JP4690240B2 - Remote control system - Google Patents

Description

  The present invention relates to a remote control system including a remote control device capable of simultaneously transmitting a plurality of infrared signals and an electronic device operated by the remote control device.

Conventionally, remote control of a television or the like by an infrared remote controller has been generally performed. However, in recent years, mobile phones and the like are also equipped with a module for infrared communication, and infrared rays are applied to digital televisions and audio devices. Data transfer can be performed by communication. As infrared communication, there are various communication methods such as remote control communication for remote operation, IrDA, and IrSimple. By the way, in infrared communication, when infrared rays transmitting different data interfere with each other, the transmitted data cannot be transmitted accurately. In order to solve such a problem, in Patent Document 1, in a remote controller capable of transmitting and receiving an IrDA signal and a remote control signal, when the remote control signal is transmitted, the transmission of the IrDA signal is prohibited. An infrared communication device that prevents an IrDA signal and a remote control signal from interfering with each other is disclosed.
JP 2002-191085 A

  However, when infrared communication is controlled as in Patent Document 1, although there is no interference between the IrDA signal and the remote control signal, there is an inconvenience that the IrDA signal cannot be transmitted while the remote control signal is being transmitted.

  Therefore, in the present invention, a remote control system including a remote control device and an electronic device operated by the remote control device, the remote control device includes a plurality of infrared signal transmission units and a plurality of infrared signal source units. The electronic device provides a remote control system having an infrared signal receiving unit corresponding to a plurality of infrared signal transmitting units of the remote control device. The infrared signal transmitting unit corresponds to, for example, an infrared light emitting module, and the infrared signal source unit corresponds to a processing mechanism that performs processing for transmitting an infrared signal. Also, there may be a plurality of infrared signal source units, each of which may be a processing mechanism that performs processing such as modulation in order to transmit infrared signals of different communication methods such as remote control signals, IrDA signals, and IrSimple signals. In addition, the remote control device can perform connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units, that is, which communication system infrared signal is transmitted from each infrared signal transmission unit. It is possible to switch between these.

  FIG. 1 illustrates an outline of a remote control device according to the present invention. As shown in FIG. 1A, the remote control device (0100) includes a plurality of infrared signal transmission units (0101a, 0101b, 0101c, 0101d). Here, as shown in FIG. 1B, when infrared signals of different systems are output from the infrared signal transmission unit 0101b and the infrared signal transmission unit 0101c, there is an interference region (0102) where the mutual communication regions interfere with each other. . However, as shown in FIG. 1C, if connection control is performed so that infrared signals of different systems are output from the infrared signal transmission unit 0101a and the infrared signal transmission unit 0101c, the interference area becomes small, and interference may occur depending on the communication distance. The region no longer exists.

  In the remote control system according to the present invention, when the remote control device performs connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units, the plurality of infrared signal transmission units are connected to one electronic device. Connection control may be performed so as to transmit the same infrared signal. Further, a plurality of infrared signal transmission units may be controlled to transmit different infrared signals to one electronic device. Further, when connection control is performed, connection control may be performed so that the arrangement of the interference of infrared signals is small based on information relating to the communicable range and directivity of the infrared signal transmission unit. Further, in order to measure the reception intensity of the infrared signal in the electronic device, a command is transmitted to cause the remote control device to transmit the reception intensity measurement signal from each infrared signal transmission unit without overlapping. Also good. Furthermore, the electronic device may be configured to perform control for enabling or disabling some or all of the plurality of infrared signal receiving units in accordance with the measurement result of the reception intensity. In addition, the measurement result of the reception intensity at the electronic device is acquired by the remote control device, and control is performed to enable or disable some or all of the plurality of infrared signal transmission units according to the acquired measurement result. It may be. In addition, the electronic device determines whether the path through which the infrared signal transmitted from the remote control device is received by the infrared signal receiver of the electronic device is twisted based on the measurement result of the received intensity, and the determination result is determined by the remote control device. May be sent to. Furthermore, the remote control device may be configured to perform connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units based on the determination result of the twist relationship from the electronic device. In addition, the electronic device may include a plurality of reception signal processing units for processing received infrared signals according to the communication method, and connection control between the plurality of infrared signal reception units and the plurality of reception signal processing units. You may come to perform. Further, connection control between the plurality of infrared signal reception units and the plurality of reception signal processing units may be performed based on the determination result of the twist relationship.

  According to the remote control system of the present invention, the connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units can be performed by the remote control device. It is possible to transmit an infrared signal from the unit. Similarly, when performing connection control between a plurality of infrared signal reception units and a plurality of reception signal processing units in an electronic device, it is possible to receive an infrared signal from an optimal infrared signal reception unit depending on the interference state of the infrared signal, etc. Is possible.

The best mode for carrying out the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to these embodiments, and can be implemented in various modes without departing from the spirit of the present invention. The first embodiment will mainly describe claims 1, 12, and 13. The second embodiment will mainly describe claim 2 and the like. The third embodiment will mainly describe claim 3 and the like. The fourth embodiment will mainly describe claim 4 and the like. In the fifth embodiment, claims 5 and 14 will be mainly described. In the sixth embodiment, claims 6 and 15 will be mainly described. In the seventh embodiment, claims 7 and 16 will be mainly described. In the eighth embodiment, claims 8 and 17 will be mainly described. In the ninth embodiment, claims 9 and 18 will be mainly described. In the tenth embodiment, claims 10 and 19 will be mainly described. In the eleventh embodiment, claims 11 and 20 will be mainly described.
(Embodiment 1)

  (Embodiment 1: Overview) This embodiment is a remote control system including a remote control device and an electronic device operated by the remote control device. The remote control device includes a plurality of infrared signal transmission units and a plurality of infrared rays. A remote control system having a signal source unit and an electronic device having an infrared signal receiving unit corresponding to a plurality of infrared signal transmitting units of the remote control device will be described. Further, the remote control device can control connection between a plurality of infrared signal source units and a plurality of infrared signal transmission units.

  (Embodiment 1: Configuration) FIG. 2 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (0200) and an electronic device (0220). The remote control device (0200) may be an infrared remote control dedicated to remote operation, or may be a mobile terminal such as a mobile phone capable of transmitting and receiving infrared signals. The electronic device (0220) may be any electronic device that can transmit and receive infrared signals. The remote control device (0200) and the electronic device (0220) can communicate with each other by infrared communication. Hereinafter, the configuration of the remote control device (0200) and the configuration of the electronic device (0220) will be described.

  Note that each unit, which is a component of the present invention described in detail below, is configured by either hardware, software, or both hardware and software. For example, as an example for realizing these, when a computer is used, there are hardware constituted by a CPU, a bus, a memory, an interface, a peripheral device, and the like, and software that can be executed on the hardware. As software, the functions of each unit are realized by sequentially executing a program developed on the memory, and processing, storing, and outputting data on the memory and data input via the interface. It is also possible to record such software (program) on a medium such as an optical disk. More specifically, FIG. 35 is a diagram illustrating the configuration of a general computer. The computer mainly includes a CPU (3510), an input / output interface (I / O) (3520), an HDD (3530), and a RAM (3540). ), ROM (3550), etc., but the remote control device and the electronic device according to the present invention can be realized by the same configuration as in FIG. (Same throughout this specification). (The same applies throughout the specification.)

  (Embodiment 1: Configuration of a remote control device) The remote control device (0200) includes a plurality of infrared signal transmission units (0201), a plurality of infrared signal source units (0202), and a transmission connection control unit (0203). .

  A plurality of “infrared signal transmitters” (0201) exist in the remote control device (0200) and can operate at least simultaneously. “Simultaneous operation” means that a plurality of infrared signal transmission units operate simultaneously, and infrared signals representing the same transmission data may be transmitted simultaneously, or infrared signals representing different transmission data may be transmitted simultaneously. May be. Further, since simultaneous operation is “possible”, it is not always necessary to operate simultaneously. The infrared signal transmitting unit corresponds to, for example, an infrared light emitting module. Since the operation of the infrared light emitting module is a generally well-known technique, a detailed description thereof will be omitted.

  There are a plurality of “infrared signal source units” (0202) in the remote control device (0200), and a processing mechanism or the like for performing processing for transmitting an infrared signal is applicable. The processing for transmitting an infrared signal corresponds to, for example, buffering for holding transmission data as serial data, processing for converting serial data into an infrared signal, and the like. A processing mechanism or the like that executes only a part of these processes may be used. The plurality of infrared signal sources may be signal sources of different communication methods. That is, each may be a processing mechanism that processes infrared signals of different communication methods such as a remote control signal, an IrDA signal, and an IrSimple signal. Specifically, the infrared signal source unit reads transmission data such as audio data and image data stored in a predetermined storage area such as a RAM, and modulates the transmission data into an infrared signal according to a communication method. The modulated infrared signal is output from the infrared signal transmission unit (0201). The infrared signal source unit may include a program for causing the CPU to execute such processing.

  The “transmission connection control unit” (0203) has a function of controlling connection between the plurality of infrared signal source units (0202) and the plurality of infrared signal transmission units (0201). That is, it is possible to switch which communication method of infrared signal is transmitted from each infrared signal transmission unit (0201) by the transmission connection control unit. Connection control may be performed so that a plurality of infrared signals of different communication methods are transmitted from the plurality of infrared signal transmission units (0201), or connection control may be performed so that infrared signals of only one communication method are transmitted. Good. Furthermore, when transmitting an infrared signal of only one communication method, an infrared signal representing different transmission data may be transmitted from each infrared signal transmission unit (0201), or each infrared signal transmission unit Infrared signals representing the same transmission data may be transmitted in synchronization with (0201). In addition, the infrared signal transmission unit (0201) may be controlled so as not to transmit an infrared signal by cutting the connection.

  FIG. 3 shows an example of processing in the transmission connection control unit. FIG. 3 illustrates a case where there are four infrared signal transmission units (0301a, 0301b, 0301c, 0301d) and two infrared signal source units (0303a, 0303b). Further, it is assumed that the infrared signal source units (0303a, 0303b) are a remote control signal and IrSimple signal processing mechanism. As illustrated in FIG. 3, the transmission connection control unit (0302) can switch the connection between the two infrared signal source units and the four infrared signal transmission units by switching, for example. In FIG. 3, the infrared signal transmission unit 0301a and the infrared signal transmission unit 0301c are connected to the remote control signal processing mechanism and the like, and the infrared signal transmission unit 0301b and the infrared signal transmission unit 0301d are connected to the IrSimple signal processing mechanism and the like. ing. Therefore, a remote control signal is transmitted from the infrared signal transmission unit 0301a and the infrared signal transmission unit 0301c, and an IrSimple signal is transmitted from the infrared signal transmission unit 0301b and the infrared signal transmission unit 0301d. The transmission connection control unit may include a program for causing the CPU to execute such processing.

  (Embodiment 1: Configuration of Electronic Device) The electronic device (0220) has an infrared signal receiver (0221).

  The “infrared signal receiver” (0221) has a function of receiving an infrared signal, and corresponds to each of the plurality of infrared signal transmitters (0201) of the remote control device (0200). “Corresponding to a plurality of infrared signal transmission units of the remote control device” means that one or more infrared signals of one or more communication methods transmitted from the infrared signal transmission unit (0201) of the remote control device can be received. Therefore, the number of infrared signal transmitting units (0201) and the number of infrared signal receiving units of the remote control device need not be the same. For example, when infrared signals of the same communication method are transmitted from two infrared signal transmission units (0201), the infrared signal may be received by one infrared signal reception unit, or one infrared signal transmission unit ( The infrared signal transmitted from (0201) may be received by a plurality of infrared signal receiving units. The infrared signal receiving unit corresponds to, for example, an infrared light receiving module. Since the operation of the infrared light receiving module is a generally well-known technique, a detailed description thereof will be omitted.

  (Embodiment 1: Process Flow) FIG. 4 illustrates a sequence diagram showing a process flow in the remote control system according to the present embodiment.

  First, in step S0401, connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. Next, in step S0402, an infrared signal is transmitted. This process is mainly executed by the infrared signal transmitter. Next, in step S0403, the electronic device receives an infrared signal. This process is mainly executed by the infrared signal receiver.

(Embodiment 1: Effect) The remote control system according to the present embodiment performs transmission control from each infrared signal transmission unit by performing connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units in the remote control device. Infrared signal can be switched.
(Embodiment 2)

  (Embodiment 2: Overview) In this embodiment, when connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by a remote control device, the plurality of infrared signal transmission units are integrated into one electronic device. A remote control system that performs connection control so as to transmit the same infrared signal will be described.

  (Embodiment 2: Configuration) FIG. 5 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (0500) and an electronic device (0520). The remote control system according to this embodiment has a configuration in which the same signal transmission control means (0504) is added to the transmission connection control unit of the remote control device (0500) in addition to the configuration of the remote control system described in the first embodiment.

  (Embodiment 2: Configuration of remote control device) The remote control device (0500) includes a plurality of infrared signal transmission units (0501), a plurality of infrared signal source units (0502), and a transmission connection control unit (0503). . The transmission connection control unit (0503) includes the same signal transmission control means (0504).

  "Same signal transmission control means" (0504) controls each of the plurality of infrared signal transmission units (0501) of the remote control device (0500) to transmit the same infrared signal to one electronic device (0520). It has a function. “Send the same infrared signal” means to simultaneously transmit infrared signals representing the same transmission data. Therefore, the same signal transmission control means also performs processing for synchronizing each infrared signal transmission unit (0501). In addition, not all of the plurality of infrared signal transmission units (0501), only some of the infrared signal transmission units (0501) transmit the same infrared signal, and the other infrared signal transmission units (0501) do not transmit the infrared signal. It may be like this.

  FIG. 6 shows an example of processing in the same signal transmission control means. FIG. 6 illustrates a case where there are four infrared signal transmission units (0601a, 0601b, 0601c, 0601d) and two infrared signal source units (0603a, 0603b). Further, it is assumed that the infrared signal source units (0603a, 0603b) are a remote control signal and IrSimple signal processing mechanism. In the same signal transmission control means (0602), as illustrated in FIG. 6, all infrared signal transmissions 0601a, 0601b, 0601c, 0601d are connected to a remote control signal processing mechanism or the like. Therefore, remote control signals are transmitted from all infrared signal transmission units 0601a, 0601b, 0601c, and 0601d.

  FIG. 32 is an example diagram showing effects expected by the same signal transmission control means. FIG. 32 illustrates a case where an infrared signal is not transmitted from the infrared signal transmission unit 3201a of the remote control device (3200) and the same infrared signal is transmitted from the infrared signal transmission units 3201b, 3201c, and 3201d. In this case, since the communicable ranges of the infrared signal transmission units 3201b, 3201c, and 3201d overlap, the hatched area 3202 becomes the communicable range, so that the infrared signal communicable range is substantially expanded. Thereby, for example, even if a part of the communicable range becomes impossible to communicate due to the presence of an obstacle or the like, the possibility that the infrared signal can reach the other communicable range increases.

  (Embodiment 2: Configuration of Electronic Device) The electronic device (0520) has an infrared signal receiving unit (0521). The configuration of the electronic device (0520) is the same as the configuration of the electronic device described in the first embodiment.

  (Embodiment 2: Process Flow) The process flow in the remote control system according to this embodiment is the same as the process flow in the remote control system according to the first embodiment illustrated in FIG. However, when the connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units is performed in step S0401, the plurality of infrared signal transmission units transmit the same infrared signal to one electronic device. Connection control is performed.

(Embodiment 2: Effect) The remote control system according to this embodiment can simultaneously transmit the same transmission data from a plurality of infrared signal transmission units of the remote control device, so that the infrared communication ranges overlap, One transmission data can be transmitted in a wider communication range.
(Embodiment 3)

  (Embodiment 3: Overview) In this embodiment, when connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by a remote control device, the plurality of infrared signal transmission units are combined into one electronic device. A remote control system that performs connection control so as to transmit different infrared signals will be described.

  (Embodiment 3: Configuration) FIG. 7 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (0700) and an electronic device (0720). The remote control system according to the present embodiment has a configuration in which a different signal transmission control means (0705) is added to the transmission connection control unit of the remote control device (0700) in addition to the configuration of the remote control system described in the first or second embodiment. . FIG. 7 illustrates a configuration in which the above-described configuration requirements are added to the configuration of the remote control system described in the first embodiment.

  (Embodiment 3: Configuration of remote control device) The remote control device (0700) includes a plurality of infrared signal transmission units (0701), a plurality of infrared signal source units (0702), and a transmission connection control unit (0703). . The transmission connection control unit (0703) includes different signal transmission control means (0705). Furthermore, the transmission connection control unit (0703) may have the same signal transmission control means.

  The “different signal transmission control means” (0705) controls each of the plurality of infrared signal transmission units (0701) of the remote control device (0700) to transmit different infrared signals to one electronic device (0720). It has a function. “Different infrared signals” means that the transmission data represented is different infrared signals. In addition, not all of the plurality of infrared signal transmission units (0701), but only some infrared signal transmission units (0701) transmit different infrared signals, and the other infrared signal transmission units (0701) transmit infrared signals. You may not be.

  FIG. 8 shows an example of processing in the different signal transmission control means. FIG. 8 illustrates a case where there are four infrared signal transmission units (0801a, 0801b, 0801c, 0801d) and two infrared signal source units (0803a, 0803b). Further, it is assumed that the infrared signal source units (0803a, 0803b) are a remote control signal and IrSimple signal processing mechanism. The different signal transmission control means (0802) connects the infrared signal transmission units 0801a and 0801b to the remote control signal processing mechanism and the like, and the infrared signal transmission unit 0801c to the IrSimple signal processing mechanism and the like. In addition, the infrared signal transmission unit 0801d is disconnected, and the infrared signal is not transmitted.

  (Embodiment 3: Configuration of Electronic Device) The electronic device (0720) has an infrared signal receiving unit (0721). The configuration of the electronic device (0720) is the same as the configuration of the electronic device described in the first or second embodiment.

  (Third Embodiment: Process Flow) The process flow in the remote control system according to this embodiment is the same as the process flow in the remote control system according to the first embodiment illustrated in FIG. However, when performing connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units in step S0401, the plurality of infrared signal transmission units transmit different infrared signals to one electronic device. Connection control is performed.

(Embodiment 3: Effect) The remote control system according to this embodiment can transmit different transmission data simultaneously or at different timings from a plurality of infrared signal transmission units of the remote control device.
(Embodiment 4)

  (Embodiment 4: Overview) This embodiment relates to a communicable range and directivity of an infrared signal transmission unit when connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by a remote control device. A remote control system that performs connection control based on information or the like so that an arrangement with less interference of infrared signals will be described.

  (Embodiment 4: Configuration) FIG. 9 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (0900) and an electronic device (0920). The remote control system according to the present embodiment has the same configuration as the remote control system described in any one of the first to third embodiments. The transmission connection control unit of the remote control device (0900) includes a transmission unit attribute information holding unit (0906) and attribute dependency. The connection control means (0907) is added. FIG. 9 illustrates a configuration obtained by adding these configuration requirements to the configuration of the remote control system described in the first embodiment.

  (Embodiment 4: Configuration of remote control device) The remote control device (0900) includes a plurality of infrared signal transmission units (0901), a plurality of infrared signal source units (0902), and a transmission connection control unit (0903). . The transmission connection control unit (0903) includes a transmission unit attribute information holding unit (0906) and an attribute dependent connection control unit (0907). Further, the transmission connection control unit (0903) may have the same signal transmission control means and / or different signal transmission control means.

  “Transmitter attribute information holding means” (0906) has a function of holding transmitter attribute information including infrared effective transmission range information of the infrared signal transmitter (0901). The infrared effective transmission range information mainly corresponds to, for example, infrared communicable distance, communicable angle, and the like. The transmission unit attribute information may be configured only by infrared effective transmission range information, or may include other information.

  FIG. 10 shows an example of the transmission unit attribute information. As illustrated in FIG. 10A, the transmission unit attribute information includes, for example, information such as “communicable distance” and “communicable angle”. Here, the “communicable distance” represents a distance L at which infrared rays transmitted from the infrared signal transmission unit (1001) in FIG. 10B can communicate, and the “communicable angle” represents directivity. Represents the angle θ. 10A indicates that the communicable distance L is 7 meters and the communicable angle θ is 15 degrees. The transmission unit attribute information holding unit is realized by holding such transmission unit attribute information in a predetermined storage area such as a RAM or an HDD.

  The “attribute-dependent connection control means” (0907) is configured to arrange the plurality of infrared signal sources so that the infrared signal interference is reduced based on the transmission part attribute information held in the transmission part attribute information holding means (0906). Unit (0902) and the plurality of infrared signal transmission units (0901).

  FIG. 33 shows an example of processing in the attribute-dependent connection control means. As illustrated in FIG. 33A, when the distance between the two infrared signal transmission units (3301) is x, and the communicable distance L and the communicable angle θ, the length α = L × tan θ. When x <2α, the infrared effective transmission ranges of the two infrared signal transmission units (3301) interfere with each other. When x ≧ 2α, the infrared effective transmission ranges of the two infrared signal transmission units (3301) do not interfere. Therefore, as illustrated in FIG. 33B, when the remote control device (3300) includes four infrared signal transmission units (3301a, 3301b, 3301c, 3301d), the distance between the infrared signal transmission units is physical. For example, when the distance between the infrared signal transmitters 3301a and 3301c is less than 2α, the infrared signal interferes, and is illustrated in FIG. 33C. Thus, control such as transmitting infrared signals from 3301a and 3301d is performed.

  (Embodiment 4: Configuration of Electronic Device) The electronic device (0920) has an infrared signal receiver (0921). The configuration of the electronic device (0920) is the same as the configuration of the electronic device described in any one of the first to third embodiments.

  (Embodiment 4: Process Flow) The process flow in the remote control system according to the present embodiment is the same as the process flow in the remote control system according to the first embodiment illustrated in FIG. However, when the connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units is performed in step S0401, interference of the infrared signal is caused based on information on the communicable range and directivity of the infrared signal transmission unit. It is characterized in that connection control is performed so as to reduce the number of arrangements.

(Embodiment 4: Effect) The remote control system according to this embodiment performs connection control between the infrared signal source unit and the infrared signal transmission unit so that there is less interference of infrared signals transmitted from a plurality of infrared signal transmission units of the remote control device. Since it can be performed, for example, even when different transmission data is simultaneously transmitted from a plurality of infrared signal transmission units, there is a high possibility that each transmission data is accurately transmitted.
(Embodiment 5)

  (Embodiment 5: Overview) In this embodiment, in order to measure the reception intensity of an infrared signal in an electronic device, the reception intensity measurement signal is transmitted from each infrared signal transmission unit so as not to overlap with the remote control device. A remote control system capable of transmitting commands will be described.

  (Embodiment 5: Configuration) FIG. 11 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (1100) and an electronic device (1120). In the remote control system according to this embodiment, in addition to the configuration of the remote control system described in any one of the first to fourth embodiments, the electronic device (1120) includes a reception intensity measurement signal transmission command output unit (1122) and a reception intensity. The remote control device (1100) includes a measurement unit (1123), and the reception intensity measurement signal transmission control unit (1108). FIG. 11 illustrates a configuration obtained by adding these configuration requirements to the configuration of the remote control system described in the first embodiment.

  (Embodiment 5: Configuration of Remote Control Device) A remote control device (1100) includes a plurality of infrared signal transmission units (1101), a plurality of infrared signal source units (1102), a transmission connection control unit (1103), and reception intensity. A measurement signal transmission control unit (1108). Further, the transmission connection control unit (1103) may have the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be configured such that the transmission connection control unit (1103) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit.

  The “reception intensity measurement signal transmission control unit” (1108) has a function of transmitting the reception intensity measurement signals from the respective infrared signal transmission units (1101) so as not to overlap in accordance with the received reception intensity measurement signal transmission command. Have "Received reception strength measurement signal transmission command" refers to a reception strength measurement signal transmission command output from the reception strength measurement signal transmission command output unit (1122) of the electronic device (1120) described in detail later. This is information for instructing transmission of a reception intensity measurement signal from the electronic device to the remote control device.

  FIG. 12 shows an example of a reception intensity measurement signal transmission command. The reception intensity measurement signal transmission command is realized by information such as “command =“ test_signal ””, for example. Here, “command” is a variable on the program for representing the command content from the electronic device to the remote control device, and the value of this variable represents the command content. That is, here, the value “test_signal” is a content for instructing transmission of a reception intensity measurement signal from the electronic device to the remote control device.

  The “reception strength measurement signal” is an infrared signal for measuring the reception strength of the infrared signal transmitted from the remote control device in the electronic device, and transmits, for example, predetermined special test data. If it is an infrared signal, it may be convenient because it can be determined that the signal is an infrared signal for measuring reception intensity. “Transmit the reception intensity measurement signals so that they do not overlap” means that the plurality of reception intensity measurement signals are transmitted so that they do not interfere. If the reception intensity measurement signal is transmitted, there is no interference. In addition, when the infrared signals transmitted from a plurality of infrared signal transmission units are in a positional relationship such that they do not interfere with each other, the reception intensity measurement signals may be transmitted simultaneously from the plurality of infrared signal transmission units. Good. In addition, when transmitting a reception intensity measurement signal, other infrared communication transmitted from the infrared signal transmission unit may be temporarily stopped. This is to prevent interference between other infrared communication and the received intensity measurement signal. The communication for the reception intensity measurement signal transmission control unit to receive the reception intensity measurement signal transmission command need not be limited to infrared communication. It may be wired communication or wireless communication. As long as wireless communication is used, Bluetooth (registered trademark), wireless LAN, or the like may be used in addition to infrared communication. Specific processing of the reception intensity measurement signal transmission control unit includes, for example, infrared rays performed by a plurality of infrared signal transmission units triggered by reception of a reception intensity measurement signal transmission command via a communication interface. The transmission of the signal is paused and the timer is reset to 0 and started. By outputting a command for transmitting a reception intensity measurement signal to one infrared signal transmission unit, the reception intensity measurement signal is transmitted from the one infrared signal transmission unit. When the timer reaches a predetermined value, the timer is reset to 0 and started, and a command for transmitting a reception intensity measurement signal to another infrared signal transmission unit is output. When the timer reaches a predetermined value, all the infrared signals indicate that the timer is reset to 0 and started, and a command for transmitting a reception intensity measurement signal to another infrared signal transmission unit is output. Repeat for the transmitter. Further, the reception intensity measurement signal transmission control unit may include a program for causing the CPU to execute such processing.

  (Embodiment 5: Configuration of Electronic Device) The electronic device (1120) includes an infrared signal receiving unit (1121), a reception intensity measurement signal transmission command output unit (1122), and a reception intensity measurement unit (1123). Have.

  The “reception strength measurement signal transmission command output unit” (1122) has a function of outputting a reception strength measurement signal transmission command to the remote control device (1100). The communication for the reception intensity measurement signal transmission command output unit to transmit the reception intensity measurement signal transmission command may be wired communication or wireless communication. As long as wireless communication is used, Bluetooth (registered trademark), wireless LAN, or the like may be used in addition to infrared communication. In addition, when transmitting a signal transmission command for reception intensity measurement by infrared communication, it may be transmitted at a time from a plurality of infrared transmission modules or the like. This is to ensure that a signal transmission command for reception intensity measurement is transmitted to the remote control device (1100). As specific processing of the reception strength measurement signal transmission command output unit, for example, a reception strength measurement signal transmission command is read from a predetermined storage area such as a RAM, and the read reception strength measurement signal transmission command is transmitted to a communication interface. Send through. The reception intensity measurement signal transmission command output unit may include a program for causing the CPU to execute such processing.

  The “reception intensity measurement unit” (1123) uses the infrared signal reception unit (1121) to receive a plurality of reception intensity measurement signals transmitted from the remote control device (1100) in response to the transmitted reception intensity measurement signal transmission command. It has a function of receiving and measuring the reception intensity of a plurality of reception intensity measurement signals by executing the same gain control for each. The “transmitted reception strength measurement signal transmission command” refers to a reception strength measurement signal transmission command transmitted from the reception strength measurement signal transmission command output unit (1122). “Perform equivalent gain control” corresponds to a case where gain control is performed at the same rate for all reception intensity measurement signals, or a case where no gain control is performed at all. When the automatic gain control (ACG) is applied to the received infrared signal as in the prior art, the amplitude of the infrared signal is amplified to a certain amplitude, so that it is not possible to know how much the actual reception intensity is. Therefore, the actual reception strength can be measured if no amplification is performed on all reception strength measurement signals. Further, if the gain control is performed at the same rate, such as doubling all reception strength measurement signals, it is possible to measure the relative reception strength. The reception strength may be a value indicated by using a unit such as “mW / sr (milliwatt / steradian)”, or may be a special reception by converting the value into, for example, 10 reception strength levels. It may be expressed as an intensity index. As specific processing of the reception intensity measurement unit, first, the infrared signal reception unit receives a reception intensity measurement signal, performs gain control on the received reception intensity measurement signal, and outputs the result to RAM or HDD. Or the like in a predetermined storage area. This is repeated for each infrared signal receiver. The reception intensity measurement unit may include a program for causing the CPU to execute such processing.

  (Embodiment 5: Process Flow) FIG. 13 exemplifies a sequence diagram showing a process flow in a remote control system according to this embodiment.

  First, in step S1301, connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. In step S1304, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S1305, the remote control apparatus receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 1306, the reception intensity measurement signals are transmitted from the respective infrared signal transmission units so as not to overlap. This process is mainly executed by the infrared signal transmitter. In step S1307, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S1308, the reception intensity is measured by executing equivalent gain control for each reception intensity measurement signal. This process is mainly executed by the reception intensity measurement unit.

(Embodiment 5: Effect) The remote control system according to this embodiment measures the reception intensity of each infrared signal in an electronic device by transmitting reception intensity measurement signals from a plurality of infrared signal transmission units of the remote control device. be able to. Thus, for example, when the same infrared signal is received by a plurality of infrared signal receivers and the reception sensitivity is high, only some of the infrared signal receivers are operated, or some infrared signals are received. It is possible to reduce energy consumption in the remote control device or the electronic device by operating only the signal receiving unit. Also,
(Embodiment 6)

  (Embodiment 6: Overview) In this embodiment, a remote controller is configured to perform control for enabling or disabling part or all of a plurality of infrared signal reception units in accordance with a measurement result of reception intensity in an electronic device. The system will be described.

  (Embodiment 6: Configuration) FIG. 14 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (1400) and an electronic device (1420). In the remote control system according to the present embodiment, in addition to the configuration of the remote control system described in the fifth embodiment, the electronic device (1420) includes a first effectiveness control unit (1424).

  (Embodiment 6: Configuration of Remote Control Device) A remote control device (1400) includes a plurality of infrared signal transmission units (1401), a plurality of infrared signal source units (1402), a transmission connection control unit (1403), and reception intensity. A measurement signal transmission control unit (1408). Further, the transmission connection control unit (1403) may include the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be a configuration in which the transmission connection control unit (1403) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit. The configuration of the remote control device (1400) is the same as the configuration of the remote control device described in the fifth embodiment.

  (Embodiment 6: Configuration of Electronic Device) An electronic device (1420) includes an infrared signal receiving unit (1421), a reception intensity measurement signal transmission command output unit (1422), a reception intensity measuring unit (1423), And an effectiveness control unit (1424).

  The “first effectiveness control unit” (1424) is a function for enabling or disabling part or all of the plurality of infrared signal receiving units (1421) according to the measurement result of the reception intensity measuring unit (1423). Have “Enabling or disabling part or all of a plurality of infrared signal reception units according to the measurement result of the reception intensity measurement unit” means, for example, two infrared signal reception units receiving the same infrared signal If both received intensities in (1421) are equal to or greater than a certain threshold value, it is determined that both infrared signals are not interfering with other infrared signals, and one of the two infrared signal receiving units is invalidated. In this case, the infrared signal is received only on the other side. Thereby, it is possible to reduce energy consumption in the electronic device (1420).

  FIG. 34 shows a specific example of processing in the first effectiveness control unit. As illustrated in FIG. 34A, the remote control device (3400) includes four infrared signal transmission units (S1, S2, S3, S4), and the electronic device (3410) includes four infrared signal reception units. (R1, R2, R3, R4) are provided. Also, the reception intensity measurement signal is transmitted in order from each infrared signal transmission unit (S1, S2, S3, S4), and the received reception intensity measurement signal is transmitted to each infrared signal reception unit (R1, R2, R3, R4). It is assumed that the result of the reception intensity received and measured at (1) is a value as shown in FIG. Here, when the threshold value is 0.7 and the reception intensity is 0.7 or more, the infrared signal is valid, and when the reception intensity is less than 0.7, the infrared signal is invalid. To do. Here, for example, if the infrared signal transmitting unit transmitting the infrared signal is only S2, the infrared signal receiving units R1, R2, and R3 can receive the infrared signal. If R1 and R2 are invalid as valid, energy consumption can be saved. For example, when different infrared signals are transmitted from the infrared signal transmission units S2 and S3, the infrared signals interfere with each other even if the infrared signal reception units R2 and R3 are enabled. Can be enabled.

  “Valid” means that the infrared signal receiver (1421) can receive an infrared signal, and “invalid” means that the infrared signal receiver (1421) cannot receive an infrared signal. Means. In order to disable the infrared signal receiving unit, for example, when the infrared signal receiving unit itself is not operated by stopping the power supply to the infrared signal receiving unit, the infrared signal received by the infrared signal receiving unit is used. It may be a case where the connection to the processing mechanism for processing the signal is substantially invalidated by cutting off the connection. As a specific process of the first effectiveness control unit, for example, the reception intensity measurement unit reads and compares the threshold value with the reception intensity stored in a predetermined storage area such as a RAM or an HDD. The comparison result is stored in a predetermined storage area such as a RAM. Further, a comparison result is read from a predetermined storage area such as a RAM, and processing for stopping power supply to a predetermined infrared signal receiving unit is performed according to the comparison result. The first effectiveness control unit may include a program for causing the CPU to execute such processing.

  (Sixth Embodiment: Process Flow) FIG. 15 illustrates a sequence diagram showing a process flow in the remote control system according to the present embodiment.

  First, in step S1501, the remote controller controls connection between the plurality of infrared signal source units and the plurality of infrared signal transmission units. This process is mainly executed by the transmission connection control unit. In step S1504, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S1505, the remote control apparatus receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 1506, the reception intensity measurement signals are transmitted from the respective infrared signal transmission units so as not to overlap. This process is mainly executed by the infrared signal transmitter. In step S1507, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S1508, the reception strength is measured by executing equivalent gain control for each reception strength measurement signal. This process is mainly executed by the reception intensity measurement unit. Next, in step S1509, some or all of the plurality of infrared signal reception units are validated or invalidated according to the measurement result of the reception intensity. This process is mainly executed by the first effectiveness control unit.

(Embodiment 6: Effect) The remote control system according to this embodiment can enable or disable each infrared signal receiver in accordance with the measurement result of the received intensity measuring unit in the electronic device. In the case where the received intensity is strong, it is possible to reduce energy consumption in the electronic device by disabling some of the infrared signal receivers.
(Embodiment 7)

  (Embodiment 7: Overview) In the present embodiment, a measurement result of reception intensity at an electronic device is acquired by a remote control device, and some or all of a plurality of infrared signal transmission units are enabled according to the acquired measurement result. Alternatively, a remote control system that performs control for invalidation will be described.

  (Embodiment 7: Configuration) FIG. 16 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (1600) and an electronic device (1620). In the remote control system according to this embodiment, in addition to the configuration of the remote control system described in the fifth or sixth embodiment, the remote control device (1600) has a measurement result acquisition unit (1609), and the transmission connection control unit (1603) Second effectiveness control means (1610) is included. FIG. 16 illustrates a configuration obtained by adding these configuration requirements to the configuration of the remote control system described in the fifth embodiment.

  (Embodiment 7: Configuration of Remote Control Device) A remote control device (1600) includes a plurality of infrared signal transmission units (1601), a plurality of infrared signal source units (1602), a transmission connection control unit (1603), and reception intensity. A measurement signal transmission control unit (1608) and a measurement result acquisition unit (1609); The transmission connection control unit (1603) includes second effectiveness control means (1610). Further, the transmission connection control unit (1603) may have the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be configured such that the transmission connection control unit (1603) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit.

  The “measurement result acquisition unit” (1609) has a function of acquiring the measurement result in the reception intensity measurement unit (1623) of the electronic device. That is, the measurement result measured by the reception intensity measurement unit (1623) of the electronic device (1620) is transmitted by communication or the like and acquired by the measurement result acquisition unit. When the measurement result is transmitted, it may be transmitted by wired communication or wireless communication. As long as wireless communication is used, Bluetooth (registered trademark), wireless LAN, or the like may be used in addition to infrared communication. As a specific process of the measurement result acquisition unit, for example, the reception intensity acquired via the communication interface is stored in a predetermined storage area such as a RAM or an HDD. Further, the measurement result acquisition unit may include a program for causing the CPU to execute such processing.

  The “second validity control unit” (1610) has a function of enabling or disabling part or all of the plurality of infrared signal transmission units (1601) according to the acquired measurement result. “Enabling or disabling part or all of the plurality of infrared signal transmission units according to the acquired measurement results” means, for example, when different infrared signals are transmitted from the plurality of infrared signal transmission units (1601). Is a case where only the infrared signal transmission unit (1601) determined not to interfere with each other is enabled and the other infrared signal transmission unit (1601) is disabled. Thereby, it is possible to reduce energy consumption in the remote control device (1600).

  FIG. 34 shows a specific example of processing in the second effectiveness control means. As illustrated in FIG. 34A, the remote control device (3400) includes four infrared signal transmission units (S1, S2, S3, S4), and the electronic device (3410) includes four infrared signal reception units. (R1, R2, R3, R4) are provided. Also, the reception intensity measurement signal is transmitted in order from each infrared signal transmission unit (S1, S2, S3, S4), and the received reception intensity measurement signal is transmitted to each infrared signal reception unit (R1, R2, R3, R4). It is assumed that the result of the reception intensity received and measured at (1) is a value as shown in FIG. Here, when the threshold value is 0.7 and the reception intensity is 0.7 or more, the infrared signal is valid, and when the reception intensity is less than 0.7, the infrared signal is invalid. To do. Here, when two different infrared signals are transmitted simultaneously, if they are transmitted by the infrared signal transmitters S1 and S3, or S1 and S4, or S2 and S4, the infrared signals do not interfere with each other.

Further, “valid” means that the infrared signal transmission unit (1601) can transmit infrared signals, and “invalid” means that the infrared signal transmission unit (1601) cannot transmit infrared signals. Means. For example, when the infrared signal transmitter is disabled, the infrared signal transmitter is not operated by stopping the power supply to the infrared signal transmitter. It may be a case where the connection to the processing mechanism for processing the signal is substantially invalidated by cutting off the connection. As specific processing of the second validity control means, for example, the measurement result acquisition unit reads and compares the received intensity stored in a predetermined storage area such as a RAM or HDD with a threshold value. The comparison result is stored in a predetermined storage area such as a RAM. Further, a comparison result is read from a predetermined storage area such as a RAM, and processing for stopping power supply to a predetermined infrared signal transmission unit is performed according to the comparison result. Further, the second effectiveness control unit may include a program for causing the CPU to execute such processing.

  (Embodiment 7: Configuration of Electronic Device) The electronic device (1620) includes an infrared signal receiving unit (1621), a reception intensity measurement signal transmission command output unit (1622), and a reception intensity measuring unit (1623). Have. Furthermore, the electronic device (1620) may have a first effectiveness control unit. That is, the configuration of the electronic device (1620) is the same as the configuration of the electronic device described in the fifth or sixth embodiment.

  (Embodiment 7: Process Flow) FIG. 17 illustrates a sequence diagram illustrating a process flow in the remote control system according to the present embodiment.

  First, in step S1701, connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. In step S1704, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S1705, the remote control apparatus receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 1706, the received intensity measurement signals are transmitted from the respective infrared signal transmitters so as not to overlap. This process is mainly executed by the infrared signal transmitter. In step S1707, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S1708, the reception strength is measured by executing equivalent gain control for each reception strength measurement signal. This process is mainly executed by the reception intensity measurement unit. In step S1709, the reception strength measurement result is output. Next, in step S1710, the measurement result of the reception intensity is acquired by the remote control device. This process is mainly executed by the measurement result acquisition unit. Next, in step S1711, some or all of the plurality of infrared signal transmission units are validated or invalidated according to the acquired measurement results. This process is mainly executed by the second effectiveness control means.

(Embodiment 7: Effect) In the remote control system according to this embodiment, in the remote control device, each infrared signal transmission unit can be enabled or disabled according to the measurement result of the reception intensity at the electronic device. When the reception intensity of the infrared signal is strong, it is possible to reduce energy consumption in the remote control device by disabling some of the infrared signal transmission units. The remote control device is particularly effective because it is often driven by a battery.
(Embodiment 8)

  (Embodiment 8: Overview) In this embodiment, the electronic device is based on the measurement result of the received intensity, and the path through which the infrared signal transmitted from the remote control device is received by the infrared signal receiver of the electronic device is twisted. A remote control system is described in which a determination is made and the determination result is transmitted to the remote control device.

  (Embodiment 8: Configuration) FIG. 18 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (1800) and an electronic device (1820). In the remote control system according to this embodiment, in addition to the configuration of the remote control system described in any one of the fifth to seventh embodiments, the electronic device (1820) includes a twist relationship determination unit (1825) and a twist relationship determination result transmission unit ( 1826). FIG. 18 illustrates a configuration in which these configuration requirements are added to the configuration of the remote control system described in the fifth embodiment.

  (Embodiment 8: Configuration of remote control device) A remote control device (1800) includes a plurality of infrared signal transmission units (1801), a plurality of infrared signal source units (1802), a transmission connection control unit (1803), and reception intensity. A measurement signal transmission control unit (1808). Further, the remote control device (1800) may include a measurement result acquisition unit, and the transmission connection control unit (1803) may include a second effectiveness control unit. In addition, each of the above-described configurations may further include the transmission connection control unit (1803) having the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be a configuration in which the transmission connection control unit (1803) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit. That is, the configuration of the remote control device (1800) is the same as the configuration of the remote control device described in any one of the fifth to seventh embodiments.

  (Embodiment 8: Configuration of Electronic Device) An electronic device (1820) includes an infrared signal receiving unit (1821), a reception intensity measurement signal transmission command output unit (1822), a reception intensity measuring unit (1823), and a twist. A relationship determination unit (1825) and a torsional relationship determination result transmission unit (1826). Furthermore, the electronic device (1820) may have a first effectiveness control unit.

  The “twist relation determination unit” (1825) is configured to receive infrared signals transmitted from the plurality of infrared signal transmission units (1801) of the remote control device (1800) based on the reception intensity measurement result of the reception intensity measurement unit (1823). The electronic device (1820) has a function of determining whether or not the path received by the infrared signal receiver (1821) has a twisted relationship. The “twisted relationship” means, for example, a state as shown in FIG. Of the plurality of infrared signal transmission units (1901a, 1901b, 1901c, 1901d) of the remote control device (1900), an IrSimple signal is transmitted from the infrared signal transmission unit 1901b, and a remote control signal is transmitted from the infrared signal transmission unit 1901c. Further, it is assumed that the infrared signal receiver 1911a of the electronic device (1910) receives a remote control signal transmitted from the infrared signal transmitter 1901c, and the infrared signal receiver 1911b receives an IrSimple signal transmitted from the infrared signal transmitter 1901b. . In such a case, the path between the remote control signal and the IrSimple signal is twisted due to the positional relationship between the infrared signal transmitting unit and the infrared signal receiving unit. Further, even if both are infrared signals of the same communication method, a problem occurs when different transmission data is transmitted by infrared signals. That is, if such a twisting relationship is used, different infrared signals interfere with each other over a wide range, and there is a high possibility that transmission data will be corrupted. In addition, the reception intensity measurement signal is transmitted in order from each infrared signal transmitter (S2, S3), and the received reception intensity measurement signal is received and measured by each infrared signal receiver (R1, R2). It is assumed that the result of the reception intensity is a value as shown in FIG. In such a case, “based on the reception intensity measurement result in the reception intensity measurement unit” means, for example, a combination of an infrared signal transmission unit and an infrared signal reception unit (S2 and R1 in FIG. A case where infrared signals are transmitted / received by a combination other than (S3 and R2) (S2 and R2, S3 and R1 in FIG. 19) may be determined to be a twisted relationship. This is because, when performing infrared communication, it is normal to perform communication using a combination of an infrared signal transmission unit and an infrared signal reception unit that will increase the reception intensity. This is because it is assumed that the remote control device is turned upside down. As specific processing of the torsional relationship determination unit, for example, the reception intensity stored in a predetermined storage area such as a RAM or HDD is read and compared with the reception intensity measurement unit. The comparison result is stored in a predetermined storage area such as a RAM. Further, the comparison result is read from a predetermined storage area such as a RAM, and it is determined whether or not there is a twist relationship according to the comparison result, and the determination result is stored in a predetermined storage area such as a RAM. The torsional relationship determination unit may include a program for causing the CPU to execute such processing.

  The “twist relationship determination result transmission unit” (1826) has a function of transmitting the determination result of the twist relationship determination unit (1825) to the remote control device (1800). Communication for transmitting the determination result to the remote control device (1800) may be wired communication or wireless communication. As long as wireless communication is used, Bluetooth (registered trademark), wireless LAN, or the like may be used in addition to infrared communication. As specific processing of the twist relation determination result transmission unit, for example, a twist relation determination result is read from a predetermined storage area such as a RAM, and the read determination result is transmitted via a communication interface. Further, the torsional relationship determination result transmitting unit may include a program for causing the CPU to execute such processing.

  (Embodiment 8: Process Flow) FIG. 20 illustrates a sequence diagram showing a process flow in the remote control system according to the present embodiment.

  First, in step S2001, connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. In step S2004, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S2005, the remote control device receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 2006, the reception intensity measurement signals are transmitted from the respective infrared signal transmission units so as not to overlap. This process is mainly executed by the infrared signal transmitter. Next, in step S2007, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S2008, the same gain control is executed for each reception strength measurement signal to measure the reception strength. This process is mainly executed by the reception intensity measurement unit. Next, in step S2012, whether the path through which the infrared signal transmitted from the plurality of infrared signal transmission units of the remote control device is received by the infrared signal reception unit of the electronic device based on the reception intensity measurement result is twisted. to decide. This process is executed by the twist relation determining unit. Next, in step S2013, the determination result of the twist relation is transmitted to the remote control device. This process is mainly executed by the twist relation determination result transmission unit.

(Embodiment 8: Effect) In the remote control system according to the present embodiment, the path through which the infrared signal transmitted from the remote control device is received by the infrared signal receiver of the electronic device based on the measurement result of the reception intensity of the electronic device is Since it is possible to determine whether the relationship is twisted and transmit the determination result to the remote control device, for example, in the remote control device, processing such as canceling the twist relationship by changing the communication method in the infrared signal transmission unit is executed. be able to.
(Embodiment 9)

  (Embodiment 9: Overview) This embodiment is characterized in that the remote control device performs connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units based on the determination result of the twist relation from the electronic device. A remote control system will be described.

  (Embodiment 9: Configuration) FIG. 21 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (2100) and an electronic device (2120). In the remote control system according to the present embodiment, in addition to the configuration of the remote control system described in the eighth embodiment, the remote control device (2100) has a twist relationship determination result acquisition unit (2111), and the transmission connection control unit (2103) It has a twist relationship-dependent connection control means (2112).

  (Ninth Embodiment: Configuration of Remote Control Device) A remote control device (2100) includes a plurality of infrared signal transmission units (2101), a plurality of infrared signal source units (2102), a transmission connection control unit (2103), and reception intensity. A measurement signal transmission control unit (2108) and a torsional relationship determination result acquisition unit (2111). The transmission connection control unit (2103) includes a twist relationship dependent connection control unit (2112). Further, the remote control device (2100) may have a measurement result acquisition unit, and the transmission connection control unit (2103) may have a second effectiveness control unit. In addition, each of the above-described configurations may further include the transmission connection control unit (2103) having the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be a configuration in which the transmission connection control unit (2103) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit.

  The “twist relation determination result acquisition unit” (2111) has a function of acquiring a twist relation determination result of the electronic device (2120). “The twist relationship determination result of the electronic device” refers to the twist relationship determination result transmitted from the twist relationship determination result transmission unit (2126) of the electronic device (2120). The communication for the twist relationship determination result acquisition unit to acquire the twist relationship determination result need not be limited to infrared communication. It may be wired communication or wireless communication. As long as wireless communication is used, Bluetooth (registered trademark), wireless LAN, or the like may be used in addition to infrared communication. As specific processing of the twist relationship determination result acquisition unit, for example, a twist relationship determination result is acquired via a communication interface and stored in a predetermined storage area such as a RAM. The torsional relationship determination result acquisition unit may include a program for causing the CPU to execute such processing.

  The “twist relationship-dependent connection control means” (2112) has a function of performing connection control based on the acquired twist relationship determination result. The “acquired torsional relationship determination result” refers to the torsional relationship determination result acquired by the torsional relationship determination result acquisition unit (2111). “Connection control” refers to connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units.

  FIG. 22 shows an example of processing in the twist relationship-dependent connection control means. First, as shown in FIG. 22A, among the plurality of infrared signal transmission units (2201a, 2201b, 2201c, 2201d) of the remote control device (2200), an IrSimple signal is transmitted from the infrared signal transmission unit 2201b to the infrared signal transmission. Assume that a remote control signal is transmitted from the unit 2201c. In addition, as an infrared signal receiving unit of the corresponding electronic device (2210), it is assumed that the infrared signal receiving unit 2211a receives a remote control signal and the infrared signal receiving unit 2211b receives an IrSimple signal. Accordingly, it is assumed that the twist relationship shown in FIG. 22A is obtained, and the remote controller (2200) obtains the determination result that is determined to be the twist relationship by the electronic device (2210). In such a case, for example, as shown in FIG. 22B, if connection control is performed so that a remote control signal is transmitted from the infrared signal transmission unit 2201b and an IrSimple signal is transmitted from the infrared signal transmission unit 2201c, the twisting relationship of the path of the infrared signal Therefore, both infrared signals are less likely to interfere with each other. FIG. 23 illustrates connection control by the twist relationship-dependent connection control means at this time. In the case of the twist relationship illustrated in FIG. 22A, as shown in FIG. 23A, the infrared signal transmission unit 2201b is connected to the IrSimple signal processing mechanism (2301b), and the infrared signal transmission unit 2201c is remote control signal processing. It is connected to the mechanism (2301a). As illustrated in FIG. 23B, when the connection control is performed by switching the portion surrounded by the broken-line circle of the twist relationship-dependent connection control means (2302), the infrared signal transmission unit 2201b performs remote control signal processing. The infrared signal transmitter 2201c is connected to the mechanism (2301a), and the infrared signal transmission unit 2201c is connected to the IrSimple signal processing mechanism (2301b). By such connection control, the state shown in FIG. 22B is obtained, and the torsional relationship is eliminated.

  (Embodiment 9: Configuration of Electronic Device) An electronic device (2120) includes an infrared signal receiving unit (2121), a reception intensity measurement signal transmission command output unit (2122), a reception intensity measurement unit (2123), and a twist. A relationship determination unit (2125) and a twist relationship determination result transmission unit (2126); Furthermore, the electronic device (2120) may have a first effectiveness control unit. That is, the configuration of the electronic device (2120) is the same as the configuration of the electronic device described in the eighth embodiment.

  (Embodiment 9: Process Flow) FIG. 24 illustrates a sequence diagram showing a process flow in the remote control system according to the present embodiment.

  First, in step S2401, connection control between a plurality of infrared signal source units and a plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. Next, in step S2404, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S2405, the remote control device receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 2406, the reception intensity measurement signals are transmitted from the respective infrared signal transmission units so as not to overlap. This process is mainly executed by the infrared signal transmitter. In step S2407, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S2408, the reception intensity is measured by executing equivalent gain control for each reception intensity measurement signal. This process is mainly executed by the reception intensity measurement unit. Next, in step S 2412, is the twisting relationship between the paths in which the infrared signals transmitted from the plurality of infrared signal transmission units of the remote control device are received by the infrared signal reception unit of the electronic device based on the reception intensity measurement result? to decide. This process is executed by the twist relation determining unit. In step S2413, the determination result of the twist relation is transmitted to the remote control device. This process is mainly executed by the twist relation determination result transmission unit. In step S2414, the torsional relationship determination result is acquired by the remote control device. This process is mainly executed by the torsional relationship determination result acquisition unit. Next, in step S2415, connection control is performed based on the twist relationship determination result. This process is mainly executed by the twist relationship dependent connection control means.

(Embodiment 9: Effect) Since the remote control system according to the present embodiment performs connection control based on the twist relation determination result acquired by the remote control device, for example, the twist is obtained by switching the infrared signal transmitted from the infrared signal transmitter. Connection control such as canceling the relationship can be executed.
(Embodiment 10)

  (Embodiment 10: Overview) In this embodiment, an electronic device includes a plurality of reception signal processing units for processing received infrared signals according to the communication method, and includes a plurality of infrared signal reception units and a plurality of reception signals. A remote control system that performs connection control with a processing unit will be described.

  (Embodiment 10: Configuration) FIG. 25 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (2500) and an electronic device (2520). In the remote control system according to the present embodiment, in addition to the configuration of the remote control system described in any one of the first to ninth embodiments, the electronic device (2520) includes a reception signal processing unit (2527) and a reception connection control unit (2528). Have FIG. 25 illustrates a configuration obtained by adding these configuration requirements to the configuration of the remote control system described in the first embodiment.

  (Embodiment 10: Configuration of remote control device) The remote control device (2500) includes a plurality of infrared signal transmission units (2501), a plurality of infrared signal source units (2502), and a transmission connection control unit (2503). . Further, the remote control device (2500) may include a reception intensity measurement signal transmission control unit and a twist relationship determination result acquisition unit, and the transmission connection control unit (2503) may include a twist relationship dependent connection control unit. Further, the remote control device (2500) may include a measurement result acquisition unit, and the transmission connection control unit (2503) may include a second effectiveness control unit. Further, the remote control device (2500) may have a reception intensity measurement signal transmission control unit. In addition, each of the above-described configurations may further include the transmission connection control unit (2503) having the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be a configuration in which the transmission connection control unit (2503) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit. That is, the configuration of the remote control device (2500) is the same as the configuration of the remote control device described in any one of the first to ninth embodiments.

  (Embodiment 10: Configuration of Electronic Device) The electronic device (2520) includes an infrared signal receiving unit (2521), a received signal processing unit (2527), and a receiving connection control unit (2528). Furthermore, the electronic device (2520) may include a twist relationship determination unit and a twist relationship determination result transmission unit. Furthermore, the electronic device (2520) may include a reception intensity measurement signal transmission command output unit and a reception intensity measurement unit. Furthermore, the electronic device (2520) may have a first effectiveness control unit.

  There are a plurality of “reception signal processing units” (2527) and have a function of processing the infrared signals received by the infrared signal reception unit (2521) according to the communication method. “Processing an infrared signal according to its communication method” corresponds to decoding according to the format of the remote control signal if the received infrared signal is a remote control signal, for example. The infrared signal received by the infrared signal receiver (2521) is an infrared signal transmitted from the plurality of infrared signal transmitters (2501) of the remote control device (2500), and the plurality of infrared signal transmitters ( 2501) is connected to a plurality of infrared signal source units (2502). Therefore, the communication method of the received infrared signal is assumed to be not only one but also plural. That is, each of the received signal processing units may be a processing mechanism that processes infrared signals having different communication methods such as a remote control signal, an IrDA signal, and an IrSimple signal. Specifically, the received signal processing unit decodes the infrared signal received by the infrared signal receiving unit, and the received data such as audio data and image data obtained as a result is stored in a predetermined storage area such as a RAM or HDD. To remember. The received signal processing unit may include a program for causing the CPU to execute such processing.

  The “reception connection control unit” (2528) has a function of controlling connection between the plurality of infrared signal reception units (2521) and the plurality of reception signal processing units (2527). In other words, the reception connection control unit can switch the reception signal processing unit (2527) to be processed according to the communication method of the infrared signal received by each infrared signal reception unit (2521). In addition, the reception signal processing unit (2527) is controlled so that the infrared signal is not processed by disconnecting the connection, and the connection control is performed so that the infrared signal reception unit (2521) is substantially invalid. May be.

  FIG. 26 illustrates an example of processing in the reception connection control unit. FIG. 26 illustrates a case where there are two infrared signal reception units (2601a, 2601b) and two reception signal processing units (2603a, 2603b). The received signal processing units (2603a and 2603b) are assumed to be a remote control signal and IrSimple signal processing mechanism. As illustrated in FIG. 26, the reception connection control unit (2602) can switch the connection between the two infrared signal reception units and the two reception signal processing units by switching, for example. In FIG. 26, the infrared signal receiving unit 2601a is connected to a remote control signal processing mechanism and the like, and the infrared signal receiving unit 2601b is connected to an IrSimple signal processing mechanism and the like. Therefore, the remote control signal is received from the infrared signal receiving unit 2601a, and the IrSimple signal is received from the infrared signal receiving unit 2601b. The reception connection control unit may include a program for causing the CPU to execute such processing.

  (Embodiment 10: Process Flow) FIG. 27 exemplifies a sequence diagram showing a process flow in the remote control system according to this embodiment.

  First, in step S2701, connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. In step S2716, the electronic device performs reception connection control between the plurality of infrared signal reception units and the plurality of reception signal processing units. This process is mainly executed by the reception connection control unit. Next, in step S2702, an infrared signal is transmitted. This process is mainly executed by the infrared signal transmitter. Next, in step S2703, the electronic device receives an infrared signal. This process is mainly executed by the infrared signal receiver. Next, in step S2717, infrared signal processing is performed. This process is mainly executed by the received signal processing unit.

(Embodiment 10: Effect) The remote control system according to this embodiment can acquire received data such as audio data and image data by processing an infrared signal received by an electronic device according to the communication method. it can.
(Embodiment 11)

  (Embodiment 11: Overview) In this embodiment, a remote control system is characterized in that connection control between a plurality of infrared signal reception units and a plurality of reception signal processing units in an electronic device is performed based on a determination result of a twist relationship. Will be described.

  (Embodiment 11: Configuration) FIG. 28 illustrates a functional block diagram of a remote control system according to this embodiment. The remote control system includes a remote control device (2800) and an electronic device (2820). In the remote control system according to the present embodiment, in addition to the configuration of the remote control system related to the eighth embodiment of the tenth embodiment, the reception connection control unit of the electronic device (2820) has the twist relationship dependent reception connection control means (2829). Have.

  (Embodiment 11: Configuration of Remote Control Device) A remote control device (2800) includes a plurality of infrared signal transmission units (2801), a plurality of infrared signal source units (2802), a transmission connection control unit (2803), and reception intensity. And a measurement signal transmission control unit (2808). Further, the remote control device (2800) may include a measurement result acquisition unit, and the transmission connection control unit (2803) may include a second effectiveness control unit. Further, the remote control device (2800) may have a reception intensity measurement signal transmission control unit. In addition, each of the above-described configurations may further include the transmission connection control unit (2803) having the same signal transmission control means and / or different signal transmission control means. In addition, each of the above configurations may be a configuration in which the transmission connection control unit (2803) further includes a transmission unit attribute information holding unit and an attribute dependent connection control unit. That is, the configuration of the remote control device (2800) is the same as the configuration of the remote control device related to the eighth embodiment of the tenth embodiment.

  (Embodiment 11: Configuration of Electronic Device) An electronic device (2820) includes an infrared signal receiving unit (2821), a reception intensity measurement signal transmission command output unit (2822), a reception intensity measuring unit (2823), and a twist. A relationship determination unit (2825), a twist relationship determination result transmission unit (2826), a reception signal processing unit (2827), and a reception connection control unit (2828) are included. The reception connection control unit (2828) includes a twist relationship dependent reception connection control means (2829). Furthermore, the electronic device (2820) may have a first effectiveness control unit.

  The “twist relationship-dependent reception connection control means” (2829) has a function of performing reception connection control based on the determination result of the twist relationship. “Reception connection control” refers to connection control between a plurality of infrared signal reception units (2821) and a plurality of reception signal processing units (2827).

  FIG. 29 shows an example of processing in the twist relationship dependent reception connection control means. First, as shown in FIG. 29A, among the plurality of infrared signal transmission units (2901a, 2901b, 2901c, and 2901d) of the remote control device (2900), an IrSimple signal is transmitted from the infrared signal transmission unit 2901b to the infrared signal transmission. Assume that a remote control signal is transmitted from the unit 2901c. In addition, as an infrared signal receiving unit of the corresponding electronic device (2910), it is assumed that the infrared signal receiving unit 2911a receives a remote control signal and the infrared signal receiving unit 2911b receives an IrSimple signal. As a result, it is assumed that the torsional relationship is as shown in FIG. In such a case, for example, as shown in FIG. 29B, if the reception connection control is performed so that the infrared signal receiving unit 2911b receives the remote control signal and the infrared signal receiving unit 2911a receives the IrSimple signal, the path of the infrared signal The twisting relationship of is eliminated. Further, FIG. 30 illustrates connection control by the twist relationship dependent reception connection control means at this time. In the case of the twist relationship illustrated in FIG. 29A, the infrared signal receiving unit 2911b is connected to the IrSimple signal processing mechanism (3003b) as shown in FIG. 30A, and the infrared signal receiving unit 2911a is remote control signal processing. It is connected to the mechanism (3003a). As illustrated in FIG. 30B, when the reception connection control is performed by switching by the twist relationship dependent reception connection control means (3002), the infrared signal reception unit 2911b is connected to the remote control signal processing mechanism (3003a). The infrared signal receiving unit 2911a is connected to the IrSimple signal processing mechanism (3003b). By such connection control, the state shown in FIG. 29B is obtained, and the torsional relationship is eliminated.

  (Embodiment 11: Process Flow) FIG. 31 exemplifies a sequence diagram showing a process flow in the remote control system according to this embodiment.

  First, in step S3101, connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units is performed by the remote control device. This process is mainly executed by the transmission connection control unit. In step S3104, the electronic device transmits a reception intensity measurement signal transmission command to the remote control device. This processing is mainly executed by the reception intensity measurement signal transmission command output unit. In step S3105, the remote control device receives a reception intensity measurement signal transmission command. This processing is mainly executed by the reception intensity measurement signal transmission control unit. Next, in step 3106, the reception intensity measurement signals are transmitted from the respective infrared signal transmission units so as not to overlap. This process is mainly executed by the infrared signal transmitter. In step S3107, the electronic device receives a plurality of reception intensity measurement signals. This process is mainly executed by the infrared signal receiver. Next, in step S3108, the reception intensity is measured by executing equivalent gain control for each reception intensity measurement signal. This process is mainly executed by the reception intensity measurement unit. Next, in step S3112, whether the path through which the infrared signal transmitted from the plurality of infrared signal transmission units of the remote control device is received by the infrared signal reception unit of the electronic device based on the reception intensity measurement result is twisted. to decide. This process is executed by the twist relation determining unit. Next, in step S3113, the determination result of the twist relation is transmitted to the remote control device. This process is mainly executed by the twist relation determination result transmission unit. Next, in step S3118, reception connection control is performed based on the twist relationship determination result. This process is mainly executed by the twist relationship dependent reception connection control means.

  (Embodiment 11: Effect) The remote control system according to this embodiment can eliminate the twist relationship by performing reception connection control based on the twist relationship determination result in the electronic device.

An example figure of the outline of the remote control device concerning the present invention Functional block diagram of the remote control system according to the first embodiment Example of processing in the transmission connection control unit FIG. 3 is a sequence diagram illustrating a processing flow of the remote control system according to the first embodiment. Functional block diagram of a remote control system according to the second embodiment Example of processing in the same signal transmission control means Functional block diagram of a remote control system according to the third embodiment Example of processing in different signal transmission control means Functional block diagram of a remote control system according to Embodiment 4 Example of transmitter attribute information Functional block diagram of a remote control system according to Embodiment 5 Example of signal transmission command for receiving strength measurement FIG. 10 is a sequence diagram showing a processing flow of a remote control system according to the fifth embodiment. Functional block diagram of a remote control system according to Embodiment 6 FIG. 10 is a sequence diagram showing a processing flow of a remote control system according to the sixth embodiment. Functional block diagram of a remote control system according to Embodiment 7 FIG. 10 is a sequence diagram illustrating a processing flow of the remote control system according to the seventh embodiment. Functional block diagram of a remote control system according to Embodiment 8 Example diagram when the path of the infrared signal is twisted FIG. 10 is a sequence diagram illustrating a processing flow of a remote control system according to the eighth embodiment. Functional block diagram of a remote control system according to Embodiment 9 Example of adjusting twisting relationship of infrared signal path by twisting relationship dependent connection control means Example of processing in twist relationship dependent connection control means FIG. 10 is a sequence diagram showing a processing flow of a remote control system according to the ninth embodiment. Functional block diagram of a remote control system according to Embodiment 10 Example of processing in the reception connection control unit FIG. 10 is a sequence diagram showing a processing flow of the remote control system according to the tenth embodiment. Functional block diagram of a remote control system according to Embodiment 11 An example of the case where the twist relationship of the infrared signal path is adjusted by the twist relationship dependent reception connection control means Example of processing in torsional relation dependent reception connection control means FIG. 12 is a sequence diagram illustrating a processing flow of the remote control system according to the eleventh embodiment. An example diagram showing the expected effect by the same signal transmission control means An example figure of the process in an attribute dependence connection control means. Example diagram of processing in first effectiveness control unit and second effectiveness control means Example of general computer configuration

Explanation of symbols

0100 Remote control device 0101a Infrared signal transmitter 0101b Infrared signal transmitter 0101c Infrared signal transmitter 0101d Infrared signal transmitter 0102 Interference area

Claims (13)

  A remote control system comprising a remote control device and an electronic device operated by the remote control device,
  The remote control device
  A plurality of infrared signal transmitters capable of operating at least simultaneously;
  A plurality of infrared signal source units;
  A transmission connection control unit for controlling connection between the plurality of infrared signal source units and the plurality of infrared signal transmission units;
Have
  The transmission connection control unit
  Transmitter attribute information holding means for holding transmitter attribute information including infrared effective transmission range information of the infrared signal transmitter;
  Connection control between the plurality of infrared signal source units and the plurality of infrared signal transmission units so that the interference of infrared signals is reduced based on the transmission unit attribute information held in the transmission unit attribute information holding unit. Attribute-dependent connection control means for
With
  The electronic device is a remote control system having an infrared signal receiving unit corresponding to each of a plurality of infrared signal transmitting units of the remote control device.   A remote control system comprising a remote control device and an electronic device operated by the remote control device,
  The remote control device
  A plurality of infrared signal transmitters capable of operating at least simultaneously;
  A plurality of infrared signal source units;
  A transmission connection control unit for controlling connection between the plurality of infrared signal source units and the plurality of infrared signal transmission units;
Have
  The electronic device has an infrared signal receiver corresponding to each of the plurality of infrared signal transmitters of the remote control device,

In addition, electronic devices
  A reception intensity measurement signal transmission command output unit for outputting a reception intensity measurement signal transmission command to the remote control device;
  A plurality of reception intensity measurement signals transmitted from the remote control device in response to the transmitted reception intensity measurement signal transmission command are received by the infrared signal reception unit, and the same gain control is performed on each of the plurality of reception intensity measurement signals. A reception intensity measurement unit for measuring the reception intensity of the reception intensity measurement signal of
Furthermore, the remote control device
  A reception intensity measurement signal transmission control unit that transmits the received intensity measurement signals from the respective infrared signal transmission units so as not to overlap in accordance with the received reception intensity measurement signal transmission command;
A remote control system. The remote control system according to claim 2 , wherein the electronic device includes a first effectiveness control unit that enables or disables part or all of the plurality of infrared signal reception units according to the measurement result of the reception intensity measurement unit. The remote control device has a measurement result acquisition unit that acquires a measurement result in the reception intensity measurement unit of the electronic device,
4. The remote control system according to claim 2 , wherein the transmission connection control unit includes second effectiveness control means for enabling or disabling part or all of the plurality of infrared signal transmission units according to the acquired measurement result. . Electronic equipment
Based on the reception intensity measurement result at the reception intensity measurement unit, it is determined whether the path through which the infrared signal transmitted from the plurality of infrared signal transmission units of the remote control device is received by the infrared signal reception unit of the electronic device is twisted A torsional relationship determination unit,
A torsional relationship determination result transmitting unit for transmitting the determination result in the torsional relationship determining unit to the remote control device;
5. The remote control system according to claim 2, comprising: The remote control device has a twist relationship determination result acquisition unit that acquires a twist relationship determination result of the electronic device,
The remote control system according to claim 5 , wherein the transmission connection control unit includes a twist relationship-dependent connection control unit that performs connection control based on the acquired twist relationship determination result.   Electronic equipment
  A plurality of received signal processing units for processing the infrared signal received by the infrared signal receiving unit according to the communication method;
  A plurality of infrared signal reception units, and a reception connection control unit for controlling connection with the plurality of reception signal processing units,
  The remote control system according to claim 5, wherein the reception connection control unit includes a twist relationship dependent reception connection control unit that performs reception connection control based on a twist relationship determination result.   The remote control device comprising: a remote control device having at least a plurality of infrared signal transmission units operable at the same time; a plurality of infrared signal source units; and an infrared signal reception unit corresponding to each of the plurality of infrared signal transmission units of the remote control device. And a remote control system operating method comprising:
  In the remote control device,
  A transmission connection control step for controlling connection between the plurality of infrared signal source units and the plurality of infrared signal transmission units;
    In electronic equipment,
  A reception strength measurement signal transmission command output step for outputting a reception strength measurement signal transmission command to the remote control device;
  In the remote control device, a reception intensity measurement signal transmission control step for transmitting the reception intensity measurement signals from the respective infrared signal transmission units so as not to overlap in accordance with the reception intensity measurement signal transmission command received from the electronic device,
  In electronic equipment,
  A plurality of reception intensity measurement signals transmitted from the remote control device in response to the transmitted reception intensity measurement signal transmission command are received by the infrared signal reception unit, and the same gain control is performed on each of the plurality of reception intensity measurement signals. A reception strength measurement step for measuring the reception strength of the received signal for measuring the received strength;
The operation method of the remote control system. The remote controller according to claim 8 , further comprising a first effectiveness control step of enabling or disabling part or all of the plurality of infrared signal receiving units according to the measurement result in the reception intensity measurement step in the electronic device. How the system works. In the remote control device, having a measurement result acquisition step of acquiring the measurement result in the reception intensity measurement step of the electronic device,
The remote control according to claim 8 or 9 , wherein the transmission connection control step includes a second effectiveness control sub-step for enabling or disabling part or all of the plurality of infrared signal transmission units according to the acquired measurement result. How the system works. In electronic equipment,
Based on the reception intensity measurement result in the reception intensity measurement step, it is determined whether the path through which the infrared signal transmitted from the plurality of infrared signal transmission units of the remote control device is received by the infrared signal reception unit of the electronic device is twisted A torsional relationship determination step,
A torsional relationship determination result transmission step for transmitting the determination result in the torsional relationship determination step to the remote control device;
The operation method of the remote control system according to any one of claims 8 to 10 . The remote control device has a twist relationship determination result acquisition step for acquiring a twist relationship determination result in an electronic device,
12. The operation method of a remote control system according to claim 11 , wherein the transmission connection control step includes a twist relationship dependent connection control sub-step for performing connection control based on the acquired twist relationship determination result.   The electronic device further includes a plurality of received signal processing units for processing the infrared signal received by the infrared signal receiving unit according to the communication method,
  In the electronic device, having a reception connection control step for controlling connection between the plurality of infrared signal reception units and the plurality of reception signal processing units,
  12. The operation method of a remote control system according to claim 11, wherein the reception connection control step includes a twist relationship dependent reception connection control sub-step for performing reception connection control based on a twist relationship determination result.

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