step ST8.

  In step ST8, the microcomputer 432a determines which operation key of the operation unit 420 has been operated based on the operation signal PS, and proceeds to step ST9.

  In step ST9, the microcomputer 432a reads the data code. Here, the microcomputer 432a determines that the controlled device determined in step ST7 has been operated in step ST8 from the memory 431 in which the data code corresponding to the operation key is stored for each controlled device. The data code corresponding to the key is read and the process proceeds to step ST10.

  In step ST10, the microcomputer 432a transmits a remote control signal and returns to step ST1. In the transmission of the remote control signal, for example, the remote control signal RM is generated by modulating the carrier signal with the data code read in step ST9. Further, the light emitting element is driven by the generated remote control signal RM and transmitted as an infrared remote control signal IRm.

  In this way, the device identification information is always repeatedly transmitted from the identification information transmission device provided in the controlled device, and when the key operation is performed on the remote control device, the device identification information is captured, and the captured device identification is performed. A remote control signal used in the controlled device indicated by the information is generated and transmitted according to the key operation. Therefore, even if the user does not select the controlled device, the user can easily operate the desired controlled device simply by pointing the remote control device in the direction in which the device identification information of the desired controlled device can be captured. Can be controlled. In addition, it is possible to perform a comfortable remote control operation that is intuitive and easy to understand for the user. In addition, operational errors can be reduced.

  Furthermore, since the directivity characteristics are automatically switched when capturing the device identification information, the device identification information can be captured easily and accurately.

  Note that a display unit (not shown) is provided in the remote control device 40a to display the controlled device determined based on the device identification information, or the control content of the determined controlled device is used as an operation key. If displayed in correspondence, further remote control operations can be performed easily and correctly.

  By the way, when the device identification information is always transmitted repeatedly as in the first embodiment, the device identification information is transmitted even when the remote control operation is not performed, so that power is wasted. In addition, an infrared information signal is unnecessarily transmitted from the identification information transmitting device. Therefore, a configuration in which device identification information is transmitted only when device identification information is required will be described as a second embodiment.

  FIG. 6 shows a schematic configuration of the second embodiment. In the remote control system 10b, the remote control device 40b inquires about device identification information when a key operation is performed. In addition, the controlled device is provided with an identification information transmitting device that transmits the device identification information of the controlled device as a radio signal when a signal indicating an inquiry about the device identification information is supplied from the remote control device 40b. FIG. 6 illustrates a case where the identification information transmitting device 33 is provided in the controlled device 21. The remote control device 40b has the same configuration as the remote control device 40a shown in FIG.

  FIG. 7 shows the configuration of the identification information transmitting apparatus 33 in the second mode. In FIG. 7, portions corresponding to the identification information transmitting device 31 illustrated in FIG. 2 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The communication unit 332 of the identification information transmitting device 33 includes a light receiving module 332a that receives the infrared remote control signal IRm transmitted from the remote control device 40b, a driver 312a, and a light emitting element 312b. When the light receiving module 332a receives the infrared remote control signal IRm with a photodiode (not shown), the signal processing unit (not shown) performs level adjustment and waveform shaping of the signal generated by the photodiode, The signal processed by the signal processing unit is supplied as a reception signal RT to the microcomputer 331a of the information signal generation unit 331. The microcomputer 331a reads the device identification information DE stored in the memory 311a when determining that the device identification information is inquired by the received signal RT. Further, the microcomputer 331a generates an information signal RE based on the read device identification information DE, supplies the information signal RE to the driver 312a of the communication unit 332, and outputs an infrared information signal IRe1 indicating the device identification information from the light emitting element 312b. .

  The microcomputer 331a supplies the display drive signal LD to the driver 333a of the display unit 333 when the remote control signal RM is supplied as the reception signal RT from the communication unit 332 after the device identification information transmission process.

  The driver 333a of the display unit 333 is connected to a light emitting element 333b that emits visible light, for example, a light emitting diode that emits light such as red or green. The driver 333a drives the light emitting element 333b based on the display drive signal LD supplied from the microcomputer 331a. For this reason, since the remote control signal RM is transmitted from the remote control device 40b can be determined by the display on the display unit 333, it is easy for the user to control the controlled device by the remote control device 40b. Can be identified.

  FIG. 8 is a sequence diagram showing the operation of the second embodiment. When the key operation KA is performed on the operation unit 420, the remote control device 40b transmits an infrared remote control signal IRm-k indicating an inquiry about device identification information.

  When receiving the infrared remote control signal IRm-k indicating the inquiry about the device identification information, the identification information transmitting device 33 performs the transmission process KB of the information signal indicating the device identification information, and receives the infrared information signal IRe1 indicating the device identification information. Send.

  When receiving the infrared information signal IRe1, the remote control device 40b performs a remote control signal transmission process KC. In this remote control signal transmission process KC, the controlled device 21 is discriminated based on the device identification information DE indicated by the infrared information signal IRe1, and a remote control signal used in the controlled device 21 is generated according to the key operation. Then, the infrared remote control signal IRm is transmitted.

  When the identification information transmitting device 33 receives the infrared remote control signal IRm, the identification information transmitting device 33 performs reception display processing KD and displays on the display unit 33 that the infrared remote control signal IRm has been received.

  9 and 10 are flowcharts showing the operation of the second embodiment. 9 shows the operation of the remote control device 40b, and FIG. 10 shows the operation of the identification information transmitting device 33.

  In step ST21 of FIG. 9, the microcomputer 432a determines whether or not a key operation has been performed. Here, when any one of the operation keys of the operation unit 420 is operated, the process proceeds to step ST22. If the operation key is not operated, the process returns to step ST21.

  In step ST22, the microcomputer 432a transmits a signal indicating an inquiry about device identification information, and proceeds to step ST23. That is, the microcomputer 432a generates a signal indicating an inquiry about device identification information and supplies the signal to the transmission unit 440, thereby causing the signal indicating the inquiry about device identification information to be output as an infrared remote control signal IRm.

  In step ST41 of FIG. 10, the microcomputer 331a determines whether or not a signal indicating an inquiry about device identification information has been received. Here, when the received signal RT supplied from the light receiving module 332a of the communication unit 332 indicates an inquiry of device identification information, the process proceeds to step ST42. Further, when the received signal RT does not indicate an inquiry for identification information, or when the received signal RT is not supplied, the process proceeds to step ST43.

  In step ST42, the microcomputer 331a transmits identification information and proceeds to step ST43. That is, the microcomputer 331a reads the device identification information DE stored in the memory 311a, and generates an information signal RE based on the read device identification information DE. Further, the microcomputer 331a supplies the generated information signal RE to the driver 312a of the communication unit 332 to output an infrared information signal indicating the device identification information from the light emitting element 312b, and the process proceeds to step ST43.

  The processing from step ST23 to step ST31 in FIG. 9 corresponds to the processing from step ST2 to step ST10 in FIG. That is, in step ST23, the microcomputer 432a captures device identification information by setting a wide directivity and proceeds to step ST24.

  In step ST24, the microcomputer 432a determines whether or not only device identification information about one controlled device is obtained from the received signal RS. If only the device identification information for one controlled device is not obtained, the process proceeds to step ST25. If only the device identification information for one controlled device is obtained, the process proceeds to step ST28.

  In step ST25, the microcomputer 432a captures device identification information by setting the directivity characteristics to be narrow, and proceeds to step ST26.

  In step ST <b> 26, the microcomputer 432 a determines whether only device identification information for one controlled device has been obtained from the received signal. Here, when only the device identification information for one controlled device is not obtained, the process proceeds to step ST27, and when only the device identification information for one controlled device is obtained, the process proceeds to step ST28.

  In step ST27, the microcomputer 432a displays a warning indicating that the controlled device operated by the remote control device cannot be specified, and returns to step ST21.

  In step ST28, the microcomputer 432a determines the controlled device based on the device identification information, and proceeds to step ST29.

  In step ST29, the microcomputer 432a determines which operation key of the operation unit 420 has been operated based on the operation signal PS, and proceeds to step ST30.

  In step ST30, the microcomputer 432a reads the data code and proceeds to step ST31.

  In step ST31, the microcomputer 432a transmits a remote control signal and returns to step ST21.

  In step ST43 of FIG. 10, the microcomputer 331a determines whether or not the remote control signal RM has been received based on the reception signal RT. If the remote control signal RM corresponding to the controlled device is not received, the process returns to step ST41. If the remote control signal RM corresponding to the controlled device is received, the process proceeds to step ST44.

  In step ST44, the microcomputer 331a drives the driver 333a to turn on the light emitting element 333b, displays that the remote control signal RM is received, and returns to step ST41.

  In this way, when a signal indicating an inquiry about device identification information is transmitted from the remote control device and the device identification information is transmitted from the identification information transmitting device that has received this signal, the signal indicating the device identification information is always transmitted repeatedly. Since it is not necessary, it is possible to prevent wasteful consumption of power. It is also possible to prevent the infrared information signal from being transmitted unnecessarily.

  By the way, in the first and second embodiments described above, the case where an infrared information signal indicating device identification information is transmitted from the identification information transmitting device as the device identification information has been described. For example, the device identification information may be presented using radio waves. Next, a configuration in the case of using radio waves will be described as a third embodiment.

  FIG. 11 shows a schematic configuration of the third embodiment. The controlled device of the remote control system 10c is provided with an identification information transmitting device that presents device identification information using radio waves, for example, an RFID (Radio Frequency Identification) tag. Note that FIG. 11 illustrates a case where the RFID tag 34 is provided in the controlled device 21.

  As an RFID tag, an active type having a power source and a passive type that operates by obtaining electric power for receiving radio waves to operate the RFID tag have been put into practical use. Here, if a passive type RFID tag is used as the RFID tag 34 provided in the controlled device 21, the device identification information cannot be transmitted due to battery exhaustion or the like, so that the device identification is performed without maintenance. Information can be transmitted.

  The remote control device 40c is provided with an information capturing unit 410c that can read information of the RFID tag 34, and radiates radio waves from the information capturing unit 410c to operate the passive type RFID tag 34, thereby identifying device identification information. Import.

  When device identification information is presented using an RFID tag in this way, communication is possible even if the distance between the RFID tag and the remote control device is about several meters apart. For example, communication is performed using a frequency band of 952 MHz to 954 MHz assigned to the UHF band for a passive type tag system.

  FIG. 12 shows the configuration of the RFID tag and the remote control device in the third embodiment. In FIG. 12, parts corresponding to those in FIGS. 2 and 7 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The information capture unit 410c of the remote control device 40c is configured using a reader unit 414 and an antenna 415. When the signal RQ indicating the inquiry of the device identification information is supplied from the microcomputer 432c of the signal generation unit 430c, the reader unit 414 supplies the carrier wave signal to the antenna 415 as the communication signal RFm for transmission. Next, the carrier wave signal is modulated by a signal indicating the inquiry of the device identification information, and the modulated carrier wave signal is supplied to the antenna 415 as the communication signal RFm and transmitted. Thereafter, the carrier wave signal is again supplied to the antenna 415 as the communication signal RFm and transmitted. Further, the reader unit 414 performs a demodulation process on the communication signal RFe received by the antenna 415, and supplies the demodulated signal to the microcomputer 432c as a reception signal RS. The antenna 415 of the information capturing unit 410c is provided in the remote control device 40c so that the directivity direction of the antenna 415 matches the radiation direction of the infrared remote control signal IRm radiated from the transmission unit 440.

  The RFID tag 34 includes a memory 311 a and a tag control unit 341 a as an information signal generation unit 341, and an antenna 342 a as a communication unit 342.

  The antenna 342a receives the radio wave transmitted from the information capturing unit 410c of the remote control device 40c and supplies the obtained communication signal RFm to the tag control unit 341a. The tag control unit 341a generates electric power necessary for operating the RFID tag based on the communication signal RFm. For example, the communication signal RFm is rectified and smoothed to generate necessary power. Further, the communication signal RFm is demodulated, and it is determined whether or not the demodulated signal is a signal indicating an inquiry for device identification information. Here, when it is determined that a signal indicating an inquiry about the device identification information is supplied, the device identification information DE stored in the memory 311a is read in advance, and the carrier wave signal is modulated based on the read device identification information. Then, the communication signal RFe is supplied to the antenna 342a and transmitted. In addition, since the carrier signal is continuously transmitted from the information capturing unit 410c after the transmission of the signal indicating the inquiry of the device identification information, the communication signal RFe indicating the device identification information can be transmitted from the RFID tag 34.

  FIG. 13 is a flowchart showing the operation of the remote control device according to the third embodiment.

  In step ST51, the microcomputer 432c determines whether or not a key operation has been performed. Here, when any one of the operation keys of the operation unit 420 is operated, the process proceeds to step ST52. If the operation key is not operated, the process returns to step ST51.

  In step ST52, the microcomputer 432c performs a process for fetching device identification information and proceeds to step ST53. In this device identification information capturing process, the microcomputer 432c supplies a signal indicating an inquiry about the device identification information to the information capturing unit 410c, and a signal indicating an inquiry about the carrier signal or the device identification information as described above. Is transmitted as a communication signal RFm.

  In step ST53, the microcomputer 432c determines whether or not only device identification information of one controlled device is obtained. Here, the microcomputer 432c proceeds to step ST54 when the device identification information of one controlled device is not obtained based on the received signal RS from the information capturing unit 410c, and the device identification of one controlled device. When only the information is obtained, the process proceeds to step ST55.

  In step ST54, the microcomputer 432c displays a warning indicating that the controlled device operated by the remote control device cannot be specified, and returns to step ST51.

  In step ST55, the microcomputer 432c determines the controlled device based on the device identification information, and proceeds to step ST56.

  In step ST56, the microcomputer 432c determines which operation key of the operation unit 420 has been operated based on the operation signal PS, and proceeds to step ST57.

  In step ST57, the microcomputer 432c reads the data code and proceeds to step ST58.

  In step ST58, the microcomputer 432c transmits a remote control signal and returns to step ST51.

  As described above, when the RFID tag is used, the device identification information can be presented at a lower cost than the case where an identification information transmitting device that performs device identification information using infrared rays is provided. In addition, when a passive type RFID tag is used, it is not necessary to provide a battery, a cable for supplying power, or the like, and device identification information can be easily provided without maintenance.

  Further, if the remote control device 40c is configured so that the directivity range of the antenna 415 can be adjusted, a signal from the RFID tag can be received with a wide directivity and one target signal can be received, as in the flowchart shown in FIG. When only the device identification information of the control device cannot be obtained, switching to narrow directivity and receiving the signal from the RFID tag makes it easy and accurate to capture the device identification information indicating the desired controlled device. It can be carried out.

  By the way, in the above-described embodiment, the device identification information is transmitted from the controlled device side using radio waves or infrared rays. However, the device identification information can be captured by the remote control device without transmitting the device identification information. You may do it. Next, a configuration in which device identification information can be captured by a remote control device without transmitting device identification information will be described as a fourth embodiment.

  FIG. 14 shows a schematic configuration of the fourth embodiment. In this remote control system 10d, an image indicating device identification information, for example, a barcode is provided on the controlled device so that the device identification information can be captured by the remote control device without transmitting the device identification information. The device identification information is obtained by reading the image with the remote control device 40d. As the barcode, a so-called one-dimensional barcode in which the information recording direction is only one direction or a so-called two-dimensional barcode in which the information recording direction is a horizontal direction and a vertical direction is used. FIG. 14 shows a case where the barcode 35 is provided on the controlled device 21.

  FIG. 15 shows the configuration of the remote control device according to the fourth embodiment. In the remote control device 40d of FIG. 15, the same reference numerals are given to the portions corresponding to those of the remote control device 40a of FIG.

  When a key operation is performed on the operation unit 420, the microcomputer 432d supplies a reading start signal CS to the information capturing unit 410d.

  When the reading start signal CS is supplied, the projector 417 of the information capturing unit 410d outputs the light beam while changing the direction of the light beam so that the barcode can be scanned. The light receiving sensor 418 generates a signal SB corresponding to the reflected light of the light beam and supplies it to the signal processing unit 419. The signal processing unit 419 performs level adjustment and binarization of the signal SB supplied from the light receiving sensor 418, and supplies the obtained read signal CR to the microcomputer 432d of the signal generation unit 430d.

  Here, in the light receiving sensor 418, when the distance from the barcode 35 to the light receiving sensor 418 is small as described in "Condensing method of data reader" in Japanese Patent Application Laid-Open No. 2004-145633, the reflected light is reflected. Is difficult to enter the light receiving sensor 418, and when the distance is large, the barcode 35 can be read with high accuracy by adjusting the mirror mounting angle so that the amount of reflected light to the light receiving sensor 418 increases.

  Further, the light receiving sensor 418 is configured by using an image sensor, and a barcode is read by providing a focus adjustment mechanism and a magnification adjustment mechanism as in the barcode reading apparatus of Japanese Patent No. 2667393, and the read image is read. The signal may be supplied to the signal generator 430d as a read signal CR.

  The microcomputer 432d extracts device identification information based on the read signal CR, and determines the controlled device based on the extracted device identification information. Further, the microcomputer 432d determines which operation key of the operation unit 420 is operated based on the operation signal PS. Further, the microcomputer 432d reads out the data code DM corresponding to the determined controlled device and the key operation from the memory 431, generates a remote control signal RM, supplies it to the transmission unit 440, and supplies the infrared remote control signal IRm. Output.

  As described above, even if the controlled device is provided with an image indicating the device identification information as the information presentation means, the image indicating the device identification information can be read and the infrared remote control signal IRm corresponding to the desired controlled device can be transmitted. .

  In addition, if the remote control devices 40a to 40d described above are provided with a learning function so that a data code corresponding to a new controlled device can be registered in the memory 431, it is possible to easily cope with an increase in the number of controlled devices. It becomes possible to do. Here, when a new data code DM is registered, the data code can be registered without providing a new circuit for registering the data code by using the information fetching unit. For example, a remote control device corresponding to a new controlled device is operated to transmit a remote control signal as an infrared signal. The data code obtained by receiving the infrared signal at the information fetching unit 410a is associated with the operation key of the operation unit 420 and registered in the memory 431. In addition, the RFID tag 34 stores not only the device identification information but also a data code, and a signal indicating a request for the data code corresponding to the operated key is transmitted by radio waves from the remote control device. In response to the request for the data code corresponding to the operated key, the RFID tag 34 that has received the radio wave transmits the data code used in the controlled device via the radio wave. This radio wave is received by the information capture unit 410c of the remote control device, and the data code transmitted from the RFID tag 34 is associated with the operation key of the operation unit 420 and registered in the memory 431. Thus, the data code DM can be registered using the information fetching unit.

It is a figure which shows schematic structure of a 1st form. It is a figure which shows the structure of the identification information transmitter in a 1st form, and a remote control apparatus. It is a figure which shows the format of an information signal. It is a figure which shows the structure of the light reception module which enabled it to switch a directional characteristic. It is a flowchart which shows operation | movement of the remote control apparatus in a 1st form. It is a figure which shows schematic structure of a 2nd form. It is a figure which shows the structure of the identification information transmission apparatus in a 2nd form. It is a sequence diagram which shows the operation | movement of a 2nd form. It is a flowchart which shows operation | movement of the remote control apparatus in a 2nd form. It is a flowchart which shows operation | movement of the identification information transmission apparatus in a 2nd form. It is a figure which shows schematic structure of a 3rd form. It is a figure which shows the structure of the RFID tag and remote control apparatus in a 3rd form. It is a flowchart which shows operation | movement of the remote control apparatus in a 3rd form. It is a figure which shows schematic structure of a 4th form. It is a figure which shows the structure of the remote control apparatus in a 4th form.

Explanation of symbols

10a, 10b, 10c, 10d ... remote control system, 21, 22 ... controlled devices, 31, 33 ... identification information transmitting device, 34 ... RFID tag, 35 ... barcode, 40a , 40b, 40c, 40d ... remote control device, 211, 221 ... remote control signal receiving unit, 311, 331, 341 ... information signal generating unit, 312, 332, 342 ... communication unit, 333 ... Display unit, 410a, 410c, 410d ... Information capture unit, 420 ... Operation unit, 430a, 430c, 430d ... Signal generation unit, 440 ... Transmission unit

Claims (10)

In a remote control system comprising a remote control device and a controlled device controlled by the remote control device,
The controlled device has information presenting means for presenting device identification information unique to the controlled device,
The remote control device is
Information capturing means for capturing the device identification information;
An operation means for generating an operation signal according to a user operation;
When it is determined that a user operation has been performed based on the operation signal, a signal generation that generates a remote control signal used in the controlled device indicated by the device identification information captured by the information capturing unit according to the operation signal Means,
A remote control system comprising: a transmission unit configured to transmit the signal generated by the signal generation unit as a radio signal. The information presenting means includes
An information signal generation unit for generating an information signal indicating the device identification information;
A communication unit that transmits the information signal generated by the information signal generation unit as a radio signal;
The remote control system according to claim 1, wherein the device identification information is presented by transmitting the device identification information as a radio signal. When the signal generation means of the remote control device determines that a user operation has been performed based on the operation signal, the signal generation means generates a signal indicating a request for the device identification information and supplies the signal to the transmission means,
The communication unit of the information presentation unit receives a radio signal transmitted from the remote control device, and when the communication unit receives a signal indicating a request for the device identification information, the information signal generation unit The remote control system according to claim 2, wherein the device identification information is presented by generating a signal and transmitting the signal from the communication unit as a wireless signal. The communication unit of the information presenting means receives a radio signal transmitted from the remote control device,
3. The remote control system according to claim 2, wherein display means for displaying that the remote control signal has been received by the communication unit is provided in the information presentation means. 3. The remote control system according to claim 2, wherein the information fetching means of the remote control device is configured to be switchable in directivity when fetching the device identification information. The information fetching means of the remote control device has a communication unit that communicates with the communication unit of the information presenting means using radio waves,
When the signal generation means of the remote control device determines that a user operation has been performed based on the operation signal, the signal generation means transmits radio waves from the communication unit of the information capture means,
The information signal generating unit of the information presenting unit starts operation by receiving the radio wave transmitted from the communication unit of the information capturing unit by the communication unit, and transmits the generated information signal from the communication unit. The remote control system according to claim 2, wherein the device identification information is presented by transmission. The information presenting means presents the device identification information by displaying a code image indicating the device identification information,
2. The remote control system according to claim 1, wherein the information fetching means of the remote control device obtains the device identification information by reading the code image. 2. The remote control device according to claim 1, wherein the information capturing unit is provided in the remote control device so as to capture device identification information presented at a position in the transmission direction of the wireless signal in the transmitting unit. Remote control system. Information capturing means for capturing device identification information unique to the controlled device to be controlled;
An operation means for generating an operation signal according to a user operation;
When it is determined that a user operation has been performed based on the operation signal, a signal generation that generates a remote control signal used in the controlled device indicated by the device identification information captured by the information capturing unit according to the operation signal Means,
A remote control apparatus comprising: a transmission unit configured to transmit a signal generated by the signal generation unit as a radio signal. An information presentation step for presenting device identification information unique to the controlled device from the controlled device controlled by the remote control device;
An information capturing step for capturing the device identification information by the remote control device;
An operation signal generation step for generating an operation signal according to a user operation;
When it is determined that a user operation has been performed based on the operation signal, a signal generation that generates a remote control signal used in the controlled device indicated by the device identification information captured in the information capturing step according to the operation signal Process,
A remote control method comprising a transmission step of transmitting the signal generated in the signal generation step as a radio signal.

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