JP5027267B2 - Communication system, remote controller and equipment - Google Patents

Description

  The present invention relates to a communication technique between equipment such as an air conditioner and a remote controller.

  In recent years, equipment such as air conditioners and televisions have become multifunctional and can provide various information to users. In accordance with this, a remote controller (hereinafter referred to as a remote controller) for remotely operating equipment is also becoming more multifunctional. Such a remote control is used not only for the operation of the basic functions of equipment (air conditioning for air conditioners, broadcast display for television, etc.), but also displays, for example, power consumption and electricity costs when using equipment. You can also.

  When various information is handled in this way, the frequency of communication between the remote controller and the equipment increases, and the amount of communication increases. In this case, the remote control is required to have a performance for processing various information and presenting it to the user (for example, a high-performance microcomputer, a liquid crystal screen, a large-capacity memory, etc.). Therefore, the power consumption of the remote controller tends to increase as the number of functions increases.

  Further, in a normal case, the facility device sets its own operating state to a state in which a signal from the remote controller can always be received, and communication with the remote controller is possible at any time. Therefore, it can be said that the power consumption of the equipment that communicates with the remote controller is higher than that of an equivalent equipment that does not use the remote controller.

  Therefore, various techniques for intermittently receiving a signal from a remote controller have been proposed as an example of a method for reducing power consumption (for example, Patent Document 1).

  In Patent Literature 1, the remote control includes an availability detection function (for example, configured by an infrared sensor, a temperature sensor, or the like) that detects that a user may perform some operation. When the remote control detects the availability by the availability detection function, the remote control transmits a standby request signal to the equipment. When the equipment device receives this standby request signal, the facility device switches the intermittent reception operation to the constant reception operation.

  In this way, before the remote controller and equipment communicate with each other, the equipment is made ready for continuous reception from intermittent reception so as not to cause a delay in the reaction time of the equipment while reducing power consumption. ing.

JP 2000-59246 A

  By the way, as described above, the power consumption of the remote controller tends to increase with the multifunction of the remote controller. Such a remote control generally has a large standby power not only during its operation but also during non-operation. The standby power is smaller than the power consumption during operation, but the standby time is much longer than the operation time, so depending on the frequency of operation, the standby time within the power consumption of the remote control can be seen over a long period of time. It can be said that the ratio of electric power is very large.

  On the other hand, when the remote controller is not used, it is conceivable to reduce standby power by turning off the remote controller by removing the battery. However, it is very inconvenient for the user to insert the battery and turn on the remote control when they want to use it.

  Further, in a remote controller corresponding to an air conditioner, generally, setting information such as a set temperature and a set humidity of the air conditioner is stored in a volatile memory. For this reason, when the power of the remote control is turned off, the setting information is deleted. From this point of view, it is not preferable to turn off the remote controller.

  The above-mentioned Patent Document 1 does not make any mention of the above-described problem with respect to the power consumption of the remote controller. In addition, in other prior arts, an effective solution has not been proposed yet.

  The present invention has been made in view of such circumstances, and in equipment, the power consumption required for communication with the remote control is reduced. In the remote control, the power consumption is reduced without reducing convenience. An object of the present invention is to provide a communication system that can be used.

In order to achieve the above object, a communication system according to the present invention provides:
A communication system comprising equipment and a remote controller for remotely operating the equipment,
The equipment is
Communication means for performing wireless communication with the remote controller;
A control means for controlling the communication means so as to be intermittently receivable, and acquiring data from the remote controller received by the communication means,
When the communication unit receives the predetermined data transmitted from the remote controller, the control unit continues the receivable state until a predetermined condition is satisfied,
The remote controller is
A communication means for performing wireless communication with the equipment,
Control means for controlling the communication means to transmit data to the equipment, and to obtain data from the equipment received by the communication means;
Power supply control means for supplying power to the communication means and the control means;
A setting operation receiving means for receiving an operation input related to the setting of the equipment from the user;
Starting operation receiving means for receiving an operation input related to starting of the remote controller from a user,
The power control means starts supplying the power when the activation operation accepting means accepts the operation input when the power supply is stopped.
The control means includes
When the activation operation accepting unit accepts the operation input, the activation operation data indicating the activation start of the remote controller is transmitted to the equipment device,
When a predetermined condition is satisfied, the start-up stop data indicating start-stop of the remote controller is transmitted to the facility device, and then the supply of power by the power control unit is stopped ,
In the equipment,
When the communication means receives the start / stop data, the control means cancels the continuation of the receivable state .

  According to the present invention, it is possible to reduce power consumption required for communication with a remote controller in facility equipment, and to reduce power consumption without reducing convenience in the remote controller.

It is a block diagram which shows the structure of the air-conditioning control system to which the communication system which concerns on one Embodiment of this invention is applied. It is a flowchart which shows the operation | movement procedure of the remote control in this embodiment. It is a flowchart which shows the procedure of the remote control starting process which the remote control of this embodiment performs. It is a flowchart which shows the procedure of the remote control sleep process which the remote control of this embodiment performs. It is a flowchart which shows the operation | movement procedure of the air conditioner in this embodiment. In this embodiment, it is a timing chart which shows the communication state of a remote control and an air conditioner. In the air conditioner of this embodiment, it is a figure for demonstrating the continuation time of a receivable state, and the continuation time of a low power consumption state. It is a timing chart which shows transition of current consumption of a remote control in this embodiment. In other embodiment, it is a figure for demonstrating the example which changes the intermittent reception interval of an air conditioner with a time slot | zone, (a) shows the example of the intermittent reception interval at normal time, (b) is a user's usage frequency. The example of the intermittent reception interval in a time zone with low is shown. It is a flowchart for demonstrating the remote control sleep process which the remote control of other embodiment performs.

  Hereinafter, a communication system according to an embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of an air conditioning control system 1 to which a communication system according to the present embodiment is applied. The air conditioning control system 1 includes an air conditioner 10 and a remote controller 20. The air conditioner 10 is installed on a wall or ceiling of an indoor partitioned room or the like, and in accordance with air conditioning control data (air conditioning control data) transmitted from the remote controller 20, the air conditioner (eg, heating, cooling, Perform dehumidification, humidification, air cleaning, etc.).

  The air conditioner 10 includes a communication unit 100, a control unit 101, and a storage unit 102. Further, although not shown, a processing unit (air conditioning processing unit) for realizing an air conditioning function provided in a general air conditioner is provided.

  The communication unit 100 includes a predetermined communication interface and the like, and transmits and receives data to and from the remote controller 20 by a predetermined wireless method. The communication unit 100 is controlled by the control unit 101 so that the operation state is either a receivable state or a low power consumption state. In the receivable state, communication with the remote controller 20 is possible, and data can be transmitted to and received from the remote controller 20. On the other hand, in the low power consumption state, communication with the remote controller 20 cannot be performed, but the power consumption can be reduced by that amount (the amount of time that the reception waiting state is not maintained).

  The control unit 101 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a main storage device, and the like, and controls the communication unit 100, the storage unit 102, and the air conditioning processing unit described above.

  The storage unit 102 is configured by a readable / writable nonvolatile semiconductor memory such as a flash memory, for example, and stores a program, data, and the like related to control of the air conditioner 10. In addition, the storage unit 102 stores information (remote control information) set by the user in the remote controller 20. This remote control information includes, for example, information on the set temperature, set humidity, and the like.

  The remote controller 20 is a small and portable device for remotely operating the air conditioner 10. The remote controller 20 includes a power supply unit 200, a main power supply control unit 201, a sub power supply control unit 202, a communication unit 203, a control unit 204, a storage unit 205, a setting operation reception unit 206, a display unit 207, An activation operation receiving unit 208.

  The power supply unit 200 is configured by a battery, for example, and supplies power to the main power supply control unit 201 and the sub power supply control unit 202. The main power supply control unit 201 is composed of, for example, a regulator, and supplies the power supplied from the power supply unit 200 to the communication unit 203, the control unit 204, the storage unit 205, the setting operation reception unit 206, and the display unit 207. When the main power supply control unit 201 receives the power supply start signal sent from the activation operation accepting unit 208, the main power supply control unit 201 starts supplying power to each of the above components and receives the power supply stop signal sent from the control unit 204. Then, the supply of power to each component is stopped.

  The sub power supply control unit 202 is configured by a regulator, for example, and supplies the power supplied from the power supply unit 200 to the activation operation reception unit 208. Unlike the main power supply control unit 201, the sub power supply control unit 202 constantly supplies power to the activation operation reception unit 208.

  The activation operation accepting unit 208 is constituted by, for example, a button or the like, and sends the above-described power supply start signal to the main power supply control unit 201 when pressed by the user. Normally, when this type of button is not pressed, the current path is opened and no current flows. For this reason, even if power is always supplied from the sub power control unit 202, the amount of power consumption is very small.

  Note that the activation operation reception unit 208 may be configured by an acceleration sensor or the like. In this case, when acceleration (that is, movement of the remote controller 20) is detected, for example, when the user picks up the remote controller 20, the activation operation accepting unit 208 sends a power supply start signal to the main power supply control unit 201. . More specifically, the activation operation accepting unit 208 transmits a power supply start signal when any of the acceleration in the X-axis direction, the acceleration in the Y-axis direction, and the acceleration in the Z-axis direction is equal to or greater than a preset threshold value. .

  In addition, when the activation operation reception unit 208 is resistant to voltage fluctuation, the activation operation reception unit 208 may be configured to supply power directly to the activation operation reception unit 208 from the battery.

  The communication unit 203 includes a predetermined communication interface and the like, and exchanges data with the air conditioner 10 by a predetermined wireless method. The communication unit 203 can communicate with the air conditioner 10 only while power is supplied from the main power supply control unit 201. The communication unit 203 transmits the transmission data received from the control unit 204 to the air conditioner 10. In addition, when the communication unit 203 receives data from the air conditioner 10, the communication unit 203 supplies the received data to the control unit 204.

  The control unit 204 includes a CPU, a ROM, a main storage device, and the like. Similarly to the communication unit 203, the control unit 204 operates only while power is supplied from the main power supply control unit 201. The control unit 204 executes processing related to a function provided in this type of general remote controller. That is, when the setting operation accepting unit 206 accepts a user operation related to air conditioning setting, the control unit 204 displays the setting content on the display unit 207 and generates air conditioning control data based on the setting content. It transmits to the air conditioner 10 via 203.

  In addition, when the power supply from the main power supply control unit 201 is started, the control unit 204 executes a remote control activation process described later. Further, when a predetermined time has elapsed since the user operation was last performed, a remote control sleep process to be described later is executed. These processes are processes unique to the present invention.

  The storage unit 205 is configured by, for example, a readable / writable volatile semiconductor memory. The storage unit 205 is used as a work memory when the control unit 204 executes each process described above. Further, the storage unit 205 stores remote control information acquired from the air conditioner 10. The content of the remote control information stored in the storage unit 205 is updated every time a setting operation is performed by the user via the setting operation reception unit 206. Since the storage unit 205 is a volatile semiconductor memory, when the power supply from the main power supply control unit 201 is stopped, the stored remote control information and other data are erased.

  The setting operation reception unit 206 includes various buttons provided on the front panel of the remote controller 20 for the user to perform operations. The setting operation reception unit 206 receives an operation input by the user and sends a signal related to the received operation input to the control unit 204.

  The display unit 207 includes, for example, a display device such as an LCD (Liquid Crystal Display) or an organic EL (Electro-Luminescence) display. The display unit 207 is supplied from the control unit 204 and includes user operation screens and air conditioning settings ( Remote control information) is displayed.

  FIG. 2 is a flowchart showing an operation procedure of the remote controller 20 configured as described above. The operation of the remote controller 20 is started when the power supply unit 200 is turned on by the user, that is, when a battery is set. When the power source 200 is turned on, the power source 200 supplies power to the main power source control unit 201 and the sub power source control unit 202 (step S101).

  The sub power supply control unit 202 supplies the power supplied from the power supply unit 200 to the activation operation reception unit 208. As a result, the activation operation accepting unit 208 becomes operable. When the activation operation accepting unit 208 accepts an input (activation input) from the user (step S102; YES), the activation operation accepting unit 208 sends a power supply start signal to the main power supply control unit 201. Receiving this power supply start signal, the main power supply control unit 201 supplies power to the communication unit 203, the control unit 204, the storage unit 205, the setting operation reception unit 206, and the display unit 207 (step S103).

  When the supply of power by the main power supply control unit 201 is started, the control unit 204 executes a remote control activation process (step S104). Details of the remote control activation process will be described later.

  When the remote control activation process ends, the control unit 204 determines whether or not a predetermined time has elapsed since the last operation performed by the user (step S105). The operation here includes both an operation via the activation operation accepting unit 208 and an operation via the setting operation accepting unit 206.

  When the predetermined time has not elapsed since the last operation (step S105; NO), the control unit 204 determines whether or not an air conditioning setting input operation has been performed by the user via the setting operation reception unit 206 (step S105). S106). When an air conditioning setting input operation is performed (step S106; YES), the control unit 204 generates air conditioning control data based on the air conditioning setting content by the user operation, and the air conditioner 10 via the communication unit 203. (Step S107). Further, the control unit 204 updates the content of the remote control information stored in the storage unit 205 based on the setting content (step S108). And the control part 204 performs the process of step S105 again. On the other hand, when the air conditioning setting input operation is not performed (step S106; NO), the control unit 204 executes the process of step S105 again.

  When a predetermined time (for example, about several tens of seconds) has elapsed since the last operation (step S105; YES), the control unit 204 executes a remote control sleep process (step S109). Details of the remote control sleep process will be described later. When the remote control sleep process ends, the supply of power from the main power supply control unit 201 is stopped, and the operation of the remote control 20 returns to the process of step S102.

  The remote controller 20 repeatedly executes the above-described processing until the battery is removed by the user or the power supply unit 200 is turned off due to the battery being exhausted.

  Next, the remote control activation process executed by the control unit 204 will be described with reference to the flowchart of FIG. First, the control unit 204 substitutes an initial value “0” for i (step S201). i is a counter indicating the number of transmissions. The control unit 204 transmits data for requesting the air conditioner 10 to transmit remote control information (remote control information request data) to the air conditioner 10 via the communication unit 203 (step S202). Then, the control unit 204 increments the counter i (step S203).

  The control unit 204 determines whether or not response data from the air conditioner 10 for the transmitted remote control information request data (starting start data) has been received (step S204). When response data is received within a predetermined time after transmission of the remote control information request data (step S204; YES), the control unit 204 extracts remote control information from the received response data (step S205). Then, the control unit 204 stores the extracted remote control information in the storage unit 205 (step S206). Further, the control unit 204 displays a normal screen on the display unit 207 based on the extracted remote control information (step S207), and ends the remote control activation process. On this screen, for example, the current air conditioning settings are displayed.

  On the other hand, when the response data is not received within the predetermined time (step S204; NO), the control unit 204 determines whether or not the counter i has reached the preset maximum number of transmissions (step S208). When the counter i has not reached the maximum number of transmissions (step S208; NO), the control unit 204 executes the process of step S202 again. On the other hand, when the counter i reaches the maximum number of transmissions (step S208; YES), the control unit 204 causes the display unit 207 to temporarily display an error message indicating that remote control information could not be acquired from the air conditioner 10, Thereafter, a predetermined initial screen is displayed (step S209). Thereby, the remote control activation process ends. On this initial screen, default setting values for air conditioning are displayed. Alternatively, the set value may be displayed blinking.

  Next, remote control sleep processing executed by the control unit 204 will be described with reference to the flowchart of FIG. First, the control unit 204 substitutes an initial value “0” for i (step S301). i is a counter indicating the number of transmissions. The control unit 204 reads remote control information from the storage unit 205 (step S302). And the control part 204 transmits the data (remote control information data) which stored this remote control information to the air conditioner 10 via the communication part 203 (step S303), and increments the counter i (step S304).

  The control unit 204 determines whether or not response data from the air conditioner 10 for the transmitted remote control information data (start / stop data) has been received (step S305). When the response data is received within a predetermined time after the transmission of the remote control information data (step S305; YES), the control unit 204 sends a power supply stop signal to the main power supply control unit 201 (step S307), and performs remote control sleep processing. finish. When receiving the power supply stop signal, the main power supply control unit 201 stops supplying power to the communication unit 203, the control unit 204, the storage unit 205, the setting operation reception unit 206, and the display unit 207.

  On the other hand, when the response data is not received within the predetermined time (step S305; NO), the control unit 204 determines whether or not the counter i has reached a preset maximum number of transmissions (step S306). When the counter i has not reached the maximum number of transmissions (step S306; NO), the control unit 204 executes the process of step S303 again. On the other hand, when the counter i reaches the maximum number of transmissions (step S306; YES), the control unit 204 sends a power supply stop signal to the main power supply control unit 201 (step S307), and ends the remote control sleep process.

  When the activation operation accepting unit 208 accepts a user operation while repeating retransmission of the remote control information data in the remote control sleep process described above, the control unit 204 forcibly terminates the remote control sleep process and the remote control activation process. Is executed preferentially.

  Next, the operation of the air conditioner 10 will be described with reference to the flowchart of FIG. In the following description of the operation, only the operation resulting from communication with the remote controller 20 will be described. Therefore, for example, description of operations and the like that are executed when the operation buttons provided on the air conditioner 10 are directly operated by the user is omitted. The air conditioner 10 repeatedly performs the following operations while the air conditioner 10 is powered on.

  When the power is turned on, the control unit 101 of the air conditioner 10 initializes a flag and a timer (step S401). Specifically, the flag is turned OFF, and the timer (software timer) value (measurement time) is reset to zero.

  Next, the control unit 101 determines whether or not the communication unit 100 has received the data transmitted from the remote controller 20 (step S402). When the data from the remote controller 20 is received (step S402; YES), the control unit 101 turns off the flag and starts the time measurement (time measurement) in the timer (step S403). Here, if the timer has already started to measure time by the previous reception, the control unit 101 resets the measurement time of the timer and restarts it.

  The control unit 101 analyzes the received data and determines whether or not the received data is remote control information request data (activation start data) (step S404). As a result, the received data is the remote control information request data. (Step S404; YES), the control unit 101 reads remote control information from the storage unit 102 (Step S405). Then, the control unit 101 transmits response data storing the read remote control information to the remote control 20 via the communication unit 100 (step S406), and executes the process of step S402 again.

  On the other hand, when the received data is not remote control information request data (step S404; NO), the control unit 101 determines whether the received data is remote control information data (start / stop data) (step S407). When the received data is remote control information data (step S407; YES), the control unit 101 extracts remote control information from the received data and stores the extracted remote control information in the storage unit 102 (step S408). Then, the control unit 101 transmits response data indicating that the remote control information has been received to the remote control 20 via the communication unit 100 (step S409). And the control part 101 turns ON a flag (step S410), and performs the process of step S402 again.

  When the received data is neither the remote control information request data nor the remote control information data (step S407; NO), in this case, the received data means air conditioning control data. The air conditioning unit is controlled according to the contents (step S411). Thereby, the air conditioning according to the content of the received air conditioning control data is executed. And the control part 101 performs the process of step S402 again.

  If NO in step S402 (when no data is received from the remote control), the control unit 101 determines whether or not the flag is ON (step S412). If the flag is ON (step S412; YES). The control unit 101 cancels the continuation of the receivable state and shifts the operation state of the communication unit 100 to the low power consumption state (step S414). In the low power consumption state, the communication unit 100 cannot receive data from the remote controller 20, but the power consumption is suppressed as compared with the receivable state.

  On the other hand, when the flag is not ON, that is, OFF (step S412; NO), the control unit 101 determines whether or not the measurement time of the timer exceeds a preset predetermined time (step S413). When the measurement time of the timer does not exceed the predetermined time set in advance (step S413; NO), the control unit 101 executes the process of step S402 again.

  On the other hand, when the measurement time of the timer exceeds the preset predetermined time (step S413; YES), the control unit 101 shifts the operation state of the communication unit 100 to the low power consumption state (step S414).

  The control unit 101 determines whether or not a predetermined time has elapsed since the communication unit 100 shifted to the low power consumption state (step S415). When the predetermined time has elapsed (step S415; YES), The control unit 101 shifts the operation state of the communication unit 100 to a receivable state (step S416). As a result, the communication unit 100 is ready to receive data from the remote controller 20. Then, the control unit 101 turns off the flag and restarts the timer to measure time (step S417), and executes the process of step S402 again.

  FIG. 6 is a timing chart showing communication states of both the remote controller 20 and the air conditioner 10 described above. As shown in FIG. 6, while data is not transmitted from the remote controller 20, the operation state of the communication unit 100 of the air conditioner 10 is periodically repeated between a low power consumption state and a receivable state. That is, the communication unit 100 performs intermittent reception in communication with the remote controller 20.

  When the air conditioner 10 receives data from the remote controller 20 during intermittent reception, the air conditioner 10 receives the remote controller information data or the data from the remote controller 20 until a predetermined time has elapsed since the last reception of other data. Can always be received.

  Next, an example of setting the duration of a receivable state and the duration of a low power consumption state in intermittent reception of the air conditioner 10 will be described. For example, as shown in FIG. 7, the duration of the receivable state is set to be equal to or longer than the data retransmission interval of the remote controller 20. The duration of the low power consumption state is set to be equal to or less than the data retransmission interval of the remote controller 20 × (maximum number of transmissions−1). In this way, by setting the duration of the receivable state and the duration of the low power consumption state, air conditioning of the remote control information request data or remote control information data transmitted from the remote controller 20 in the remote control activation process or the remote control sleep process It is possible to prevent the machine 10 from being overlooked.

  Next, the current consumption of the remote controller 20 of this embodiment will be described. FIG. 8 is a diagram conceptually showing a temporal transition of current consumption during the operation of the remote controller 20 of the present embodiment.

  Generally, in the case of short-range wireless communication, current consumption during communication is about several tens of mA to several tens of mA. One communication time depends on the data rate, but is approximately several ms to several tens of ms. Further, during communication standby (when communication is not being performed but communication is possible), the current consumption is several mA to several tens of mA.

  In the remote controller 20 of the present embodiment, when power is being supplied from the main power supply control unit 201 (when power supply is ON), the communication unit 203 is driven to be in a communicable state, and the control unit 204 and the storage unit 205 are also driven. The current consumption is about several mA to several tens mA.

  Since the operation time of the remote control 20 by the user is assumed to be several seconds to several tens of seconds, most of the time during which the power supply of the remote control 20 is on is other than the operation time. I can say that. During the time other than the operation time, the power supply from the main power supply control unit 201 is in an OFF state, and in this state, only the main power supply control unit 201, the sub power supply control unit 202, and the startup operation reception unit 208 consume current. , About several μA to several tens μA. Therefore, the current consumption is much smaller than that during communication or communication standby.

  As described above, in the air conditioning control system 1 to which the communication system according to this embodiment of the present invention is applied, the air conditioner 10 receives data from the remote controller 20, so that the remote controller 20 is operated by the user. Knowing when you are. The air conditioner 10 is in a state where it can always receive data from the remote controller 20 while the remote controller 20 is being operated, but performs an intermittent operation otherwise. For this reason, the air conditioner 10 can perform communication with the remote controller 20 without hindrance, and can reduce power consumption.

  The remote controller 20 supplies power to main components only while being operated by the user. Therefore, the power consumption of the remote controller 20 can be reduced. Further, when the operation is started by the user, the remote control information is acquired from the air conditioner 10, and the remote control information is saved in the air conditioner 10 when the operation is finished. Therefore, when the user operates, the remote controller 20 holds the latest air conditioning settings, so that there is no inconvenience for the user and the convenience is not lowered.

  In addition, this invention is not limited to the said embodiment, Of course, the various change in the range which does not deviate from the summary of this invention is possible.

  For example, you may comprise so that communication with the remote control 20 and the air conditioning machine 10 may be performed via one or more relay machines. As a relay machine, for example, another remote controller having a function equivalent to the remote controller 20, another air conditioner having a function equivalent to the air conditioner 10, or other equipment may be used. Good. Thus, if it is set as the structure which communicates using a relay machine, since the communicable range spreads, a user's convenience improves further.

  The remote controller 20 may receive not only the remote control information transmitted by itself from the air conditioner 10, but also other additional information related to air conditioning. As additional information, for example, the actual temperature and humidity measured by the sensor of the air conditioner 10, the expected charge during operation, and the like are applicable. If the additional information is received together with the remote control information when the remote controller 20 is activated (when the operation is started), the user can obtain the additional information without any special operation, which is convenient.

  Further, in the wireless communication between the remote controller 20 and the air conditioner 10, the communication medium is not limited. For example, radio waves may be used, and infrared rays or other light may be used as a communication medium.

  Further, the interval of intermittent reception of the air conditioner 10, that is, the duration of the low power consumption state can be suitably set by the above-described method or the like, but does not need to be a fixed time. For example, the air conditioner 10 may appropriately change the interval of intermittent reception based on the communication history with the remote controller 20. In this case, the control unit 101 of the air conditioner 10 selects a time zone in which the frequency of use of the user is low from the communication history with the remote controller 20, and in that time zone, the interval of intermittent reception (the duration of the low power consumption state). Can be set longer than usual. In the example of FIG. 9, (a) shows the interval of intermittent reception at normal times, and (b) shows the interval of intermittent reception in a time zone (for example, midnight) where the user's usage frequency is low. If it does in this way, the reduction effect of the power consumption of the air conditioner 10 will increase further.

  In the remote controller 20 of the above embodiment, the power supply to the communication unit 203, the control unit 204, the storage unit 205, the setting operation reception unit 206, and the display unit 207 is stopped when the user is not operating. For example, a configuration unit that consumes less power, such as the setting operation reception unit 206, may be configured so that power is constantly supplied.

  In the above embodiment, in the remote control sleep process (see FIG. 4) by the remote controller 20, when the response data from the air conditioner 10 cannot be received and retransmission of the remote control information data is repeated, the number of transmissions reaches the maximum number of transmissions. (Step S306; YES), the control unit 204 sends a power supply stop signal to the main power supply control unit 201 (Step S307), and the remote control sleep process is terminated. However, the remote control sleep process may not be ended until the response data from the air conditioner 10 is received, that is, the power supply from the main power supply control unit 201 may not be turned off.

  FIG. 10 is a flowchart showing a processing procedure in this case. FIG. 10 shows only the processing flow added to the flowchart of FIG. When the number of transmissions reaches the maximum number of transmissions (step S306 in FIG. 4; YES), the control unit 204 shifts its own state to a low power consumption state (step S311). In this low power consumption state, the control unit 204 does not control at least the communication unit 203 (that is, the communication unit 203 does not function). For this reason, the power consumption of the remote controller 20 can be suppressed as compared with the standby mode. However, even in this case, when the activation operation accepting unit 208 accepts a user operation, the control unit 204 forcibly ends the remote control sleep process and preferentially executes the remote control activation process.

  Next, the control unit 204 determines whether or not a predetermined time (for example, about 1 hour) set in advance has elapsed since the transition to the low power consumption state (step S312). When a predetermined time has elapsed since the transition to the low power consumption state (step S312; YES), the control unit 204 transmits remote control information data to the air conditioner 10 (step S313).

  The control unit 204 determines whether or not response data from the air conditioner 10 for the transmitted remote control information data has been received (step S314). When the response data is received within a predetermined time after the transmission of the remote control information data (step S314; YES), the control unit 204 sends a power supply stop signal to the main power supply control unit 201 (step S307 in FIG. 4). On the other hand, when the response data is not received within the predetermined time (step S314; NO), the control unit 204 executes the process of step S311 again.

  Thus, by adding the processing flow shown in FIG. 10 to the flowchart of the remote control sleep processing shown in FIG. 4, it is possible to reliably save the remote control information data in the air conditioner 10 while suppressing the power consumption. .

  The present invention can be suitably applied not only to an air conditioning control system but also to various equipment control systems including other equipment such as an illuminator and a remote controller.

DESCRIPTION OF SYMBOLS 1 Air conditioning control system 10 Air conditioner 100 Communication part 101 Control part 102 Storage part 20 Remote control 200 Power supply part 201 Main power supply control part 202 Sub power supply control part 203 Communication part 204 Control part 205 Storage part 206 Setting operation reception part 207 Display part 208 Start-up Operation reception part

Claims (11)

A communication system comprising equipment and a remote controller for remotely operating the equipment,
The equipment is
Communication means for performing wireless communication with the remote controller;
A control means for controlling the communication means so as to be intermittently receivable, and acquiring data from the remote controller received by the communication means,
When the communication unit receives the predetermined data transmitted from the remote controller, the control unit continues the receivable state until a predetermined condition is satisfied,
The remote controller is
A communication means for performing wireless communication with the equipment,
Control means for controlling the communication means to transmit data to the equipment, and to obtain data from the equipment received by the communication means;
Power supply control means for supplying power to the communication means and the control means;
A setting operation receiving means for receiving an operation input related to the setting of the equipment from the user;
Starting operation receiving means for receiving an operation input related to starting of the remote controller from a user,
The power control means starts supplying the power when the activation operation accepting means accepts the operation input when the power supply is stopped.
The control means includes
When the activation operation accepting unit accepts the operation input, the activation operation data indicating the activation start of the remote controller is transmitted to the equipment device,
When a predetermined condition is satisfied, the start-up stop data indicating start-stop of the remote controller is transmitted to the facility device, and then the supply of power by the power control unit is stopped ,
In the equipment,
The control means cancels the continuation of the receivable state when the communication means receives the start / stop data.
A communication system characterized by the above. In the equipment,
The control means releases the continuation of the receivable state after a predetermined time has elapsed since the communication means last received data other than the start / stop data in the receivable state period.
The communication system according to claim 1 . In the remote controller,
When the predetermined time elapses from the later of the time when the start operation accepting unit last accepts the operation input or the time when the setting operation accepting unit last accepts the operation input, the control unit Determining that the predetermined condition is satisfied,
The communication system according to claim 1 or 2 . In the remote controller,
The power control means further supplies the power to a volatile memory,
The volatile memory stores setting information related to the setting of the equipment,
The control means includes
When the predetermined condition is satisfied, the start / stop data storing the setting information read from the volatile memory is transmitted to the equipment device,
When the communication means receives response data from the equipment for the activation start data, the setting information extracted from the response data is stored in the volatile memory,
In the equipment,
The control means includes
When the communication means receives the start / stop data, the setting information extracted from the start / stop data is stored in a predetermined memory,
When the communication means receives the start-up data, it transmits response data storing the setting information read from the memory to the remote controller.
The communication system according to any one of claims 1 to 3 , wherein: In the equipment, the control means changes the intermittent reception interval of the communication means based on a communication history with the remote controller.
The communication system according to any one of claims 1 to 4 , characterized in that: A remote controller for remotely operating equipment,
A communication means for performing wireless communication with the equipment,
Control means for controlling the communication means to transmit data to the equipment, and to obtain data from the equipment received by the communication means;
Power supply control means for supplying power to the communication means and the control means;
A setting operation receiving means for receiving an operation input related to the setting of the equipment from the user;
Starting operation receiving means for receiving an operation input related to starting of the remote controller from a user,
The power control means starts supplying the power when the activation operation accepting means accepts the operation input when the power supply is stopped.
The control means includes
When the activation operation accepting unit accepts the operation input, the activation operation data indicating the activation start of the remote controller is transmitted to the equipment device,
When a predetermined condition is satisfied, the start-up stop data indicating start-stop of the remote controller is transmitted to the equipment, and then the supply of power by the power control unit is stopped.
A remote controller characterized by that. When the predetermined time elapses from the later of the time when the start operation accepting unit last accepts the operation input or the time when the setting operation accepting unit last accepts the operation input, the control unit Determining that the predetermined condition is satisfied,
The remote controller according to claim 6 . Equipment that is remotely controlled by a remote controller,
Communication means for performing wireless communication with the remote controller;
A control means for controlling the communication means so as to be intermittently receivable, and acquiring data from the remote controller received by the communication means,
When the communication means receives the predetermined data transmitted from the remote controller, the control means continues the receivable state until a predetermined condition is satisfied , and the communication means transmits the remote controller from the remote controller. When receiving the start / stop data indicating the start / stop of the controller, the continuation of the reception enabled state is canceled
Equipment equipment characterized by that. The control means releases the continuation of the receivable state after a predetermined time has elapsed since the communication means last received data other than the start / stop data in the receivable state period.
The equipment according to claim 8 . The duration of the receivable state is set to be equal to or longer than the data retransmission interval of the remote controller.
The equipment according to claim 8 or 9, wherein The same state data is transmitted from the remote controller until the one data from the remote controller is acquired by the control means at the data retransmission interval of the remote controller during the duration of the operation state that is not in the receivable state. Set to be less than or equal to the time obtained by multiplying the maximum number minus one.
The equipment according to any one of claims 8 to 10, wherein

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