JP6520997B2 - Door phone device - Google Patents

Description

  The present disclosure relates to a door phone device.

  Awareness for crime prevention has been increasing year by year, and in recent years there has been an increasing demand for low cost, easy installation and realization of front door slaves and the like not only in single-family homes but also in single-family households such as studio apartments.

  In order to meet such low-cost and easy installation requirements, wireless communication between the two has also begun to disseminate one that requires no wiring work. For example, Patent Document 1 discloses a television door phone apparatus including an entrance slave unit and a wireless master unit for performing wireless communication with the entrance slave unit.

Unexamined-Japanese-Patent No. 2008-252271

  When the front door slave unit or the wireless master unit is battery-operated, it is desirable to suppress power consumption in order to save time and effort such as battery replacement or battery charging.

  An object of the present invention is to provide a door phone device that suppresses power consumption.

A door phone device according to an aspect of the present invention is a door phone device that performs wireless communication between a parent device and a child device, and the child device is activated from a sleep state at an activation interval set by the parent device. Repeat temporarily becomes operational state operation Te, the master unit when the slave unit of the稼work state, according to a predetermined condition, the initiation interval of the child machine, the first initiation interval, Alternatively, transition request information for transitioning to any of the second activation intervals longer than the first activation interval is transmitted to the slave unit to set the activation interval of the slave units, and the predetermined condition is: The remaining amount of battery of the child device, and the parent device transmits, to the child device, transition request information for causing transition to the second activation interval when the battery remaining amount of the child device is less than a threshold, Transition request to shift to the first activation interval when the remaining battery level of the slave unit is equal to or higher than the threshold Sending a multi-address to the slave unit.

  According to the present invention, power consumption of the door phone device can be suppressed.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the television door phone apparatus which concerns on embodiment of this invention. The block diagram which shows the structural example of a front door slave unit. The block diagram showing the example of composition of the indoor child machine. The figure which shows transition of power consumption mode. FIG. 7 is a diagram showing transition processing from the normal power consumption mode to the low power consumption mode. FIG. 7 is a diagram showing transition processing from the low power consumption mode to the ultra low power consumption mode. FIG. 8 is a diagram showing transition processing from the ultra low power consumption mode to the normal power consumption mode. FIG. 6 is a view showing a first example of a setting screen of a power consumption mode of a parent device. The figure which shows the 2nd example of the setting screen of the power consumption mode of a main | base station. The figure which shows the 3rd example of the setting screen of the power consumption mode of a main | base station. The figure which shows the 4th example of the setting screen of the power consumption mode of a main | base station. FIG. 1 is a diagram showing an example of a hardware configuration according to an embodiment of the present invention.

  Hereinafter, the embodiments will be described in detail with reference to the drawings.

Embodiment
<Configuration of TV Door Phone Device>
First, the configuration of a television door phone apparatus 1 according to an embodiment of the present invention will be described with reference to FIG.

  The television door phone apparatus 1 includes a front door slave unit (hereinafter referred to as "child unit") 10 and an indoor parent unit (hereinafter referred to as "parent unit") 20, and the child unit 10 and the parent unit 20 are connected by a wireless communication circuit N. Do. Although one slave unit 10 is connected to the master unit 20 in FIG. 1, two or more slave units 10 may be connected to the master unit 20.

  The handset 10 is installed, for example, at the entrance, and includes a call button 109, a handset camera 11, a handset microphone 13, and a handset speaker 12.

  The parent device 20 is installed, for example, indoors, and includes an operation unit 211, a display 21, a parent device microphone 23, and a parent device speaker 22. The operation unit 211 includes a response button for responding to depression of the call button 109 of the slave unit 10, a monitor button for acquiring a captured image of the slave unit camera 11, a control button for controlling the slave unit 10, and the like. . The display 21 is, for example, an LCD (Liquid Crystal Display).

  Next, an outline of the operation of the television door phone device 1 will be described.

  When the visitor presses the call button 109 of the handset 10, the base unit 20 displays the photographed image of the handset camera 11 on the display 21 and outputs the voice inputted to the handset microphone 13 from the base unit speaker 22. . Thereby, the resident can confirm the image and the sound of the visitor from the parent device 20. Further, at this time, when the resident presses the response button of the parent device 20, the parent device 20 outputs the voice input to the parent device microphone 23 from the child device speaker 12. Thus, the resident can talk with the visitor through the parent device 20. Hereinafter, these processes are collectively called "call response process".

  When the resident presses the monitor button of the parent device 20, the parent device 20 acquires a photographed image of the child device camera 11 and displays the image on the display 21. Thereby, the resident can confirm the situation (for example, a suspicious person or a suspicious object) in the vicinity of the entrance from the parent device 20. Hereinafter, this process is referred to as "front door confirmation process".

  Also, the resident can operate the control button of the parent device 20 to perform various settings regarding the power consumption mode of the child device 10. Although the details of the power consumption mode and the setting method thereof will be described later, the consumption of the battery of the child device 10 can be suppressed thereby.

<Configuration of handset>
Next, the configuration of the slave unit 10 will be described with reference to FIG.

  The handset 10 includes a handset camera 11, a handset speaker 12, a handset microphone 13, a handset wireless communication unit 101, an audio processing unit 102, an image processing unit 103, a handset power supply unit 104, and a handset interrupt detection unit 105. A power supply monitoring unit 106, a storage unit 107, a slave unit control unit 108, a call button 109, a quartz oscillator 131, and a quartz oscillator 132 are provided. The handset wireless communication unit 101, the audio processing unit 102, the image processing unit 103, the power supply monitoring unit 106, the storage unit 107, and the handset control unit 108 are collectively referred to as a handset main unit 100.

  The slave wireless communication unit 101 transmits and receives data to and from the master 20 via the wireless communication line N. The communication scheme by the slave wireless communication unit 101 is, for example, Digital Enhanced Cordless Telecommunications (DECT), wireless local area network (LAN), or ZigBee (registered trademark).

  The voice processing unit 102 controls the handset speaker 12 and the handset microphone 13 based on an instruction from the handset control unit 108. For example, the audio processing unit 102 outputs the audio data collected by the slave microphone 13 to the slave control unit 108. Further, the audio processing unit 102 outputs the audio data collected by the parent device microphone 23 input from the slave device control unit 108 to the slave device speaker 12.

  The image processing unit 103 controls the slave camera 11 based on an instruction from the slave controller 108. For example, the image processing unit 103 outputs data of an image captured by the slave camera 11 to the slave control unit 108.

  The slave unit power supply unit 104 supplies the power for operating the slave unit 10 to each unit. The child device power supply unit 104 includes a battery 122 which is a power supply source, and a switching element 121 which turns on / off the supply of power to the child device main unit 100. The battery 122 may be either a primary battery or a secondary battery. In the present embodiment, the battery 122 is used for the slave 10 in consideration of the installation, but an AC power supply or an AC adapter may be used for the slave 10.

  The slave unit interrupt detection unit 105 detects an interrupt by the call button 109, an interrupt by the timer 130, and an interrupt by the occurrence of various events. Interrupt detection includes hardware and software.

  The handset interrupt detection unit 105 also has a function of controlling power supply from the handset power supply unit 104 to the handset main unit 100 in order to reduce the power consumption of the battery 122 as much as possible. For example, the slave unit interrupt detection unit 105 is disposed between the slave unit power supply unit 104 and the slave unit main unit 100 on the circuit. Then, only the slave unit interrupt detection unit 105 is constantly operated by a weak current (for example, several microamperes) supplied from the battery 122, and power is supplied to the slave unit main unit 100 based on the above-described interrupt detection. Switching element 121 for switching on / off.

  Hereinafter, the fact that the switching element 121 is on may be referred to as “main power on”, and the fact that the switching element 121 is off may be referred to as “main power off”. In addition, the main power is ON, that is, the state where power is supplied to the handset main unit 100 is "operating status", and the main power is OFF, that is, the power is not supplied to the handset main unit 100. A state in which only the slave unit interrupt detection unit 105 is operating with a weak current is referred to as a "sleep state".

  Note that in order to minimize the bias current of the slave unit interrupt detection unit 105 while the switching element 121 is off, the slave unit interrupt detection unit 105 is lower than the crystal oscillator 132 employed in the slave unit control unit 108. A quartz oscillator 131 with an oscillation frequency (for example, 32 kHz) is employed.

  When the main power is on, power supply monitoring unit 106 measures the remaining amount of battery 122 (hereinafter referred to as “remaining battery amount”), and outputs the measurement result to slave unit control unit 108. The battery remaining amount is, for example, a voltage value of the battery 122. However, the battery remaining amount may be expressed by a prescribed level value instead of the voltage value. For example, if the voltage value of the battery 122 is equal to or higher than the first threshold, "level 3", if lower than the first threshold and higher than the second threshold, "level 2", if lower than the second threshold It may be expressed as “Level 1”. In addition, the power supply monitoring unit 106 may include hysteresis in the measurement of the voltage value of the battery 122. In the case of a system in which an increase in current consumption in the sleep state is not a problem, the slave device interrupt detection unit 105 may be provided with a power supply monitoring function so that power supply monitoring can be performed even in the sleep state.

  The storage unit 107 is configured by a flash memory or the like, and stores, for example, device information such as an identification number of the slave 10, setting information, status information of the master 20, image data before transmission to the master 20, and the like.

  The child device control unit 108 performs arithmetic processing for controlling each part of the child device 10.

  Specifically, the slave unit interrupt detection unit 105 detects an interrupt of depression of the call button 109, turns on the main power, and transmits an event occurrence notification of depression of the call button 109 to the slave unit control unit 108. When the main power supply is ON, the slave control unit 108 transmits an event occurrence notification indicating that the call button 109 is pressed, and transmits a notification to that effect to the master 20 through the slave wireless communication unit 101. The handset control unit 108 receives the captured image data of the handset camera 11 input from the image processing unit 103 and the voice data of the handset microphone 13 input from the voice processing unit 102 as a handset wireless communication unit. It transmits to the parent device 20 through 101. As a result, the resident indoors can confirm the visitor present near the front door from the main unit 20. Furthermore, the handset control unit 108 outputs the audio data of the base unit microphone 23 received from the base unit 20 through the handset wireless communication unit 101 to the handset speaker 12 through the audio processing unit 102. This allows the outdoor visitor and the indoor resident to have a conversation. That is, the slave control unit 108 cooperates with the master 20 to realize the “call response process”.

  In addition, when the main unit power is on, when the slave unit control unit 108 receives request information of a photographed image of the slave unit camera 11 from the master unit 20 through the slave unit wireless communication unit 101, the slave unit control unit 108 is input from the image processing unit 103. The photographed image data of the slave camera 11 and the voice data of the slave microphone 13 input from the voice processing unit 102 are transmitted to the master 20 through the slave wireless communication unit 101 for a predetermined time. As a result, the resident can confirm the situation in the vicinity of the entrance from the parent device 20. That is, the slave control unit 108 cooperates with the master 20 to realize the “front entrance confirmation process”.

  In addition, when the slave unit control unit 108 receives request information on the remaining battery level from the master unit 20 through the slave unit wireless communication unit 101, the slave unit control unit 108 determines the remaining battery level measured by the power supply monitoring unit 106 through the slave unit wireless communication unit 101. Send to machine 20. In addition, when the child device control unit 108 receives power consumption mode transition request information from the parent device 20 through the child device wireless communication unit 101, the child device control unit 108 controls the child device interrupt detection unit 105 to perform power consumption mode transition processing. I do. The details of these processes will be described later.

<Configuration of base unit>
Next, the configuration of the parent device 20 will be described with reference to FIG.

  The parent device 20 includes the display 21, the parent device speaker 22, the parent device microphone 23, the parent device wireless communication unit 201, the RSSI level detection unit 202, the voice processing unit 203, the display processing unit 204, the parent device power supply unit 205, and the parent device division A loading detection unit 206, a storage unit 207, a charge detection unit 208, a clock function management unit 209, a parent device control unit 210, an operation unit 211, a quartz oscillator 231, and a quartz oscillator 232 are provided. The base unit wireless communication unit 201, the RSSI level detection unit 202, the voice processing unit 203, the display processing unit 204, the storage unit 207, the charge detection unit 208, the clock function management unit 209, and the base unit control unit 210 are collectively described. The main unit main unit 200 is called.

  The master wireless communication unit 201 transmits and receives data to and from the slave 10 via the wireless communication line N. The communication method by the parent device wireless communication unit 201 is, for example, DECT, a wireless LAN, or ZigBee (registered trademark), as in the case of the child device 10.

  The RSSI level detection unit 202 detects the strength of the radio signal received by the base unit wireless communication unit 201 from the slave unit 10, that is, the RSSI (Received Signal Strength Indicator) level.

  The voice processing unit 203 controls the parent device microphone 23 and the parent device speaker 22 based on an instruction from the parent device control unit 210. For example, the audio processing unit 203 outputs the audio data collected by the slave microphone 13 to the master speaker 22. Further, the audio processing unit 203 outputs the audio data collected by the parent device microphone 23 to the parent device control unit 210.

  The display processing unit 204 controls the display 21 based on an instruction from the parent device control unit 210. For example, the display processing unit 204 outputs a photographed image of the slave camera 11, a setting screen (see FIGS. 8 to 11), and the like to the display 21.

  The parent device power supply unit 205 supplies electric power for the parent device 20 to operate to each part. The parent device power supply unit 205 includes a power supply 222 that is a power supply source, and a switching element 221 that turns on / off the supply of power to the parent device main unit 200. The power source 222 may be an AC power source or an AC adapter, or may be a battery such as a primary battery or a secondary battery.

  The master unit interrupt detection unit 206 detects an interrupt by the operation unit 211, an interrupt by the timer 230, and an interrupt by the occurrence of various events. Interrupt detection includes hardware and software.

  Further, the master unit interrupt detection unit 206 also has a function of controlling power supply from the master unit power supply unit 205 to the master unit main unit 200. For example, on the circuit, the base unit interrupt detection unit 206 is disposed between the base unit power supply unit 205 and the base unit main unit 200. Then, only the base unit interrupt detection unit 206 is constantly operated by a weak current (for example, several microamperes) supplied from the power supply 222, and power is supplied to the base unit main unit 200 based on predetermined interrupt detection. Switching element 221 for switching on / off.

  Hereinafter, the fact that the switching element 221 is ON may be referred to as “main power ON”, and the fact that the switching element 221 is OFF may be referred to as “main power OFF”. Also, the main power is on, that is, the power is supplied to the main unit main unit 200 as “operating state”, and the main power is off, that is, the power is not supplied to the main unit main unit 200. A state in which only the master unit interrupt detection unit 206 is operating with a weak current is referred to as a "sleep state".

  The parent device 20 is always in an operating state, for example, when the power supply 222 does not need to replace the battery, such as power supply from an AC power supply or an AC adapter, or power supply from a secondary battery that can be set in a charging stand. It may be Further, when using the sleep state, the parent device 20 may set the period of the operation state according to the timing of communication with the slave device 10, and may set the sleep state for the remaining period other than the operation state.

  In order to minimize the bias current of the parent device interrupt detection unit 206 while the switching element 221 is off, the parent device interrupt detection unit 206 uses the crystal oscillator 232 employed in the parent device control unit 210. Alternatively, a quartz oscillator 231 with a low oscillation frequency (for example, 32 kHz) may be employed.

  The storage unit 207 is configured by a flash memory or the like, and includes various images, sounds, and other management information. The image includes, for example, a moving image and a still image, and includes an image taken by the child device camera 11 and an image for operating the parent device 20. The sound includes, for example, the sound of a fixed message issued from the parent device 20. The other management information includes, for example, password information for preventing various setting information of the parent device 20 from being changed arbitrarily.

  The charge detection unit 208 detects whether the base unit 20 is placed on a charging stand or the like and the base unit power supply unit 205 is connected to an external power supply. In addition, when the parent device 20 does not have the charging function, the parent device 20 may not include the charge detection unit 208.

  When the set start time and end time have come, the clock function management unit 209 notifies the parent device control unit 210 to that effect. When the clock function management unit 209 is used, the main device 20 needs to be in a state where the main power is on. In the case of a system in which the parent device 20 uses the sleep state and the increase in the consumption current of the parent device 20 does not cause a problem, the parent device interrupt detection so that the clock function can be operated even in the sleep state. The unit 206 may be provided with a clock function management unit.

  The parent device control unit 210 performs arithmetic processing for controlling each part of the parent device 20.

  Specifically, when the main device control unit 210 receives an event occurrence notification that the call button 109 is pressed from the child device 10 through the main device wireless communication unit 201 when the main power is on, the main device wireless communication unit 201 The image data taken by the slave camera 11 is received and displayed on the display 21 through the display processing unit 204. Further, the master control unit 210 receives audio data of the slave microphone 13 through the master wireless communication unit 201, and outputs the voice data to the master speaker 22 through the audio processing unit 203. As a result, the resident indoors can confirm the visitor present near the front door from the main unit 20. Furthermore, when the base unit control unit 210 receives an interrupt notification of pressing of the response button from the base unit interrupt detection unit 206, the base unit wireless communication unit receives the voice data of the base unit microphone 23 acquired through the voice processing unit 203. It transmits to the cordless handset 10 through 201. This allows the outdoor visitor and the indoor resident to have a conversation. That is, the master unit control unit 210 cooperates with the slave unit 10 to realize the “call response process”.

  In addition, when the main unit control unit 210 receives an interrupt notification of pressing the monitor button from the main unit interrupt detection unit 206 when the main power is on, the main unit wireless communication unit 201 of the slave unit camera The photographed image data is received and displayed on the display 21 through the display processing unit 204 for a predetermined time. Also, when the main power is on, the master control section 210 receives voice data of the slave microphone 13 through the master wireless communication section 201, and outputs the voice data to the master speaker 22 through the voice processing section 203 for a certain period of time. . As a result, the resident can confirm the situation in the vicinity of the entrance from the parent device 20. That is, base unit control unit 210 cooperates with handset 10 to realize the “front entrance confirmation process”.

  In addition, base unit control section 210 transmits a request for remaining battery capacity to handset 10 through base unit wireless communication section 201. Then, base unit control unit 210 determines the power consumption mode based on the battery remaining amount received from slave unit 10, and transmits a transition request for the power consumption mode to slave unit 10 as necessary. Further, base unit control unit 210 determines the power consumption mode in accordance with the operation and setting of the resident, and transmits a power consumption mode shift request to slave unit 10 as necessary. The details of these processes will be described later.

<Communication method and power consumption mode>
Next, with reference to FIG. 4, the communication method and the power consumption mode in the television door phone device 1 will be described.

  The first communication method is a communication method in which the slave 10 periodically repeats ON / OFF of the main power. That is, in the first communication method, handset 10 periodically repeats the operating state and the sleep state. Hereinafter, in the first communication method, an interval from when the main power supply is turned on to when the main power supply is next turned on is referred to as a "startup interval". The activation interval is counted by the timer 130 of the slave unit interrupt detection unit 105.

  In the first communication method, the power consumption of the handset 10 decreases as the activation interval is lengthened. However, if the activation interval is too long, the shift between the crystal oscillator 231 of the master unit 20 and the crystal oscillator 131 of the slave unit 10 becomes too large, and synchronization of wireless communication between the master unit 20 and the slave unit 10 Will come off. Therefore, the longest activation interval that can be set to the first communication method is set to the longest interval (for example, 10.24 seconds) in which synchronization of wireless communication is not lost between the parent device 20 and the child device 10.

  In the present embodiment, in the first communication method, the case where a relatively short activation interval (for example, 2.56 seconds) is set is referred to as a “normal power consumption mode”, and a relatively long activation interval (for example, 10. The case where 24 seconds is set is called "low power consumption mode". However, this setting is merely an example, and in the first communication method, any activation interval may be set within a range not exceeding the longest activation interval.

  The second communication method is a communication method in which the slave 10 turns off the main power for a set period, and turns on the main power after the set period has expired. That is, in the second communication method, the slave 10 is in the sleep state for a set period, and is in the operating state after the set period has expired. Hereinafter, in the second communication method, a period from when the main power is turned off to when the main power is turned on next is referred to as a “sleep period”. The sleep period is counted by the timer 130 of the slave unit interrupt detection unit 105.

  In the second communication method, since it is not necessary to maintain synchronization of wireless communication between the master unit 20 and the slave unit 10 in the operation of the sleep period, it is possible to set a long time (for example, several hours) is there. For this reason, although the second communication method requires a long time (for example, about 1 second) to resynchronize wireless communication after activation, the power consumption of the slave unit 10 is greatly reduced compared to the first communication method. can do. In the present embodiment, the second communication method is referred to as “ultra-low power consumption mode”.

  In the case of the first communication method, since the slave 10 periodically repeats the operating state and the sleep state, the slave 10 transmits the request information transmitted from the master 20 to the next operating state. It can be received. That is, in the case of the first communication method, the slave unit 10 can respond to the request information from the master unit 20 (for example, the request information of the photographed image of the slave unit camera 11) within the activation interval. It is possible to confirm a photographed image of the slave camera 11.

  On the other hand, in the case of the second communication method, once in sleep mode, handset 10 does not activate until the sleep period has expired. That is, in the case of the second communication method, the child device 10 can not respond to the request information from the parent device 20 (for example, the request information of the photographed image of the child device camera 11) until the sleep period expires. It is not possible to confirm the photographed image of the slave camera 11 from the machine 20.

  Therefore, in the case of the first communication method, that is, in the case of the normal power consumption mode and the low power consumption mode, the television door phone device 1 enables the monitor button of the main unit 20, and in the case of the second communication method, that is, In the case of the ultra low power consumption mode, the monitor button of the parent device 20 may be disabled.

<Transition condition of power consumption mode>
Next, referring to FIG. 4 as well, transition conditions of the power consumption mode will be described. However, the television door phone apparatus 1 need not necessarily have all the transition conditions described below, and may have only some of the transition conditions.

  First, the transition condition (M1) between the normal power consumption mode and the low power consumption mode will be described below.

  (M1-1) If the remaining battery level of the handset 10 is less than the first threshold in the normal power consumption mode, the handset 10 shifts to the low power consumption mode. At this time, the parent device 20 may display on the display 21 that the battery remaining amount of the child device 10 is less than the first threshold.

  (M1-2) When the resident performs a transition operation to the low power consumption mode in the normal power consumption mode, the child device 10 shifts to the low power consumption mode, and automatically after a predetermined period has elapsed Transition to the normal power consumption mode. The transition operation may be an operation of a dedicated button provided on the parent device or child device, a long press of a predetermined button of the parent device or child device, or a simultaneous push of a plurality of buttons of the parent device or child device. The resident may perform the transition operation, for example, when going out.

  (M1-3) The start time and end time of the low power consumption mode are set, and when the normal power consumption mode is set at the start time, the slave unit 10 enters the low power consumption mode when the start time is reached. Transition to the normal power consumption mode when the end time is reached. The resident may set the start time and the end time according to, for example, the time of going to bed and getting up.

  (M1-4) When the base unit 20 has not been operated for a predetermined period or more in the normal power consumption mode, the slave unit 10 transitions to the low power consumption mode, and the base unit 20 is operated when the base unit 20 is operated. Transition to power mode.

  Next, transition conditions (M2) between the normal power consumption mode and the ultra-low power consumption mode will be described below.

  (M2-1) If the remaining battery level of handset 10 is less than the second threshold (where the second threshold <the first threshold) in the normal power consumption mode, handset 10 enters the ultra-low power consumption mode. Transition. At this time, the parent device 20 displays a message on the display 21 asking whether it may shift to the ultra low power consumption mode since the battery remaining amount of the child device 10 is small (less than the second threshold), It may shift to the ultra low power consumption mode when the person permits.

  (M2-2) When the resident performs the transition operation to the ultra low power consumption mode in the normal power consumption mode, the child device 10 shifts to the ultra low power consumption mode, and after a predetermined period has elapsed, Automatically transition to the normal power consumption mode. In addition, when the transition operation is performed, the parent device 20 may display a default value of the predetermined period, and the resident may change the predetermined period as needed. The transition operation may be an operation of a dedicated button provided on the parent device or child device, a long press of a predetermined button of the parent device or child device, or a simultaneous push of a plurality of buttons of the parent device or child device. The resident may perform the transition operation, for example, when going out.

  (M2-3) If the start time and end time of the ultra low power consumption mode are set and the normal power consumption mode is set at the start time, the slave unit 10 receives the ultra low power when the start time is reached. Transition to power consumption mode and transition to normal power consumption mode when the end time is reached. The resident may set the start time and the end time according to, for example, the time of going to bed and getting up.

  (M2-4) When the call button 109 of the handset 10 is pressed during the sleep period in which the normal power consumption mode is shifted to the ultra-low power consumption mode, the handset 10 executes call response processing. In this case, the slave unit 10 may shift to the ultra-low power consumption mode after the call response process ends or after the master unit 20 has not responded and a predetermined time has elapsed.

  Next, the transition condition (M3) between the low power consumption mode and the ultra low power consumption mode will be described.

  (M3-1) When the remaining battery level of the handset 10 is less than the second threshold in the low power consumption mode, the handset 10 shifts to the ultra-low power consumption mode. At this time, the parent device 20 displays a message on the display 21 asking whether it may shift to the ultra-low power consumption mode since the battery remaining amount of the child device 10 is small (less than the second threshold). It may shift to the ultra-low power consumption mode when permitted.

  (M3-2) When the resident performs the transition operation to the ultra low power consumption mode in the low power consumption mode, the child device 10 shifts to the ultra low power consumption mode, and after a predetermined period has elapsed, Automatically transition to low power consumption mode. In addition, when the transition operation is performed, the parent device 20 may display a default value of the predetermined period, and the resident may change the predetermined period as needed. The transition operation may be an operation of a dedicated button provided on the parent device or child device, a long press of a predetermined button of the parent device or child device, or a simultaneous push of a plurality of buttons of the parent device or child device. The resident may perform the transition operation, for example, when going out.

  (M3-3) If the start time and end time of the ultra low power consumption mode are set and the low power consumption mode is set at the start time, the child device 10 is ultra low when the start time is reached. Transition to power consumption mode and transition to low power consumption mode when the end time is reached. The resident may set the start time and the end time according to, for example, the time of going to bed and getting up.

  (M3-4) When the call button 109 of the handset 10 is pressed during the sleep period in which the low power consumption mode is shifted to the ultra-low power consumption mode, the handset 10 executes call response processing. In this case, the slave unit 10 may shift to the ultra-low power consumption mode after ending the call response process or after the parent unit 20 has not responded and a predetermined time has elapsed.

<Transition process of power consumption mode>
5 to 7 are diagrams showing temporal changes in current consumption of the parent device 20 and the child device 10. FIG. The master unit 20 periodically (for example, every 10 ms) transmits a beacon signal, at which time the current consumption rises. That is, in the graphs of the parent device 20 in FIGS. 5 to 7, the timing at which the consumption current rises periodically corresponds to the timing at which the parent device 20 transmits a beacon signal. Further, in the graphs of the handsets 10 of FIG. 5 to FIG. 7, it is shown that the handset 10 is in the operating state while the consumption current is rising, and the handset 10 is the period when the consumption current is extremely small. Indicates a sleep state.

  Next, the transition process from the normal power consumption mode to the low power consumption mode will be described with reference to FIG. The transition processing corresponds to processing for changing the activation interval in the first communication method. Hereinafter, the process of (M1-1) will be described first, and then the processes of (M1-2) and (M1-3) will be described.

  The slave unit 10 is activated at timing (P11) at which the activation interval Ts1 of the normal power consumption mode has elapsed, and becomes in an operating state. Then, upon receiving request information on the remaining battery level from the main unit 20 by the beacon signal from the main unit 20 (S11), the slave unit 10 transmits response information including the remaining battery level acquired from the power supply monitoring unit 106 to the main unit 20 ( S12).

  Master device 20 determines whether the remaining battery level received from slave device 10 is less than the first threshold. Then, when the remaining battery level is less than the first threshold, the parent device 20 transmits transition request information for transition to the low power consumption mode by the next beacon signal (S13). The transition request information may include the start interval Ts2 of the low power consumption mode.

  The slave 10, upon receiving the transition request information to shift to the low power consumption mode at S13, transmits the completion response information to the master 20 (S14), and shifts to the low power consumption mode. That is, slave unit 10 sets activation interval Ts2 in timer 130 of slave unit interrupt detection unit 105, and turns off the main power. Thereafter, the slave unit 10 repeats ON / OFF of the main power supply at the startup interval Ts2.

  In the case of the above (M1-2), that is, when the transition operation to the low power consumption mode is performed, the parent device 20 is a beacon signal of the timing when the child device 10 is put into operation next time. The power mode shift request information is transmitted (S13). Then, after a predetermined time has elapsed, master device 20 transmits a transition signal to request for transition to the normal power consumption mode, using a beacon signal at the timing when slave device 10 is put into operation.

  In the case of (M1-3) above, that is, when the start time and the end time of the low power consumption mode are set, the parent device 20 sets the timing at which the child device 10 will be in operation next after the start time. Request information for transition to the low power consumption mode is transmitted using the beacon signal of (S13). Then, after the end time, master device 20 transmits a request signal for transitioning to the normal power consumption mode with a beacon signal of the timing when slave device 10 will be in operation next.

  In the case of (M1-4) above, that is, when the parent device 20 has not been operated for a predetermined period, the parent device 20 is beaconed at a timing when the child device 10 becomes in operation next after a predetermined period has elapsed. The signal including the request information for transition to the low power consumption mode is transmitted by the signal (S13). Then, after the base unit 20 is operated, the base unit 20 transmits the transition request information to the normal power consumption mode by the beacon signal of the timing when the base unit 10 is put into operation next.

  Thus, the television door phone device 1 switches between the normal power consumption mode and the low power consumption mode based on the transition conditions of the power consumption mode from (M1-1) to (M1-4).

  Next, the transition process from the low power consumption mode to the ultra low power consumption mode will be described with reference to FIG. Hereinafter, the process of (M3-1) will be described first, and then the processes of (M3-2) and (M3-3) will be described. The processes from (M2-1) to (M2-3) are the same as (M3-1) to (M3-3) except for the start-up interval, and thus the description thereof is omitted.

  The slave unit 10 is activated at timing (P21) when the activation interval Ts2 of the low power consumption mode has elapsed, and is put into operation. Then, when the child device 10 receives the request information of the battery remaining amount from the base device 20 in the beacon signal (S21), it transmits response information including the battery remaining amount to the parent device 20 (S22).

  Master device 20 determines whether the battery remaining amount received from slave device 10 is less than the second threshold. Then, if the remaining battery level is less than the second threshold, the base unit 20 transmits transition request information for transition to the ultra-low power consumption mode by the next beacon signal (S23). The transition request information may include the sleep period Ts3 of the ultra low power consumption mode.

  The slave 10, upon receiving the transition request information to shift to the ultra-low power consumption mode at S23, transmits completion response information to the master 20 (S24), and shifts to the ultra-low power consumption mode. That is, the slave unit 10 sets the sleep period Ts3 in the timer 130 of the slave unit interrupt detection unit 105, and turns off the main power. Thereafter, the slave unit 10 sleeps until the sleep period Ts3 expires, and is activated after the sleep period Ts3 expires (P22).

  In the case of (M3-2) above, that is, when the transition operation to the ultra-low power consumption mode is performed in the low power consumption mode, the master unit 20 next operates the slave unit 10 The transition request information to the ultra low power consumption mode is transmitted by the beacon signal of the timing (S23). Then, the master device 20 transmits the transition request information to the normal power consumption mode by the beacon signal after the expiration of the sleep period Ts3.

  Also, in the case of (M3-3) above, that is, when the start time and the end time of the ultra low power consumption mode are set in the low power consumption mode, the parent device 20 In the beacon signal at the timing when the machine 10 is in operation, the request information for transition to the ultra low power consumption mode is transmitted (S23). Then, the parent device 20 transmits the transition request information to the low power consumption mode by the beacon signal after the end time.

  Next, the transition process from the ultra low power consumption mode to the normal power consumption mode will be described with reference to FIG. Below, the process of (M2-2) and (M2-3) is demonstrated first, and the process of (M2-4) is demonstrated next. The processes of (M3-2) and (M3-4) are the same as the processes of (M2-2) to (M2-4) except that the activation intervals are different, and thus the description thereof is omitted here.

  When detecting the expiration of the sleep period Ts3, the handset interrupt detection unit 105 of the handset 10 turns on the main power (P31). Then, the slave unit 10 performs a reset process, searches for a beacon signal to detect the master unit 20, and establishes synchronization of wireless communication with the master unit 20 (S31).

  Next, handset 10 transmits a notification of the occurrence of the sleep period event occurrence to base unit 20 (S32).

  When the notification of the occurrence of the sleep period expiration in S32 is received, the base unit 20 transmits the transition request information to the normal power consumption mode to the base unit 10 by the next beacon signal (S33).

  The slave 10, upon receiving the transition request information to shift to the normal power consumption mode at S33, transmits completion response information to the parent device 20 (S34), and shifts to the normal power consumption mode. Thereafter, the slave unit 10 repeats ON / OFF of the main power supply at the startup interval Ts1.

  In the case of (M2-4) above, that is, when the call button 109 of the handset 10 is pressed during the sleep period, the handset 10 turns on the main power and starts up (P31). Then, the slave unit 10 establishes synchronization of wireless communication with the master unit 20 (S31), and transmits an event occurrence notification of pressing of the call button 109 to the master unit 20 (S32). When receiving the event occurrence notification that the call button 109 has been pressed, the base unit 20 executes call response processing with the slave unit 10.

  As shown in FIG. 6 and FIG. 7, the period (for example, one second or more) of the operating state of slave unit 10 when activated from the ultra low power consumption mode is the normal power consumption mode or the low power consumption mode. It is longer than the operation period (for example, 50 ms). This is because, as described above, in the case of the ultra-low power consumption mode, it takes some time (for example, about one second) to synchronize wireless communication at startup. Since the power consumption increases as the operating period increases, it is preferable that the sleep period of the ultra low power mode is sufficiently longer than the start interval of the low power mode.

  In addition, in order to notify the parent device 20 of survival, the child device 10 is put into operation periodically (for example, every two hours) and performs wireless communication (hereinafter referred to as "dead / live confirmation communication") with the parent device 20. It is also good. In this case, at the timing of the life-and-death confirmation communication, the slave 10 may combine the event occurrence notification related to the slave 10 and transmit it to the master 20. Further, the slave unit 10 may combine the information such as the battery remaining amount and / or the RSSI at the timing of the life-and-death confirmation communication, and transmit the information to the master unit 20.

<Master device setting screen>
8 to 11 are diagrams showing examples of setting screens in the parent device 20. FIG. In the following description, the setting screen of the master 20 shown on the screen 206A of FIG. 8, the screen 206D of FIG. 9, the screen 206G of FIG. 10, and the screen 206J of FIG. Is displayed on the display 21 of the parent device 20 by pressing the menu button of the above.

  Next, an example of a method of setting the low power consumption mode and the ultra low power consumption mode from the parent device 20 will be described with reference to FIG.

  When the resident selects "Various settings" from the list displayed on screen 206A of base unit 20 and then selects "Manual setting for power consumption mode" from the list displayed on screen 206B, base unit 20 Next, as shown in the screen 206C, a selection list of the normal power consumption mode, the low power consumption mode, and the ultra low power consumption mode is displayed.

  When the resident selects the "normal power consumption mode" from the list on the screen 206C, the slave 10 operates in the normal power consumption mode, and when the "low power consumption mode" is selected, the slave 10 operates in the low power consumption mode Works with

  In addition, when the resident selects the "ultra-low power consumption mode" from the list on the screen 206C, the slave 10 operates in the ultra-low power consumption mode for a certain period. A default value (for example, 8 hours) may be set in advance for this fixed period, and the resident may be arbitrarily changed.

  Next, another example of the method of setting the low power consumption mode and the ultra low power consumption mode from the parent device 20 will be described with reference to FIG.

  When the resident selects "various settings" from the list displayed on screen 206D of base unit 20 and then selects "Eco function" and "ON" from the list displayed on screen 206E, base unit 20 Next, as shown on the screen 206 F, the low power consumption mode and the ultra-low power consumption mode selection list are displayed.

  Next, referring to FIG. 10, an example of a method of setting the start time and the end time of the low power consumption mode (or the ultra low power consumption mode) from the parent device 20 will be described.

  When the resident selects "various settings" from the list displayed on screen 206G of base unit 20 and then selects "Eco function" and "ON" from the list displayed on screen 206H, base unit 20 Next, as shown in the screen 206I, the setting values of the start time and the end time of the low power consumption mode (or the ultra low power consumption mode) are displayed.

  When the resident sets the start time and the end time on the screen 206I, the child device 10 operates in the low power consumption mode (or the ultra low power consumption mode) from the set start time to the end time.

  Note that, in the above-described configuration in which the child device 10 transmits an event occurrence notification at the timing of the alive confirmation notification, the start time and the end time that can be set on the screen 206I may be limited to the timing of the alive confirmation notification. . For example, when the cycle of the life and death confirmation notification is "every 2 hours", the settable start time and end time are limited to every 2 hours, such as 0 o'clock, 2 o'clock, 4 o'clock, and so on.

  Next, another example of the method of setting the low power consumption mode and the ultra low power consumption mode from the parent device 20 will be described with reference to FIG.

  When the resident selects "Various settings" from the list displayed on the screen 206J of the parent device 20 and then selects "Eco function automatic setting" from the list displayed on the screen 206K, the parent device 20 Next, as shown on the screen 206 L, a list of ON / OFF of the eco functions 1, 2 and 3 is displayed. Here, for example, the eco function 1 corresponds to transition conditions (corresponding to the above (M1-1), (M2-1) and (M3-1) related to the reduction of the battery capacity, and the eco function 2 is a residence Corresponding to the transition conditions (corresponding to (M1-2), (M2-2) and (M3-2) above) related to the operation of the person, the eco function 3 is the transition condition (above (M1-3) , (M2-3) and (M3-3)).

  When the resident sets at least one eco function to ON from the list on screen 206L, next, as shown on screen 206M, base unit 20 selects the low power consumption mode and the ultra low power consumption mode selection list Display Then, the resident selects one of the power consumption modes from the selection list on the screen 206M. When the eco function 3 is set to ON, the master device 20 may display the screen 206I of FIG.

  As a result, when the transition condition related to the eco function selected on the screen 206L is met, the child device 10 shifts to the power consumption mode selected on the screen 206M.

<Effect of the embodiment>
In the present embodiment, the slave unit 10 of the television door phone device 1 has a first communication scheme and a second communication scheme. In the first communication method, slave unit 10 repeats ON / OFF of the main power supply at a constant start-up interval. Here, the power consumption of the slave 10 can be suppressed by lengthening the start interval. For example, when the activation interval is increased according to the remaining battery level of the slave 10, the replacement time of the battery 122 can be extended.

  In the second communication method, the slave 10 turns off the main power for the set sleep period, and turns on the main power after the expiration of the sleep period or when the call button 109 is pressed. For example, when a period in which the photographed image of the handset camera 11 is not confirmed from the base unit 20 continues for a long time, such as when going out and going to bed, the first communication can be performed by operating the handset 10 by the second communication method. The power consumption of the handset 10 can be suppressed more than the method. Further, by setting the sleep period, even if the resident does not press the call button 109 of the handset 10, for example, the handset 10 can be automatically shifted to the first communication method.

<Hardware configuration>
Although the embodiments according to the present invention have been described in detail with reference to the drawings, the functions of the device 10 and the device 20 described above can be realized by a computer program.

  FIG. 12 is a diagram illustrating a hardware configuration of a computer that realizes the functions of the respective devices by a program. The computer 2100 includes an input device 2101 such as a button or a touch panel, an output device 2102 such as a display or a speaker, a central processing unit (CPU) 2103, a read only memory (ROM) 2104, a random access memory (RAM) 2105, a flash memory, etc. And a reader 2107 for reading information from a storage medium such as a USB (Universal Serial Bus) memory, and a transmitter / receiver 2108 for communicating via a network, and each unit is connected by a bus 2109.

  Then, the reading device 2107 reads the program from the recording medium storing the program for realizing the function of each of the above-described devices, and causes the storage device 2106 to store the program. Alternatively, the transmission / reception device 2108 communicates with a server device connected to the network, and stores in the storage device 2106 a program for realizing the functions of the respective devices downloaded from the server device.

  Then, the CPU 2103 copies the program stored in the storage device 2106 to the RAM 2105, sequentially reads out the instruction included in the program from the RAM 2105, and executes the function, whereby the functions of the respective devices are realized.

  The embodiments described above are exemplifications for describing the present invention, and are not intended to limit the scope of the present invention only to the embodiments. Those skilled in the art can practice the present invention in various other aspects without departing from the scope of the present invention.

  The present invention is useful for suppressing power consumption of a television door phone device.

DESCRIPTION OF SYMBOLS 1 TV door phone apparatus 10 entry slave unit 11 slave unit camera 12 slave unit speaker 13 slave unit microphone 20 indoor master unit 21 display 22 master unit speaker 23 master unit microphone 100 slave unit main unit 104 slave unit power supply unit 105 slave unit interrupt detection Part 108 Slave unit control unit 109 Call button 130 Timer 200 Main unit main unit 205 Parent unit power supply unit 206 Parent unit interrupt detection unit 210 Parent unit control unit 211 Operation unit 230 Timer

Claims (5)

A door phone device that performs wireless communication between a master unit and a slave unit,
The slave unit is
The operation to be activated from the sleep state and temporarily put into the operating state is repeated at the activation interval set in the master unit,
The parent machine is
When the slave unit is in the operating state, either the first startup interval or the second startup interval longer than the first startup interval may be set according to a predetermined condition. Send transition request information to be transferred to the child device to set the activation interval of the child device,
The predetermined condition is the remaining battery capacity of the child device,
The parent machine is
Transition request information for shifting to the second activation interval is transmitted to the child device when the battery residual amount of the child device is less than a threshold, and the battery residual amount of the child device is equal to or greater than the threshold. Transmitting transition request information for transitioning to a first activation interval to the child device ,
De Ahon apparatus. The slave unit is
Transmitting information indicating the remaining battery capacity to the base unit;
The parent machine is
After the information indicating the remaining battery level is received, the threshold determination is performed.
A door phone apparatus according to claim 1 . A door phone device that performs wireless communication between a master unit and a slave unit,
The slave unit is
The operation to be activated from the sleep state and temporarily put into the operating state is repeated at the activation interval set in the master unit,
The parent machine is
When the slave unit is in the operating state, either the first startup interval or the second startup interval longer than the first startup interval may be set according to a predetermined condition. Send transition request information to be transferred to the child device to set the activation interval of the child device,
The predetermined condition is an operation of changing to the low power consumption mode for the parent device or the child device,
The parent machine is
Transmission request information for transitioning to the second activation interval when the change operation to the low power consumption mode is performed is transmitted to the child device, and constant after the change operation to the low power consumption mode is performed. Transmitting transition request information for transitioning to the first activation interval after the period has elapsed, to the child device;
De Ahon apparatus. A door phone device that performs wireless communication between a master unit and a slave unit,
The slave unit is
The operation to be activated from the sleep state and temporarily put into the operating state is repeated at the activation interval set in the master unit,
The parent machine is
When the slave unit is in the operating state, either the first startup interval or the second startup interval longer than the first startup interval may be set according to a predetermined condition. Send transition request information to be transferred to the child device to set the activation interval of the child device,
The predetermined condition is setting of start time and end time,
The parent machine is
Transition request information for transitioning to the second activation interval at the start time is transmitted to the slave unit, and transition request information for transitioning to the first activation interval at end time is transmitted to the slave unit.
De Ahon apparatus. A door phone device that performs wireless communication between a master unit and a slave unit,
The slave unit is
The operation to be activated from the sleep state and temporarily put into the operating state is repeated at the activation interval set in the master unit,
The parent machine is
When the slave unit is in the operating state, either the first startup interval or the second startup interval longer than the first startup interval may be set according to a predetermined condition. Send transition request information to be transferred to the child device to set the activation interval of the child device,
The predetermined condition is a non-operation period of the master unit,
The parent machine is
Transition request information for shifting to the second activation interval is transmitted to the child device when the non-operation period is equal to or greater than the threshold, and the first activation interval is transmitted when the non-operation period is less than the threshold Sending transition request information to be transferred to the child device,
De Ahon apparatus.

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