JP6624374B2 - Sensor light - Google Patents

Description

  The present invention relates to a sensor light that lights when a movement of a moving body is detected.

  2. Description of the Related Art Conventionally, as a product for security use, for example, a sensor light that turns on when a movement of a moving object (for example, a person) entering a monitoring area at night or the like is detected has been known.

  Further, as a prior art related to a lighting device which detects a movement of a moving body and turns on, for example, a lighting control device of Patent Document 1 is known. The lighting control device of Patent Literature 1 selects the lighting holding time of the lighting load according to the number of times the human body is detected within a predetermined time. This lighting control device illuminates a specific place (for example, a toilet) where people frequently go in and out, and can vary the lighting time to prevent useless lighting.

JP 2001-223092 A

  The lighting control device disclosed in Patent Literature 1 turns off the light after turning on when no human motion is detected during the lighting holding time. For this reason, in the configuration of Patent Literature 1, if the lighting holding time is short, the lighting is immediately turned off when no one is present immediately after lighting, so that the convenience of lighting is reduced, which is inconvenient.

  On the other hand, if the lighting holding time is set to be long, the lighting is turned off when no human motion is detected during the lighting holding time. The power consumption of the device increases. For example, when the battery is operated by a battery due to the influence of an installation place or the like, an increase in power consumption causes a problem in use.

  The present invention has been devised in view of the above-described conventional situation, and has been set to turn on the light for a certain period of time and to turn off the light as soon as possible while suppressing an increase in power consumption. It is an object of the present invention to provide a sensor light for preventing the light from being turned off immediately after a lapse of time, even if the movement of the moving object is no longer detected.

The present invention includes a light that lights at least for a preset time, a sensor that detects the movement of a moving object, and a processor that turns on the light when the movement of the moving object is detected, wherein the processor Starts measuring the lighting time of the light in response to the lighting of the light, and thereafter, when the movement of the moving body is no longer detected, until the light is turned off after the moving body is no longer detected. the start the measurement of the switch-off delay time indicating the duration of the non-detection state of the moving body, wherein the switch-off delay time measurement value is correlated et the unlit delay time setting value of the lighting time of the light Provided is a sensor light that turns off the light when a measured value of a lighting time of the light exceeds a preset value and a measured value of a lighting time of the light exceeds the preset time.

  According to the present invention, turning on the light for a certain period of time and turning off the light as soon as possible while suppressing an increase in power consumption are compatible. Even if the detection is stopped, it is possible to prevent the light from being turned off immediately.

FIG. 1 is a diagram illustrating an example of a system configuration of a surveillance camera system incorporating a sensor light according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a parent device in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a slave unit in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a camera in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a sensor in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a smartphone in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of a smart plug in the surveillance camera system according to the present embodiment. FIG. 2 is a block diagram illustrating an example of an internal configuration of the sensor light according to the embodiment. The perspective view which shows an example of the external appearance of the sensor light of this embodiment. FIG. 4 is a diagram illustrating an example of registered contents of a setting information table in a sensor light according to the present embodiment. FIG. 7 is a diagram illustrating an example of registered contents of a light-off delay time table in a sensor light according to the present embodiment. 4 is a flowchart for explaining an example of an operation procedure of the sensor light according to the embodiment while the light is turned off. 4 is a flowchart illustrating an example of an operation procedure during lighting of the sensor light according to the embodiment.

  Hereinafter, an embodiment (hereinafter, referred to as the present embodiment) that specifically discloses a sensor light according to the present invention will be described in detail with reference to the drawings as appropriate. However, an unnecessary detailed description may be omitted. For example, a detailed description of well-known matters and a repeated description of substantially the same configuration may be omitted. This is to prevent the following description from being unnecessarily redundant and to facilitate understanding of those skilled in the art. The accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the claimed subject matter.

  Hereinafter, the sensor light of the present embodiment will be described as being applied to a surveillance camera system installed in, for example, a premises of a user's home (including, for example, indoors and outdoors in yards and the like). However, it is needless to say that the sensor light of the present embodiment is not limited to the security use in the premises of the user's home, and may be used as a security use in any one of business establishments such as stores, factories, offices, and the like. . Further, the sensor light of the present embodiment may not be used for crime prevention purposes, but may be used for improving usability for people who go to and from the installation location.

  Note that the present invention is not limited to the device category of the sensor light, a lighting control method that defines a lighting operation of the light in the sensor light, a lighting control method that defines a lighting operation of the light in the sensor light, or a lighting control method that defines the lighting operation of the sensor light. The control including turning on and off can be expressed as a specified light control method.

  FIG. 1 is a diagram illustrating an example of a system configuration of a monitoring camera system 5 in which a sensor light 90 according to the present embodiment is incorporated. The surveillance camera system 5 is installed, for example, in the house 8 and includes a base unit 10 of a fixed telephone, two sub units 20A and 20B, two cameras 30 (for example, an indoor camera 30A and a surveillance camera 30B), and various sensors. 40 (for example, human sensors 40A and 40B, smoke sensor 40C, open / close sensor 40D), smart plug 80, sensor light 90, smartphone 50, and wireless router 60. The configuration of the monitoring camera system 5 is an example, and can be changed to various modes.

  Master device 10 has a role as a gateway for communication with various devices in surveillance camera system 5. In other words, the base unit 10 is a control device that controls the overall operation of the monitoring camera system 5, and is communicably connected to a slave unit, a camera, a sensor, and the like using a DECT (Digital Enhanced Cordless Telecommunications) communication method, for example. Is done. Master device 10 is connected to the Internet 65 (network) via wireless router 60 using a wireless LAN. Master device 10 is connected to fixed telephone network 85 by wire, and performs an intermediary process for enabling a telephone call between slave devices 20A and 20B and another fixed telephone 800. Master device 10 may directly communicate with another fixed telephone 800. Master device 10 has a function of charging slave device 20A inserted into insertion port 10a.

  The slave units 20A and 20B are connected to the master unit 10 by the DECT communication method, and can communicate with the master unit 10. In particular, when there is no need to distinguish between the two slaves 20A and 20B, they are collectively referred to as slaves 20.

  The various sensors 40 (for example, the human sensors 40A and 40B, the smoke sensor 40C, and the open / close sensor 40D) are connected to the master unit 10 by a DECT communication method. Here, as the sensors, an opening / closing sensor 40D that detects opening and closing of a window, a smoke sensor 40C that senses smoke, and human sensors 40A and 40B that sense a person by infrared rays are used. In particular, when it is not necessary to distinguish these types of sensors, they are collectively referred to as sensors 40. Further, as described later, an infrared sensor 313 (see FIG. 4) built in the camera 30 is also used as a human sensor.

  The two cameras (for example, the indoor camera 30A and the surveillance camera 30B) have a call function, are connected to the master device 10 by the DECT communication method, and can talk with the slave devices 20A and 20B. Here, a surveillance camera 30B that captures images of the outdoors and an indoor camera 30A that captures images of the house 8 are used as cameras. In particular, when it is not necessary to distinguish the types of cameras, they are collectively referred to as cameras 30.

  The smart plug 80 has a wireless communication function using DECT, and is connected to the master device 10 using a DECT wireless communication method. The smart plug 80 is a commercial AC power supply that supplies power to various electric devices (for example, an air conditioner, a lighting device, the camera 30, and the sensor 40) connected to the smart plug 80 according to an instruction transmitted from the master device 10. Alternatively, the energization or the interruption of the DC power supply is switched. Details of the smart plug 80 will be described later.

  The sensor light 90 detects the movement of a person in a monitoring area (for example, a yard in a house, an entrance), and lights up when the surroundings are dark at night or the like to illuminate the surroundings of the monitoring area. The brightness of the sensor light 90 may be high enough to illuminate the monitoring area brightly or low enough to be used as a warning light. The sensor light 90 has a wireless communication function using DECT, and is connected to the master device 10 using a DECT wireless communication method. The sensor light 90 can arbitrarily set operating conditions (hereinafter, may be referred to as “scenario”) of the sensor light 90 from the smartphone 50 via the master device 10. The details of the sensor light 90 will be described later.

  The smartphone 50 is connected to the base unit 10 via a wireless router 60 using a wireless LAN, and via a mobile phone network 75 using various communication methods such as 3G (3rd generation) and 4G (4th generation). Connected to another mobile phone 70 or another smartphone (not shown).

  FIG. 2 is a block diagram illustrating an example of an internal configuration of the master device 10 in the monitoring camera system 5 of the present embodiment. Master device 10 is configured to include control unit 109, storage unit 103, operation unit 105, and display unit 106. Master device 10 accepts various input operations and displays information such as images on display unit 106. The control unit 109 includes a call control unit 110 and an audio stream processing unit 112, and performs call control of a call, processing of audio data, and the like.

  Master device 10 also has an image memory control unit 115 and an image memory 116, and receives image data and the like captured by camera 30 and transferred from camera 30 and stores the data in image memory 116.

  Master device 10 has a wireless LAN control unit 121 and a wireless LAN communication I / F unit 122, and communicates with smartphone 50, camera 30, and the like via wireless router 60 connected by wireless LAN. Send and receive data.

  Master device 10 also has a DECT protocol control unit 108 and a DECT wireless I / F unit 107, and uses a wireless communication system of DECT (Digital Enhanced Cordless Telecommunications) to execute slave device 20, sensor 40, and camera 30. , The smart plug 80 and the sensor light 90 perform wireless connection and wireless communication, respectively.

  Master device 10 also has audio bus 117, audio input / output control unit 104, speaker 129, and microphone 128, and inputs and outputs audio to and from the outside.

  Base unit 10 has fixed telephone line I / F unit 101 and can talk with external fixed telephone 800 connected to fixed telephone network 85. As described above, base unit 10 performs various processing of voice data during a call so that a call can be made between external fixed telephone 800 connected to fixed telephone network 85 and slave units 20A and 20B. May be controlled.

  Master device 10 also has a child device / mobile terminal charging unit 126, and charges child device 20 or smartphone 50 inserted into insertion port 10a.

  Master device 10 also has a USB communication I / F section 127, and transmits and receives data to and from devices and memories having a USB (Universal Serial Bus) standard interface.

  Master device 10 also associates various sensors 40 (for example, human sensors 40A, 40B, smoke sensor 40C, open / close sensor 40D) with a plurality of cameras 30 and writes and registers them in storage unit 103. For example, the human sensor 40B and the surveillance camera 30B are registered in association with each other because they are installed in a close place outdoors. Further, as will be described later, since the monitoring camera 30B integrally incorporates an infrared sensor 313 (see FIG. 4) as a human sensor, it is registered in association with the infrared sensor 313. Since the human sensor 40A, the smoke sensor 40C, and the open / close sensor 40D are all installed in the house 8, they are registered in association with the indoor camera 30A.

  FIG. 3 is a block diagram illustrating an example of an internal configuration of the slave 20 in the monitoring camera system 5 of the present embodiment. Slave device 20 is configured to include control unit 247, storage unit 242, operation unit 244, and display unit 245. The child device 20 receives various input operations and displays information such as an image on the display unit 245.

  Further, the slave unit 20 has a DECT protocol control unit 249 and a DECT wireless I / F unit 248, and each of the slave units 20 communicates with the master unit 10, the sensor 40, and the camera 30 using the DECT wireless communication method. Perform connection and wireless communication.

  Further, the slave unit 20 has an audio bus 255, an audio input / output control unit 243, a speaker 252, and a microphone 251, and performs input / output of audio with respect to the outside (for example, the external fixed telephone 800). Make a call.

  FIG. 4 is a block diagram illustrating an example of an internal configuration of the camera 30 in the monitoring camera system 5 of the present embodiment. The indoor camera 30A and the surveillance camera 30B as examples of the camera 30 have almost the same specifications. The camera 30 is configured to include a control unit 309, a storage unit 303, and an operation unit 305. The camera 30 performs an operation related to imaging and receives an input operation.

  The camera 30 has a DECT protocol control unit 317 and a DECT wireless I / F unit 318, and performs wireless connection and wireless communication with the base unit 10 using the DECT wireless communication method.

  The camera 30 has a wireless LAN control unit 321 and a wireless LAN communication I / F unit 322, and communicates with the master device 10, the smartphone 50, and the like via a wireless router 60 connected by a wireless LAN. Send and receive data.

  The camera 30 includes an audio bus 307, an audio input / output control unit 304, a speaker 329, and a microphone 328, and performs audio input / output with respect to an external device (for example, the slaves 20A and 20B) to perform a call. I do.

  Further, the camera 30 includes an imaging unit 312, an image memory control unit 316, and an image memory 315, and stores image data captured by the imaging unit 312 in the image memory 315. The imaging unit 312 includes a lens and an imaging element (for example, an image sensor such as a CCD (Charged Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor)).

  The camera 30 has a built-in infrared sensor (current collecting sensor) 313 as a PIR (Passive Infra Red) sensor as a human sensor. The infrared sensor 313 detects a change in heat (infrared) emitted by a person (person) and senses the presence of the person. The camera 30 has a power supply unit 314 configured by, for example, a commercial AC power supply or a DC power supply.

  FIG. 5 is a block diagram illustrating an example of an internal configuration of the sensor 40 in the monitoring camera system 5 of the present embodiment. The sensor 40 includes a control unit 447, a storage unit 442, and a display lamp 445. The sensor 40 performs a predetermined detection operation such as turning on a display lamp 445 when detecting a target (for example, an intruder; the same applies hereinafter).

  In addition, the sensor 40 has a DECT protocol control unit 449 and a DECT wireless I / F unit 448, and performs wireless connection and wireless communication with the base unit 10 using the DECT wireless communication method, and detects an object. The sensor detection information is sent to master device 10.

  The sensor unit 453 differs depending on the type of the sensor 40. For example, in the case of the human sensors 40A and 40B, the sensor unit 453 is a PIR sensor that detects a person by a change in infrared rays. In the case of the open / close sensor 40D that detects opening / closing of a window or the like, the sensor unit 453 is a reed switch that is turned on / off by opening / closing. In the case of the smoke sensor 40C, the sensor unit 453 is a light-emitting / light-receiving unit that senses smoke by blocking emitted light by smoke.

  The rechargeable battery 450 is a rechargeable battery and supplies necessary power to each part of the sensor 40.

  FIG. 6 is a block diagram illustrating an example of an internal configuration of the smartphone 50 in the monitoring camera system 5 of the present embodiment. The smartphone 50 includes a control unit 506, a storage unit 504, and a display / operation unit (touch panel) 503. The smartphone 50 receives various input operations and displays information such as images on the touch panel 503. The control unit 506 has a built-in monitoring function control unit 514 that can set the function of the camera 30, the setting information of the sensor light 90 (for example, see FIG. 10) and the scenario, as described later. The touch panel 503 is a display input unit in which a display unit and an operation unit are integrated, and displays information such as images and icons on a screen, a setting information generation screen (not shown) of the sensor light 90, and setting of a scenario. A screen (not shown) is displayed, and a tap operation (or a touch operation) on the screen by the user is received.

  The smartphone 50 has a 3G / 4G protocol control unit 502 and a 3G / 4G wireless I / F unit 501, and uses a 3G (3rd generation) or 4G (4th generation) wireless communication method. It performs wireless connection and wireless communication with the mobile phone 70 and other smart phones connected to the mobile phone network 75.

  In addition, the smartphone 50 includes an audio bus 515, an audio input / output control unit 505, a speaker 513, and a microphone 512, and performs input and output of audio to the outside.

  Also, the smartphone 50 has a wireless LAN control unit 507 and a wireless LAN communication I / F unit 508, and communicates with the master device 10, the camera 30, and the like via the wireless router 60 connected by the wireless LAN. Send and receive data. In addition, when there is an input operation by the user who operates the smartphone 50, the smartphone 50 receives a signal from the operation and performs various settings such as the sensor light 90 and the smart plug 80 via the wireless router 60 and the base unit 10. It is possible to newly create information or to arbitrarily change the setting information.

  The smartphone 50 has a USB communication I / F unit 511, and transmits and receives data to and from a device or a memory having a USB (Universal Serial Bus) standard interface.

  FIG. 7 is a block diagram illustrating an example of an internal configuration of the smart plug 80 in the monitoring camera system 5 of the present embodiment. The smart plug 80 includes a control unit 847, a storage unit 842, and a display unit 845 including a display lamp. In the storage unit 842, schedule setting information relating to ON / OFF conditions that can be set or changed by the smart plug 80 performing wireless communication using DECT with the master device 10 is registered.

  Also, the smart plug 80 has a DECT protocol control unit 849 and a DECT wireless I / F unit 848, and performs connection by wireless communication with the base unit 10 using the DECT wireless communication method, and establishes connection by this wireless communication. In accordance with a signal transmitted via the main unit 10 (that is, a switching control signal from the base unit 10), a commercial AC is supplied to each electric device (for example, an air conditioner, a lighting device, a camera 30, a sensor 40) connected to each smart plug 80. Switching between supply and cutoff of power supply or DC power supply.

  The smart plug 80 has a switch unit 850. The switch unit 850 is connected to an outlet terminal (not shown) exposed at various positions (for example, positions of a dining room, a living room, a bedroom, etc.) of the house 8 connected from a switchboard (not shown) of the house 8. A power supply line as a power supply is connected or disconnected between a plug terminal 851 to be connected and an outlet terminal 852 to be connected to an electric device. The switch unit 850 is driven by, for example, a solenoid coil 853, and closes the switch unit 850 by flowing a drive current from an AC power supply to the solenoid coil 853, thereby establishing electrical connection between the plug terminal 851 and the outlet terminal 852. Further, the switch unit 854 turns on / off a drive current flowing through the solenoid coil 853 under the control of the control unit 847.

  A current detection element 855 is provided between the plug terminal 851 and the switch unit 850. When a current flows between the plug terminal 851 and the outlet terminal 852, the current detection element 855 detects the current and sends a detection signal to the control unit 847. send. For example, when an input operation is performed from the operation unit 841, the control unit 847 displays the amount of supplying power to the electric device (power supply amount) when receiving a detection signal from the current detection element 855. To be displayed.

  For example, when an instruction signal of the operation mode of the smart plug 80 is received by the DECT wireless I / F unit 848 from the master device 10 according to an instruction from the smartphone 50 based on a user operation, the control unit 847 establishes a connection with the plug terminal 851. A switching control signal for establishing electrical connection with the outlet terminal 852 is output to the switch unit 854. Thus, electrical continuity is established between the plug terminal 851 and the outlet terminal 852. On the other hand, when the DECT wireless I / F unit 848 receives an instruction signal of the operation stop mode of the smart plug 80 from the master device 10 in response to an instruction from the smartphone 50 based on a user operation, for example, the control unit 847 A switching control signal for disconnecting the terminal 851 from the outlet terminal 852 is output to the switch unit 854. As a result, the electrical connection between the plug terminal 851 and the outlet terminal 852 becomes non-conductive.

  In addition, the control unit 847 refers to the schedule setting information stored in the storage unit 842 and, when the operation mode time included in the schedule setting information is reached, establishes conduction between the plug terminal 851 and the outlet terminal 852. The switching control signal is output to the switch unit 854. Thus, electrical continuity is established between the plug terminal 851 and the outlet terminal 852. Note that, during the operation mode, the plug terminal 851 is not connected unless the DECT wireless I / F unit 848 receives an operation stop mode instruction signal transmitted from the master device 10 according to an instruction from the smartphone 50 based on a user operation, for example. The electrical connection between the power supply terminal and the outlet terminal 852 is maintained.

  On the other hand, the control unit 847 refers to the schedule setting information stored in the storage unit 842 and, when the operation stop mode time included in the schedule setting information comes, disconnects the connection between the plug terminal 851 and the outlet terminal 852. Is output to the switch unit 854. As a result, the electrical connection between the plug terminal 851 and the outlet terminal 852 becomes non-conductive. During the time of the operation stop mode, the plug terminal 851 is connected to the DECT wireless I / F unit 848 unless the operation mode instruction signal transmitted from the base unit 10 in response to an instruction from the smartphone 50 based on a user operation is received. The non-conductive state between the power supply terminal and the outlet terminal 852 is maintained.

  FIG. 8 is a block diagram illustrating an example of an internal configuration of the sensor light 90 of the present embodiment. The sensor light 90 has a configuration including a processor 901, a DECT wireless I / F unit 902, a DECT protocol processing unit 903, a memory 904, an illuminance sensor 905, an operation sensor 906, a light 907, and a battery 908. Have.

  The processor 901 uses the DECT wireless I / F unit 902 and the DECT protocol processing unit 903 to perform wireless connection and wireless communication with the parent device 10 using the DECT wireless communication method. The sensor light 90 can be connected to various devices such as the sensor 40, the smartphone 50, and the smart plug 80 by performing wireless communication with the master device 10.

  Further, the processor 901 incorporates a lighting time measurement timer 901z and a light emission delay time measurement timer 901y. The lighting time measurement timer 901z measures the lighting time Ta of the light 907. The light-off delay time measurement timer 901y measures the light-off delay time Td. The turn-off delay time Td indicates the duration of the non-detection state of the moving object (from the detection of the movement of the moving object (for example, a person) by the motion sensor 906 to the turning off of the light 907). The processor 901 compares the measured value of the light-off delay time Td measured by the light-off delay time measurement timer 901y with the set value Tdm of the light-off delay time stored in the memory 904, as described later. Lighting / turning off of the light 907 is controlled accordingly.

  In the present embodiment, the set value Tdm of the light-off delay time can be set by, for example, two methods. In the first setting method, the processor 901 stores the turn-off delay time table 170 (see FIG. 11) in the memory 904 in advance, and refers to the turn-off delay time table 170 to set the lighting time setting value Tam of the light 907. And reads out and acquires the set value Tdm of the turn-off delay time corresponding to.

  Further, in the second setting method, the processor 901 measures the lighting time Ta of the light 907 and calculates a predetermined ratio of the measured lighting time Ta (for example, 10% of the measured value of the lighting time Ta). The calculated value is set as a set value Tdm of the light-off delay time. Note that the predetermined ratio is not limited to 10% and can be set to an arbitrary value such as 5% or 20%.

  Further, the set value Tdm of the light-off delay time may be set in the sensor light 90 via the master device 10 by a setting input of the user who operates the smartphone 50. For example, when the information of the set value Tdm of the turn-off delay time input by the setting operation of the user who operates the smartphone 50 is transmitted from the smartphone 50 to the base unit 10, the information of the set value Tdm of the turn-off delay time is transmitted to the base unit. Received at 10. Thereafter, base unit 10 transmits information on set value Tdm of the light-off delay time to sensor light 90. When the sensor light 90 receives the information of the set value Tdm of the light-off delay time, the setting can be completed by writing the information to the memory 904.

  Further, for example, when the set value Tam of the lighting time of the light 907 is 20 seconds, but when the lighting time Ta that has been turned on has passed 70 seconds, the movement of the person is finally not detected, and after that, during the light-off delay time, It is assumed that the non-detection state continues. In this case, in the first setting method, referring to the turn-off delay time table 170, the set value Tdm of the turn-off delay time is 5 seconds. On the other hand, in the second setting method, the set value Tdm of the turn-off delay time is 7 seconds as 10% of the measured value of the turn-on time Ta. Therefore, the light 907 is turned on for a total of 75 seconds in the first setting method, while the light 907 is turned on for a total of 77 seconds in the second setting method. That is, when the set value Tdm of the light-off delay time is set by the first setting method, the time for which the light 907 is turned on is reduced by 2 seconds as compared with the case where the setting value Tdm is set by the second setting method. The light 90 is more preferable in that power consumption is reduced. On the other hand, when the light 907 is set by the second setting method, the light 907 is turned on for two seconds longer than in the case of the setting by the first setting method. Then it can be said that it is more preferable.

  Further, for example, when the set value Tam of the lighting time of the light 907 is 20 seconds, but when the lighting time Ta that has been turned on has passed 20 seconds, the movement of a person is finally not detected, and during the light-off delay time, It is assumed that the non-detection state continues. In this case, in the first setting method, referring to the turn-off delay time table 170, the set value Tdm of the turn-off delay time is 5 seconds. On the other hand, in the second setting method, the set value Tdm of the light-off delay time is 2 seconds as 10% of the measured value of the light-on time Ta. Therefore, the light 907 is turned on for a total of 25 seconds in the first setting method, while the light 907 is turned on for a total of 22 seconds in the second setting method. That is, which of the first setting method and the second setting method should set the set value Tam of the turn-off delay time depends on the length of the turn-on time Ta of the light 907 up to the point where the movement of the person is no longer detected. Depends on. The setting value Tam of the light-off delay time is set by one of the first setting method and the second setting method.

  As a method of setting the set value Tdm of the light-off delay time, the first setting method / second setting method is based on an operation switch (not shown) built in the sensor light 90 or the smartphone 50 via the master device 10. Is selectable.

  The light 907 includes, for example, a white LED that is a light source and a reflector that reflects light projected from the white LED forward. The light source is not limited to a white LED, but may be a color LED other than white, an incandescent lamp, a fluorescent lamp, a halogen lamp, a xenon lamp, or the like. In the present embodiment, for example, a white LED with low power consumption and close to natural light is used.

  The memory 904 stores a control program executed by the processor 901 and various data. The various data include a setting information table 160, a turn-off delay time table 170, and the like, which will be described later.

  The illuminance sensor 905 as an example of the sensor senses ambient brightness, and senses light in a wavelength region close to the wavelength of light sensed by the human eye, that is, a spectral sensitivity characteristic close to the human eye. Photodiode. Note that an image sensor may be used as the illuminance sensor. In this case, the illuminance can be obtained from the luminance value of each pixel of the image sensor, and an image can be obtained from the luminance values of all pixels.

  The operation sensor 906 as an example of the sensor has an LED and a photodiode, emits near-infrared light from the LED toward the monitoring area, receives the reflected light with the photodiode, and, based on a change in the reflected light, Detects the movement of a person. Here, the movement of a person is detected as an example of a moving object, but the movement of not only a person but also an animal such as a dog or a cat or a structure of a small or large vehicle or a robot is detected. You may. Although the near-infrared light is irradiated here, visible light, ultraviolet light, or the like may be irradiated, and the movement of the moving body may be detected from a change in the reflected light. Instead of irradiating light, ultrasonic waves may be irradiated and the movement of the moving object may be detected from the reflected waves. In addition, the motion sensor detects the movement of the moving body, but in the case of a moving body that is expected to move extremely small, even if the movement body can detect the presence of the moving body without moving. For example, an infrared sensor (a pyroelectric sensor) that is a PIR (Passive Infra Red) sensor may be used as a motion sensor that detects infrared light emitted by a human body as a motion sensor. When a current collecting sensor is used, light is not emitted like an LED, so that power saving is achieved.

  The battery 908 is, for example, four AA batteries used as a power source of the sensor light 90. As the battery, not only a primary battery such as a manganese dry battery or an alkaline dry battery but also a rechargeable secondary battery such as a nickel hydride battery, a lithium ion battery, or a lead battery may be used. In the present embodiment, a battery is used as a power supply for the sensor light 90. However, instead of a battery, a power supply device that is connected to a commercial AC power supply and converts a commercial AC to output a predetermined voltage is built in. Is also good.

  FIG. 9 is a perspective view illustrating an example of the appearance of the sensor light 90 of the present embodiment. The sensor light 90 has a light main body 91, a connecting portion 92, and a pedestal 93. The light main body 91 has a built-in substrate on which electronic components of the respective components shown in FIG. 8 are mounted. On the front surface of the light main body 91, a light 907 that can be irradiated toward the monitoring area is arranged. An illuminance sensor 905 and an operation sensor 906 are arranged on the front surface of the light main body 91.

  The pedestal 93 is a rectangular plate that supports the light main body 91 via the connecting portion 92. The rectangular plate has a shape with four rounded corners (R shape). Holes 93z into which screws are inserted are formed in the four corners of the pedestal 93, respectively.

  The connecting portion 92 connects the light main body 91 and the pedestal 93 and has a hinge mechanism that can manually and stepwise adjust the direction of the light main body 91 with respect to the pedestal 93. Even if the pedestal 93 is attached to a member having a surface having an arbitrary angle (for example, a horizontal surface, a vertical surface, or an inclined surface), the front surface of the light main body 91 can be adjusted to a desired area by adjusting the hinge mechanism. In the direction of. In the present embodiment, the sensor light 90 is attached to the outer wall 150 of the house. In this mounting, the pedestal 93 of the sensor light 90 is fixed to the outer wall 150 by tightening screws 94 into four holes 93z provided in the pedestal 93. After installation, the connecting portion 92 is manually moved so that the direction of the light main body 91 is adjusted so that the light 907 can illuminate a monitoring area (for example, a front entrance, a garden, a garage, and the like). In addition, the mounting location of the sensor light is not limited to the outer wall of the house outside the house, but may be a veranda, a gate, a support, or the like, or may be a storeroom in the house.

  The operation of the sensor light 90 in the surveillance camera system 5 having the above configuration will be described.

  First, the setting information table 160 and the light-off delay time table 170 stored in the memory 904 will be described as data necessary for the operation of the sensor light 90.

  FIG. 10 is a diagram showing an example of registered contents of the setting information table 160 in the sensor light 90 of the present embodiment. The setting information table 160 is stored in the memory 904 of the sensor light 90 in advance, for example, during manufacturing. Note that the registered contents of the setting information table 160 may be changed by an operation switch (not shown) mounted on the sensor light 90, or may be rewritten via the master device 10 by a user's operation of the smartphone 50. .

  In the setting information table 160, items of light lighting time, light lighting pattern, light lighting luminance, illuminance sensor sensitivity, and operation sensor sensitivity are registered. In the item of “light lighting time”, a time for turning on the light 907 when the motion sensor 906 detects a movement of a person or the like, that is, a preset lighting time setting value Tam is set. This setting range is from 0 second to 3 minutes, and the initial value of the setting value Tam of the lighting time is “20 seconds”.

  In the item of “light lighting pattern”, lighting or blinking is set as a lighting method when the light 907 is turned on. The initial value is set to "lighting". In the item of “light lighting brightness”, the brightness when the light 907 is turned on is set. This setting range is 100-300 lumens. The initial value is “300 lumens”.

  In the item of “illuminance sensor sensitivity”, the sensitivity of the illuminance sensor 905 is set so as not to emit light even when the motion sensor 906 detects a motion of a person in a bright daytime or the like. This setting range includes "bright" (lights up even slightly brighter than "normal"), "normal" (starts lighting from dimly lit), and "dark" (compared to "normal"). , Start lighting after a little darkening). The default value is "normal".

  In the item of “motion sensor sensitivity”, the detection sensitivity of the motion sensor is set. In this setting range, "High" (it is easier to respond even with a little action compared to "Medium"), "Medium" (moderate response), "Low" (It is less responsive than "Medium") ), And four levels of “extremely low” (more difficult to respond than “medium”). The initial value is “medium”.

  Note that the items registered in the setting information table 160 are not limited to these five items, but may be other items, for example, a setting change according to the weather (always off in rainy weather), a limit value of the number of lightings per day, A blink cycle at the time of blinking, a luminance change pattern at the time of lighting, and the like may be included.

  FIG. 11 is a diagram illustrating an example of registered contents of the light-off delay time table 170 in the sensor light 90 according to the present embodiment. The turn-off delay time table 170 is stored in the memory 904 of the sensor light 90 in advance. The registered contents of the turn-off delay time table 170 may be changed by an operation switch mounted on the sensor light 90, or may be rewritten via the master device 10 by a user's operation of the smartphone 50.

  In the turn-off delay time table 170, a turn-off delay time set value Tdm corresponding to the turn-on time set value Tam of the light 907 set by the user is registered. Specifically, when the set value Tam of the lighting time is less than 1 minute, the set value Tdm of the turn-off delay time is 5 seconds. When the set value Tam of the lighting time is 1 minute or more, the set value Tdm of the light-off delay time is 10 seconds. These values are merely examples, and can be set to any values.

  FIG. 12 is a flowchart illustrating an example of an operation procedure of the sensor light 90 according to the present embodiment when the light is off. This operation is repeatedly executed by the processor 901 of the sensor light 90 while the light 907 is turned off.

  In FIG. 12, the processor 901 determines whether or not a motion of a person is detected by the motion sensor 906 (S1). When the motion of the person is not detected (S1, NO), the processor 901 repeats the process of step S1.

  On the other hand, when the motion of the person is detected (S1, YES), the processor 901 determines whether the surroundings are brighter than the set value, that is, the illuminance detected by the illuminance sensor 905 is the set value (“ It is determined whether the conditions of “bright”, “normal”, and “dark” are satisfied (S2). If the surroundings are brighter than the set value (S2, YES), the processing of the processor 901 returns to step S1, and the same processing is repeated.

  On the other hand, when the surroundings are darker than the set value (S2, NO), the processor 901 turns on the light 907 (S3). Further, the processor 901 starts the lighting time measurement timer 901z and starts measuring the lighting time Ta (S4). After that, the processor 901 ends the process of turning off the light and shifts to the process of turning on the light shown in FIG.

  FIG. 13 is a flowchart illustrating an example of an operation procedure during lighting of the sensor light 90 of the present embodiment. This operation is repeatedly executed by the processor 901 of the sensor light 90 while the light 907 is on.

  In FIG. 13, the processor 901 determines whether or not a motion of a person is detected by the motion sensor 906 (S11). When the motion of the person is detected (S11, YES), the processor 901 repeats the process of step S11.

  On the other hand, when the movement of the person is no longer detected (S11, NO), the processor 901 activates the turn-off delay time measurement timer 901y and starts measuring the turn-off delay time Td (S12). The processor 901 calculates a set value Tdm of the light-off delay time (S13). In the calculation of the set value Tdm of the light-off delay time, the light-off delay time table 170 is referred to according to the first setting method described above, for example, and the light-off delay time set value Tdm (here, , 5 seconds or 10 seconds). Note that the processor 901 may acquire the set value Tdm of the light-off delay time using the second setting method.

  The processor 901 determines whether or not the motion of the person has been detected again by the motion sensor 906 (S14). When the motion of the person is detected (S14, YES), it means that the motion of the person or the other person that is no longer detected in step S11 is detected. For this reason, the processor 901 stops the measurement of the light-off delay time measurement timer 901y, and resets the measured value to 0 (S15). Then, the process of the processor 901 returns to step S11.

  On the other hand, when the motion of the person is not detected by the motion sensor 906 in step S14 (S14, NO), the processor 901 obtains (calculates) the light-off delay time Td measured by the light-off delay time measurement timer 901y in step S13. It is determined whether or not the value is equal to or longer than the set value Tdm of the turned-off delay time (S16). When the light-off delay time Td is less than the light-off delay time set value Tdm (S16, NO), the processing of the processor 901 returns to step S14.

  On the other hand, when the light-off delay time Td is equal to or longer than the light-off delay time set value Tdm (S16, YES), the processor 901 stores the measured value of the light-on time Ta measured by the light-on time measurement timer 901z in the setting information table 160. It is determined whether the registered lighting time is equal to or longer than the set value Tam (S17). When the measured value of the lighting time Ta is less than the set value Tam of the lighting time (S17, NO), the processing of the processor 901 returns to step S14.

  On the other hand, when the measured value of the lighting time Ta is equal to or more than the set value Tam of the lighting time (S17, YES), the processor 901 stops the measurement of the lighting time measurement timer 901z and resets the measured value to 0 ( S18), the measurement of the light-off delay time measurement timer 901y is stopped, the measured value is reset to 0 (S19), and the processor 901 turns off the light 907 (S20). After that, the processor 901 ends the lighting process and shifts to the lighting process.

  As described above, in the sensor light 90 of the present embodiment, when the motion sensor 906 detects the motion of the person, the processor 901 turns on the light 907. The light 907 illuminates the monitoring area when turned on. The processor 901 starts measuring the lighting time Ta of the light 907. After that, the processor 901 starts measuring the turn-off delay time Td when the movement of the person is no longer detected, and acquires the set value Tdm of the turn-off delay time according to the set value Tam of the turn-on time of the light 907. The processor 901 turns off the light 907 when the measured value of the turn-off delay time Td exceeds the set value Tdm of the turn-off delay time and the measured value of the lighting time Ta of the light 907 exceeds the set value Tam of the turn-on time. Let it.

  Thus, it is possible to achieve both turning on the light 907 for a certain period of time and turning off the light 907 as much as possible while suppressing an increase in the power consumption of the sensor light 90. Further, even if the sensor light 90 detects the movement of a person and turns on after detecting the movement of the person, even if the movement of the person is no longer detected when the set lighting time elapses, it is possible to prevent the light from being turned off immediately.

  In addition, the sensor light 90 includes a memory 904 that stores the set value Tdm of the light-off delay time in association with the set value Tam of the lighting time of the light 907. The processor 901 reads out the setting value Tdm of the light-off delay time stored in the memory 904 based on the setting value Tam of the lighting time of the light 907. By storing the set value Tdm of the turn-off delay time corresponding to the set value Tam of the turn-on time of the light 907 in the memory 904 in advance, it becomes easy to obtain the set value Tdm of the turn-off delay time.

  Further, the set value Tdm of the light-off delay time is set to a time that becomes longer or shorter according to the length of the set value Tam of the lighting time of the light 907. As a result, the setting value Tdm of the light-off delay time is set so as to be longer as the setting value Tam of the light 907 is longer or shorter as the setting value Tam is shorter (that is, from the time when the movement of the person is no longer detected until the light is turned off). The duration of the non-detection state of a person) can be varied. Therefore, as the set value Tam of the lighting time is longer, the set value Tdm of the light-off delay time is longer, so that the lighting of the sensor light 90 for the preset time is completed, and the lighting time until that time is reached even after the person is gone. The light can be turned off after a sufficient delay according to the time. Further, the shorter the set value Tam of the lighting time is, the shorter the set value Tdm of the turn-off delay time is. Therefore, when the sensor light 90 is driven by a battery, it is possible to suppress a decrease in the remaining amount of the battery and to temporarily set the light. If the light source 907 is turned on for a sufficiently long time exceeding the set value Tam of the lighting time, the light is turned off immediately if the non-detection state continues during the period of the set value of the short turn-off delay time after the motion of the person is not detected. An increase in power consumption of the light 90 can be suppressed.

  Further, the processor 901 obtains, as the set value Tdm of the light-off delay time, a predetermined ratio of the light-on time Ta of the light 907 when the movement of the person is no longer detected. Thus, the processor 901 can set the set value Tdm of the light-off delay time in consideration of the length of the light-on time of the light 907.

  After determining that the measured value of the turn-off delay time Td has exceeded the set value Tdm of the turn-off delay time, the processor 901 determines whether the measured value of the lighting time Ta of the light 907 has exceeded the set value of the turn-on time Tam. to decide. As a result, even if the movement of a person is no longer detected when the lighting time Ta ends, the light 907 does not have to continue to light for the set value Tdm of the light-off delay time. That is, it is possible to prevent the lighting time Ta and the set value Tdm of the light-off delay time from being added to the lighting time and to keep the lighting on, and to save waste of power consumption in the battery-powered (that is, battery-powered) sensor light 90. .

  Although the present embodiment has been described with reference to the drawings, it goes without saying that the present invention is not limited to such an example. It is clear that those skilled in the art can conceive various changes or modifications within the scope of the claims, and these naturally belong to the technical scope of the present invention. I understand.

  Further, the present invention supplies a program for realizing the function of the sensor light of the present embodiment to the sensor light via a network or various storage media, and reads and executes a program in a processor in the sensor light. The recording medium on which the program is recorded is also applicable.

  The present invention makes it possible to turn on the light for a certain period of time, and to turn off the light as soon as possible by suppressing an increase in power consumption. It is useful as a sensor light that can prevent the light from being turned off immediately even if the movement of the person is not detected immediately before the end of the operation.

Reference Signs List 5 surveillance camera system 8 home 10 parent device 10a outlet 20, 20A, 20B slave device 30 camera 30A indoor camera 30B surveillance camera 40, 40A, 40B, 40C, 40D sensor 50 smartphone 60 wireless router 65 Internet 70 mobile phone 75 mobile Telephone network 80 Smart plug 85 Fixed telephone network 90 Sensor light 91 Light body 92 Connecting part 93 Pedestal 93z hole 94 Screw 101 Fixed telephone line I / F part 103, 242, 303, 442, 504, 842 Storage part 104, 243, 304 , 505 Audio input / output control unit 105, 244, 305, 841 Operation unit 106, 245, 845 Display unit 107, 248, 318, 448, 848, 902 DECT wireless I / F unit 108, 249, 317, 449, 849 DEC Protocol control unit 109, 247, 309, 447, 506, 847 Control unit 110 Call control unit 112 Audio stream processing unit 115 Image memory control unit 116 Image memory 117, 255, 307, 515 Audio bus 121, 321, 507 Wireless LAN control Units 122, 322, 508 Wireless LAN communication I / F unit 126 Handset / portable terminal charging unit 127 USB communication I / F unit 128, 251, 328, 512 Microphone 129, 252, 329, 513 Speaker 150 Outer wall 160 Setting information table 170 Turn-off delay time table 250, 550 Secondary battery 312 Imaging unit 313 Infrared sensor 314 Power supply unit 315 Image memory 316 Image memory control unit 445 Indicator lamp 450 Rechargeable battery 453 Sensor unit 501 3G / 4G wireless I / F unit 502 3G 4G protocol control unit 503 display / operation section (touch panel)
511 USB communication I / F unit 514 Monitoring function control unit 800 Fixed telephone 851 Plug terminal 852 Outlet terminal 853 Solenoid coil 850, 854 Switch unit 855 Current detection element 901 Processor 901y Lighting delay time measurement timer 901z Lighting time measurement timer 903 DECT protocol processing Unit 904 memory 905 illuminance sensor 906 operation sensor 907 light 908 battery

Claims (5)

A light that lights at least for a preset time,
A sensor for detecting the movement of the moving body,
A processor that turns on the light when the movement of the moving body is detected,
The processor comprises:
The measurement of the lighting time of the light is started in response to the lighting of the light, and thereafter, when the movement of the moving body is no longer detected, the time from when the moving body is no longer detected until the light is turned off is stopped. the measurement of the switch-off delay time indicating the duration of the non-detection state of the moving body to start,
Exceeds the set value of the switch-off delay time of the measured value is the light unlit delay associated et a set value of the lighting time, and the time measurement value of the lighting time of the light the preset If exceeded, turn off the light,
Sensor light. The sensor light according to claim 1,
A memory that stores the set value of the light-off delay time in association with the set value of the light-on time of the light,
The processor acquires the set value of the light-off delay time by reading the set value of the light-on time of the light,
Sensor light. The sensor light according to claim 2,
The set value of the light-off delay time is set to a different time according to the set value of the light-on time of the light,
Sensor light. The sensor light according to claim 1,
The processor acquires a value of a predetermined ratio of a measured value of the lighting time of the light at the time when the moving object is no longer detected as the set value of the light-off delay time,
Sensor light. The sensor light according to claim 1,
The processor, after determining that the measured value of the light-off delay time exceeds the set value of the light-off delay time, determines whether the measured value of the light-on time of the light exceeds the preset time,
Sensor light.

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