JP2020088631A - Security system and security method - Google Patents

Abstract

To provide a security system and a security method capable of tracking and photographing a target with an unmanned aircraft by a simple operation.SOLUTION: A security system 1 comprises: an unmanned aircraft 30 that is operable by plural different modes and transmits an image photographed with a camera; and a terminal 70 that displays the image transmitted from the unmanned aircraft, information of a mode in the unmanned aircraft, and a UI (User Interface) having an operation interface of the unmanned aircraft.SELECTED DRAWING: Figure 15

Description

The present disclosure relates to a security system and a security method.

In recent years, on-site camera systems (ICV: In Car Video System) mounted on patrol cars and wearable cameras (BWC: Body-Worn Camera) mounted on police officers' uniforms have been used for scenes of incidents and accidents. Is being photographed and recorded. For example, Patent Document 1 discloses the following system. That is, the BWC captures an image of the front of the police officer and transmits the captured image data to the ICV. The ICV stores the video data captured by the vehicle-mounted camera and the video data transmitted from the BWC.

In recent years, it has been considered to use an unmanned aerial vehicle (drone) to photograph and record the scene of an incident or accident. For example, Patent Document 2 discloses that a drone moves to an accident scene and photographs and records the accident scene.

JP, 2018-42229, A JP, 2018-110304, A

However, since the scene of an incident or accident is urgent, it is not preferable that the operation of the unmanned aerial vehicle is complicated, for example, when the unmanned aerial vehicle is to track and record a target such as a person or a vehicle escaping from the scene.

The non-limiting examples of the present disclosure contribute to a security system and a security method capable of tracking and photographing a target by an unmanned aerial vehicle with a simple operation.

A security system according to an aspect of the present disclosure is capable of operating in a plurality of different modes, an unmanned aerial vehicle that transmits an image captured by a camera, an image transmitted from the unmanned aerial vehicle, and information on the mode in the unmanned aerial vehicle. And a terminal for displaying a UI (User Interface) having an operation interface for the unmanned aerial vehicle.

Note that these comprehensive or specific aspects may be realized by a system, method, integrated circuit, computer program, or recording medium, and any of the system, apparatus, method, integrated circuit, computer program, and recording medium may be implemented. It may be realized by any combination.

According to the present disclosure, a target can be tracked and photographed by an unmanned aerial vehicle with a simple operation.

Further advantages and effects of one aspect of the present disclosure will be apparent from the specification and the drawings. Such advantages and/or effects are provided by the features described in several embodiments and in the specification and drawings, respectively, but not necessarily all to obtain one or more of the same features. There is no.

It is a figure which shows the structural example of the security system which concerns on Embodiment 1. FIG. 3 is a diagram showing a configuration example of a BWC according to the first embodiment. It is a figure which shows the structural example of the drone which concerns on Embodiment 1. FIG. 3 is a diagram showing a configuration example of an ICV according to the first embodiment. 5 is a sequence chart showing an example of a drone takeoff process according to the first embodiment. 9 is a sequence chart showing a modified example of the drone take-off process according to the first embodiment. 5 is a sequence chart showing an example of target tracking processing according to the first embodiment. 5 is a sequence chart showing an example of a drone landing process according to the first embodiment. 6 is a sequence chart showing an example of a recording data management process according to the first embodiment. It is a figure which shows the structural example of the security system which concerns on Embodiment 2. 9 is a sequence chart showing an example of processing according to the second embodiment. 9 is a sequence chart showing a modified example of the processing according to the second embodiment. It is a figure which shows the structural example of the security system which concerns on Embodiment 3. 9 is a sequence chart showing an example of processing according to the third embodiment. It is a figure which shows the structural example of the security system which concerns on Embodiment 4. It is a figure which shows an example of UI for drones in case the drone which concerns on Embodiment 4 is a patrol mode. It is a figure which shows an example of UI for drones in case the drone which concerns on Embodiment 4 is a manual mode. It is a figure which shows an example of UI for drones when the drone which concerns on Embodiment 4 is a tracking mode. 16 is a sequence chart showing an example of processing according to the fourth embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed description of well-known matters or duplicate description of substantially the same configuration may be omitted. This is to prevent the following description from being unnecessarily redundant and to facilitate understanding by those skilled in the art.

It should be noted that the accompanying drawings and the following description are provided for those skilled in the art to fully understand the present disclosure, and are not intended to limit the claimed subject matter by these.

(Embodiment 1)
<System configuration>
FIG. 1 is a diagram showing a configuration example of a security system 1 according to the first embodiment. The security system 1 shown in FIG. 1 includes a BWC 10, an ICV 20, an in-vehicle camera 22, a drone 30, a center server 40, and a PC 50. The BWC 10 is attached to or carried by a police officer, for example. The ICV 20 and the drone 30 are provided in, for example, a patrol car. The center server 40 is installed in, for example, a police station.

Next, an example of the configuration of the BWC 10 will be described with reference to FIG.

As shown in FIG. 2, the BWC 10 includes a camera 1001, a GPIO 1002 (General Purpose Input/Output), a RAM (Random Access Memory) 1003, a ROM (Read Only Memory) 1004, and a storage unit 1005. The BWC 10 includes an EEPROM (Electrically Erasable Programmable ROM) 1006, an RTC (Real Time Clock) 1007, and a GPS (Global Positioning System) receiving unit 1008. The BWC 10 includes an MCU (Micro Controller Unit) 1009, a communication unit 1010, a USB (Universal Serial Bus) 1011, a contact terminal 1012, a power supply unit 1013, and a battery 1014.

The BWC 10 includes, as an example of an operation input unit, a recording switch SW1, a snapshot switch SW2, an attribute information addition switch SW3, an attribute selection switch SW4, a communication mode switch SW5, and an indicator switch SW6.

The BWC 10 includes LEDs (Light Emitting Diodes) 1015a, 1015b, and 1015c and a vibrator 1016 as an example of a state display unit.

A camera 1001 which is an example of an imaging unit includes, for example, an imaging lens and a solid-state imaging device such as a CCD (Charge Coupled Device) type image sensor or a CMOS (Complementary Metal Oxide Semiconductor) type image sensor. The camera 1001 outputs the image data of the subject obtained by imaging to the MCU 1009.

The GPIO 1002 is a parallel interface, and between the recording switch SW1, the snapshot switch SW2, the attribute information addition switch SW3, the attribute selection switch SW4, the communication mode switch SW5, the indicator switch SW6, the LEDs 1015a to 1015c, the vibrator 1016, and the MCU 1009. Input and output signals. Further, various sensors (for example, an acceleration sensor) are connected to the GPIO 1002.

The RAM 1003 is, for example, a work memory used in the operation of the MCU 1009. The ROM 1004 is, for example, a memory that stores in advance a program and data for controlling the MCU 1009.

The storage unit 1005 is composed of, for example, a storage medium such as an SD memory, and stores video data obtained by capturing an image with the camera 1001. When an SD memory is used as the storage unit 1005, it can be attached to and detached from the main body of the BWC 10.

The EEPROM 1006 stores, for example, identification information that identifies the BWC 10 (for example, a serial number as a Camera ID) and other setting information. The other setting information includes, for example, login information (for example, Car ID, Office ID) obtained by setting registration on the in-house PC in the police station or logging in to the ICV 20, the state of the attribute selection switch SW4, and the attribute information. Correspondence information indicating correspondence is included.

The RTC 1007 counts the current time information and outputs it to the MCU 1009.

The GPS receiving unit 1008 receives the current position information and time information of the BWC 10 from a GPS transmitter (not shown) and outputs it to the MCU 1009. The time information is used for correcting the system time of the BWC 10.

The MCU 1009 has a function as a control unit, for example, a control process for generally controlling the operation of each unit of the BWC 10, a data input/output process with each unit of the BWC 10, and a data calculation (calculation) process. And storing data, and operates according to the programs and data stored in the ROM 1004. During operation, the MCU 1009 uses, for example, the RAM 1003, obtains current time information from the RTC 1007, and obtains current position information from the GPS receiving unit 1008. In addition, in the following description, the operation of the BWC 10 may be realized by the processing of the MCU 1009.

The communication unit 1010 defines the connection between the communication unit 1010 and the MCU 1009 in the physical layer which is the first layer of the OSI (Open Systems Interconnection) reference model, for example. The communication unit 1010 performs wireless communication (for example, Wi-fi (registered trademark)) by, for example, a wireless LAN (W-LAN) according to this regulation. The communication unit 1010 may perform wireless communication such as near field communication (NFC: Near Field Communication) and Bluetooth (registered trademark).

The USB 1011 is a serial bus and enables connection with the ICV 20 or the in-office PC, for example.

The contact terminal 1012 is a terminal for electrically connecting to a cradle (not shown) or an external adapter (not shown), and is connected to the MCU 1009 via the USB 1011 and to the power supply unit 1013. Through the contact terminal 1012, charging of the BWC 10 and communication of data including video data are possible.

The contact terminal 1012 is provided with, for example, a “charging terminal V+”, a “CON.DET terminal”, a “data terminal D−, D+”, and a “ground terminal” (all not shown). CON. The DET terminal is a terminal for detecting voltage and voltage change. The data terminals D- and D+ are terminals for transferring video data captured by the BWC 10 to an external PC or the like via, for example, a USB connector terminal.

By connecting the contact terminal 1012 and a connector of a cradle (not shown) or an external adapter (not shown), data communication becomes possible between the BWC 10 and an external device.

The power supply unit 1013 charges the battery 1014 by supplying the power supply power supplied from the cradle or the external adapter to the battery 1014 via the contact terminal 1012, for example. The battery 1014 is composed of, for example, a rechargeable secondary battery, and supplies power source power to each unit of the BWC 10.

The recording switch SW1 is, for example, a push button switch for inputting an operation instruction for starting/stopping recording (imaging of a moving image) by a pressing operation of a police officer.

The snapshot switch SW2 is, for example, a push button switch for inputting an operation instruction for capturing a still image by a pressing operation of a police officer.

The attribute information addition switch SW3 is, for example, a push button switch for inputting an operation instruction for adding attribute information to video data by a pressing operation by a police officer.

The attribute selection switch SW4 is, for example, a slide switch that inputs an operation instruction for selecting an attribute to be added to video data.

The communication mode switch SW5 is, for example, a slide switch that inputs an operation instruction for setting a communication mode between the BWC 10 and an external device.

The indicator switch SW6 is, for example, a slide switch that inputs an operation instruction for setting the operation state display mode by the LEDs 1015a to 1015c and the vibrator 1016.

The recording switch SW1, the snapshot switch SW2, the attribute information addition switch SW3, and the attribute selection switch SW4 are configured to be easily operable even in an emergency. Note that the switches SW1 to SW6 are not limited to the above-described forms, and may be operation input devices of other forms that allow the user to input operation instructions.

The LED 1015a is, for example, a display unit showing the power-on state (on/off state) of the BWC 10 and the state of the battery 1014.

The LED 1015b is, for example, a display unit that indicates the state of the image pickup operation (recording state) of the BWC 10.

LED1015c is a display part which shows the state of the communication mode of BWC10, for example.

The MCU 1009 detects the input of each of the recording switch SW1, the snapshot switch SW2, the attribute information addition switch SW3, the attribute selection switch SW4, the communication mode switch SW5, and the indicator switch SW6, and processes the switch input that has been operated. ..

When detecting the operation input of the recording switch SW1, the MCU 1009 controls the start or stop of the imaging operation of the camera 1001 and saves the video data obtained from the camera 1001 in the storage unit 1005 as the video data of the moving image.

When the operation input of the snapshot switch SW2 is detected, the MCU 1009 saves the video data of the camera 1001 when the snapshot switch SW2 is operated in the storage unit 1005 as the video data (record data) of a still image.

When the operation input of the attribute information addition switch SW3 is detected, the MCU 1009 adds the preset attribute information to the video data and stores it in the storage unit 1005 in association with the video data. At this time, the correspondence information indicating the correspondence between the state of the attribute selection switch SW4 and the predetermined attribute information is held in the EEPROM 1006, and the MCU 1009 detects the state of the attribute selection switch SW4 and sets the attribute selection switch SW4. According to the attribute information.

The MCU 1009 detects the state of the communication mode switch SW5 and operates the communication unit 1010 in the communication mode according to the setting of the communication mode switch SW5.

When the recording operation is started, the MCU 1009 detects the state of the indicator switch SW6, and according to the setting of the indicator switch SW6, notifies the outside of the recording operation state by LED display and/or vibrator vibration.

The BWC 10 records (records and records) in the recording unit 1005 the image captured by the camera 1001 and the sound collected by a microphone (not shown). Hereinafter, the video and audio data recorded on the BWC 10 will be referred to as “BWC recording data”. As a result, the video (and audio) around the police officer (on the scene and/or target, etc.) is recorded in the BWC recording data. The site is a place where a police officer goes to by a request such as a report, and is, for example, an incident site or an accident site. The target is a person or vehicle to be tracked by a police officer, and is, for example, a fugitive or a fleeing vehicle.

The BWC 10 may start and stop recording in response to manual operation by a police officer. Alternatively, the BWC 10 may automatically start and stop recording when a predetermined condition is satisfied. The predetermined condition is, for example, a case where the BWC 10 is separated from the ICV 20 by a predetermined distance or more.

The BWC 10 may also send the BWC recording data to the ICV 20. That is, the BWC recording data may be managed by the ICV 20. The BWC 10 may send the BWC recording data being recorded to the ICV 20 at any time. Alternatively, the BWC 10 may transmit the BWC recording data to the ICV 20 after the recording is stopped.

The BWC 10 may specify the current position by the GPS receiving unit 1008 and transmit the specified position information (hereinafter referred to as “BWC position information”) to the ICV 20.

Next, an example of the configuration of the drone 30, which is an example of an unmanned aerial vehicle (UAV), will be described with reference to FIG.

As shown in FIG. 3, the drone 30 includes a control unit 1201, a communication unit 1202, a camera 103, a GPS receiving unit 1204, a driving unit 1205, a battery 1206, and a storage unit 1207. ..

The control unit 1201 controls the drone 30 as a whole. The control unit 1201 may be configured by a CPU, for example. In addition, in the following description, the operation of the drone 30 may be realized by the processing of the control unit 1201.

The communication unit 1202 performs wireless communication with a base station (not shown). A camera 1203, which is an example of an imaging unit, includes an optical lens, a lens control mechanism, an image sensor, and the like. The camera 1203 outputs the captured video data to the control unit 1201.

The GPS receiving unit 1204 receives GPS signals transmitted from a plurality of GPS satellites and calculates the current position of the drone 30 using the received GPS signals. The current position includes, for example, latitude and longitude.

The drive unit 1205 is, for example, a motor, and rotates a propeller (not shown) of the drone 30 under the control of the control unit 1201. The battery 1206 is a power source of the drone 30 and is, for example, a rechargeable secondary battery.

The storage unit 1207 stores a program for operating the control unit 1201. In addition, the storage unit 1207 stores data for the control unit 1201 to perform calculation processing, data for the control unit 1201 to control each unit, and the like. The storage unit 1207 may be configured by a storage device such as RAM, ROM, flash memory, and HDD.

The drone 30 stream-transmits the image captured by the camera 1203 and the sound collected by the microphone to the ICV 20 and/or the center server 40. As a result, the ICV 20 and/or the center server 40 can output the image and sound that the drone 30 is capturing and collecting.

When the drone 30 receives the recording start command, which is an example of the control command, the drone 30 starts recording (recording and recording) the image captured by the camera 1203 and the sound collected by the microphone. When the drone 30 receives a recording stop command, which is an example of a control command, the drone 30 stops the recording. Hereinafter, the video and audio data recorded in the drone 30 will be referred to as “drone recording data”.

When the drone 30 receives a take-off command, which is an example of a control command, the drone 30 takes off and tracks the BWC position (that is, police officer). As a result, the drone record data records the image and sound around the police officer. When the drone 30 receives a return command, which is an example of a control command, the drone 30 returns to the position of the ICV 20 (that is, the position of the patrol car) and lands.

Further, when the drone 30 receives the tracking command which is an example of the control command, the drone 30 tracks the target designated by the tracking command. The control command may be transmitted from the ICV 20 and/or the center server 40.

The drone 30 may also send drone recording data to the ICV 20. That is, the drone record data may be managed by the ICV 20. The drone 30 may send the drone recording data being recorded to the ICV 20 at any time. Alternatively, the drone 30 may send drone recording data to the ICV 20 after recording has stopped or after landing.

Next, with reference to FIG. 4, a configuration of the ICV 20 which is an example of the in-vehicle recorder will be described.

As shown in FIG. 4, the ICV 20 includes a CPU 1301, a wireless communication unit 1302, a wired communication unit 1303, a flash ROM 1304, a RAM 1305, a μCON 1306, a GPS receiving unit 1307, a GPIO 1308, a button 1309, an LED 1310, and an SSD 1311.

The CPU 1301 performs, for example, a control process for generally controlling the operation of each unit of the ICV 20, a data input/output process with other units, a data calculation (calculation) process, and a data storage process.

The wireless communication unit 1302 wirelessly communicates with an external device via a wireless line. The wireless communication includes, for example, wireless LAN (Local Area Network) communication, near field communication (NFC), and Bluetooth (registered trademark). The wireless LAN communication is performed in accordance with, for example, the Wi-fi (registered trademark) IEEE 802.11n standard. The CPU 1301 and the wireless communication unit 1302 are connected via, for example, PCI (Peripheral Component InterConnect) or USB. The wireless communication unit 1302 wirelessly communicates with, for example, the vehicle-mounted camera 22, the vehicle-mounted PC 50, the BWC 10, the in-station PC of the police station, and/or the center server 40.

The wired communication unit 1303 performs wired communication with an external device via a wired line (for example, wired LAN). The wired communication unit 1303 performs wired communication with, for example, the in-vehicle camera 22, the in-vehicle PC 50, the BWC 10, the in-house PC of the police station, and/or the center server 40.

The flash ROM 1304 is, for example, a memory that stores programs and data for controlling the CPU 1301. In addition, various setting information is held.

The RAM 1305 is, for example, a work memory used in the operation of the CPU 1301. A plurality of RAMs 1305 are provided, for example.

The μCON 1306 is, for example, a kind of microcomputer, is connected to each unit related to an external interface (for example, the GPS receiving unit 1307, GPIO 1308, button 1309, LED 1310) and controls the external interface. The μCON 1306 is connected to the CPU 1301 via, for example, a UART (Universal Asynchronous Receiver Transmitter).

The GPS receiving unit 1307 receives, for example, the current position information and time information of the ICV 20 from a GPS transmitter (not shown) and outputs it to the CPU 1301. This time information is used for correcting the system time of the ICV 20.

The GPIO 1308 is, for example, a parallel interface, and inputs/outputs signals between an external device (not shown) connected via the GPIO 1308 and the μCON 1306. Various sensors (for example, a speed sensor, an acceleration sensor, a door opening/closing sensor) are connected to the GPIO 1308.

The button 1309 is, for example, a recording button for starting or stopping the recording of the video data captured by the vehicle-mounted camera 22, and an attachment for attaching attribute information or meta information to the video data captured by the vehicle-mounted camera 22. Including buttons.

The LED 1310 displays, for example, the power-on state (on/off state) of the ICV 20, the recording execution state, the connection state of the ICV 20 to the LAN, the use state of the LAN connected to the ICV 20, by turning on, turning off, blinking, or the like.

The SSD 1311 which is an example of a storage stores, for example, video data captured by the vehicle-mounted camera 22 and audio data collected by a microphone (hereinafter referred to as “ICV recording data”). The ICV recording data records video and audio around the patrol car (site, target, and/or police officer, etc.). Further, the SSD 1311 accumulates the BWC recording data transmitted from the BWC 10. Further, the SSD 1311 accumulates drone recording data transmitted from the drone 30. Further, the SSD 1311 may store data other than video data. The SSD 1311 is connected to the CPU 1301 via SATA (Serial ATA). A plurality of SSDs 1311 may be provided. A storage other than the SSD 1311 (for example, HDD) may be provided.

Further, the ICV 20 accepts the input of the incident information through the PC 50 connected to the ICV 20. For example, after processing the case, the police officer operates the PC 50 to input the case information related to the case, and the case information is used as the BWC record data, the ICV record data, and the record of the scene of the case. Associate with drone record data. The case information is, for example, information related to the case, such as the name and/or address of an investigation target person who is a suspect of crime, accident, or traffic violation, and information such as a signature of the investigation target person. The PC 50 is an example of an input terminal, and the PC 50 may be replaced with a smartphone, a tablet terminal, or the like.

Further, the ICV 20 may associate (in a set) the case information with the BWC record data, the ICV record data, and the drone record data in which the scene of the case is recorded, and may transmit them to the center server 40. Thereby, the center server 40 can manage the incident information regarding the incident on the spot, the BWC record data, the ICV record data, and the drone record data in association with each other.

The center server 40 manages incident information and record data collected from each ICV 20. Further, the center server 40 may be capable of giving an instruction to each ICV 20 and/or each drone 30.

The configuration shown in FIG. 1 is an example, and the security system 1 may have a configuration different from that of FIG. For example, in the present disclosure, a part of the processing performed by the ICV 20 (for example, processing regarding control of the drone 30) may be performed by another device (for example, the drone control device). The drone 30 may be installed in a vehicle different from the patrol car including the ICV 20. Further, the drone 30 may be fixedly set at a predetermined place (for example, a police station or police box).

<Drone takeoff>
Next, an example of the take-off process of the drone 30 will be described with reference to the sequence chart shown in FIG.

When the police officer performs the recording start operation of the BWC 10 (S101), the BWC 10 starts recording the BWC record data and associates the record ID with the BWC record data (S102). The record ID is an identifier for associating BWC record data, ICV record data, drone record data, and case information. The record ID may be any information as long as it is uniquely identifiable information such as the date and time when the recording start operation in S101 is performed.

Next, the BWC 10 transmits a recording start notification including the BWC position information and the recording ID to the ICV 20 (S103).

Upon receiving the recording start notification in S103, the ICV 20 starts recording the ICV recording data, and associates the recording ID included in the recording start notification with the ICV recording data (S104).

Then, the ICV 20 transmits a recording start command including the recording ID to the drone 30 (S105). Next, the ICV 20 transmits a takeoff command including the BWC position information and information indicating the current position of the ICV 20 (hereinafter referred to as “ICV position information”) to the drone 30 (S106). Here, by transmitting the recording start command first and transmitting the takeoff command later, it is possible to reduce the possibility that the drone 30 after takeoff cannot receive the recording start command. Note that the ICV 20 may transmit the recording start command and the takeoff command as one command.

Upon receiving the recording start command in S105, the drone 30 starts recording drone recording data and associates the recording ID included in the recording start command with the drone recording data (S107). Then, the drone 30 stream-transmits the video and audio to the center server 40 and the ICV 20 (S108). It should be noted that the drone 30 may stream the video and audio from the reception of the recording start command to the reception of the recording stop command described later.

Further, when the drone 30 receives the take-off command in S106, it takes off and tracks the position indicated by the BWC position information included in the take-off command (S109). The BWC 10 may transmit the BWC position information to the drone 30 via the ICV 20 at any time so that the drone 30 can track the moving BWC 10.

As described above, the drone 30 tracks the BWC 10 while recording the drone recording data, with the recording start of the BWC 10 as a trigger. Thereby, the video and audio of the scene can be recorded from the drone 30 without the police officer on the scene performing a complicated operation.

Note that the drone 30 may track the police officer by recognizing the face image of the police officer wearing the BWC 10 after arriving at the position indicated by the BWC position information in S109.

When the drone 30 is installed in a place other than the patrol car, the drone 30 may track the position indicated by the ICV position information included in the takeoff command of S106 in the process of S109. In this case, the drone 30 may recognize the license plate of the patrol car including the ICV 20 and track the license plate after reaching the position indicated by the ICV position information.

<Modification of drone takeoff>
Next, a modification of the sequence chart shown in FIG. 5 will be described with reference to the sequence chart shown in FIG. In FIG. 5, the recording start operation of the BWC 10 is a trigger, and the drone 30 starts takeoff and recording. In FIG. 8, the ICV 20 determines the takeoff and recording start of the drone 30.

The ICV 20 determines whether or not the takeoff condition of the drone 30 is satisfied (S201). The case where the takeoff condition of the drone 30 is satisfied is, for example, the case where the warning light of the patrol car including the (A1) ICV 20 is on and the patrol car is stopped. This is because turning on the warning light of the patrol car means that an incident has occurred, and that the patrol car has arrived at the incident scene while the patrol car is stopped. Or, if the takeoff condition of the drone 30 is satisfied, the above (A1) is satisfied and (A2) the BWC 10 is separated from the ICV 20 by a predetermined distance or more (that is, when the police officer gets out of the patrol car). ). This can prevent the drone 30 from accidentally taking off when the patrol car is stopped due to a traffic light, traffic jam, or the like (that is, other than at the site).

Next, when the ICV 20 determines in S201 that the takeoff condition of the drone 30 is satisfied, the ICV 20 starts recording the ICV record data and associates the record ID with the ICV record data (S202).

Next, the ICV 20 transmits a recording start command including the recording ID to the BWC 10 (S203). Upon receiving the recording start command of S203, the BWC 10 starts recording the BWC recording data and associates the recording ID included in the recording start command with the BWC recording data (S204).

Further, the ICV 20 transmits a recording start command and a takeoff command to the drone 30, as in S105 and S106 of FIG. 5 (S205, S206). The subsequent processes of S207 to S209 are the same as the processes of S107 to S109 of FIG.

As described above, the drone 30 tracks the BWC 10 while recording the drone recording data, with the takeoff condition of the drone 30 being satisfied in the ICV 20 as a trigger. Thereby, the video and audio of the scene can be recorded from the drone 30 without the police officer on the scene performing a complicated operation.

<Target tracking>
Next, an example of a process in which the drone 30 tracks the target will be described with reference to the sequence chart shown in FIG. 7. The process of FIG. 7 is a continuation of the process of FIG. 5 or 6. However, the process of FIG. 7 may not be executed when the target tracking is unnecessary.

The center server 40 identifies the target from the video stream-transmitted from the drone 30 (S301). For example, the operator of the center server 40 visually recognizes the image from the drone 30 and specifies the target. Alternatively, the center server 40 detects a face image or a license plate of the target registered in advance in the blacklist from the image from the drone 30 and specifies the target.

When the target is specified, the center server 40 transmits a tracking command including target information to the drone 30 (S302). The target information includes information about the target specified in S301. For example, the target information includes coordinates of the identified target on the image. Alternatively, the target information includes a face image of the identified target, a license plate, or the like.

When the drone 30 receives the tracking command in S302, it uses the target information included in the tracking command to identify the target from the video being captured by the camera and tracks the identified target (S303).

When the target is specified in S301, the center server 40 transmits a warning notice to the ICV 20 (S304). When the ICV 20 receives the warning notification in S304, the ICV 20 notifies the BWC 10 of the same warning notification (S305). This allows the police officer to know that there is a target nearby and caution is required.

<Drone landing>
Next, an example of the landing process of the drone 30 will be described with reference to the sequence chart shown in FIG. The process shown in FIG. 8 is a continuation of the process shown in FIG. 5, 6 or 7.

When the police officer performs the recording stop processing operation of the BWC 10 (S401), the BWC 10 stops recording the BWC recording data (S402). Then, the BWC 10 transmits a recording stop notification to the ICV 20 (S403).

Upon receiving the recording stop notification in S403, the ICV 20 stops recording ICV recording data (S404).
Next, the ICV 20 transmits a recording stop command to the drone 30 (S405). Further, the ICV 20 transmits a return command including the ICV position information to the drone 30 (S406). The ICV 20 may send the recording stop command and the return command as one command.

When the drone 30 receives the recording stop command in S405, the drone 30 stops recording drone recording data (S407). Further, when the drone 30 receives the return command in S406, it returns to the position indicated by the ICV position information included in the return command (that is, the position of the patrol car) (S408).

When the drone 30 arrives at the position indicated by the ICV position information (that is, above the patrol car), the drone 30 transmits a landing confirmation command to the ICV 20 (S409).

Upon receiving the landing confirmation command in S409, the ICV 20 determines whether the drone 30 can land (S410). For example, the ICV 20 determines that landing is impossible when the patrol car is traveling, and determines that landing is possible when the patrol car is stopped. Note that the ICV 20 may receive a predetermined signal from the patrol car and determine whether the patrol car is traveling.

When the ICV 20 determines in S410 that landing is possible, the ICV 20 transmits a landing permission command to the drone 30 (S411). Upon receiving the landing permission command in S411, the drone 30 lands on the patrol car (S412).

As described above, the drone 30 stops the recording of the drone recording data, triggered by the recording stop of the BWC 10, and returns to the position of the ICV 20 (patrol car). Then, the drone 30 automatically lands when the patrol car can land. This allows the drone 30 to be collected after the case is handled without the need for a complicated operation by a police officer on site.

In the example of FIG. 8, the ICV 20 determines whether or not the drone 30 can land, but the drone 30 may determine whether or not the drone 30 can land. For example, the drone 30 may determine whether the patrol car at the landing destination is running from the image captured by the camera, and automatically land if the patrol car at the landing destination is stopped.

<Recorded data management>
Next, an example of a process of associating the case information with the record data will be described with reference to the sequence chart shown in FIG. The process of FIG. 9 is a continuation of the process of FIG.

The ICV 20 stores the ICV record data associated with the record ID in the storage (S501). Further, the ICV 20 acquires the BWC record data associated with the record ID from the BWC 10 and stores it in the storage (S502). Further, the ICV 20 acquires the drone record data associated with the record ID from the drone 30 and stores it in the storage (S503).

The police officer operates the PC 50 to input the case information into the ICV 20 and associate the case information with the record ID (S504).

The ICV 20 sets the incident information, the BWC record data, the ICV record data, and the drone record data, which are associated with the common record ID, as a set and transmits the set to the center server 40 (S505).

As described above, the BWC recording data, the ICV recording data, and the drone recording data in which the video and audio of the common field and/or the target are recorded are associated with each other by the common recording ID. Thereby, the police officer can easily associate the input incident information with the BWC recording data, the ICV recording data, and the drone recording data in which the scene and/or the target indicated by the incident information are recorded. In addition, the center server 40 can manage and search incident information, BWC record data, ICV record data, and drone record data related to a common site and/or target using the record ID as a key.

Note that in the present embodiment, the above-mentioned association by the record ID is not an essential configuration. For example, when the association of the case information, the BWC record data, the ICV record data, and the drone record data shown in FIG. 9 is not implemented, the above record ID may be omitted.

(Embodiment 2)
FIG. 10 is a diagram showing a configuration example of the security system 1 according to the second embodiment. In FIG. 10, the drone 30 is installed in a vehicle different from the plurality of patrol cars including the ICV 20. Note that the contents already described in the first embodiment may be omitted in the second embodiment.

Next, an example of the processing according to the second embodiment will be described with reference to the sequence chart shown in FIG.

The drone 30 establishes a communication link with one of the ICVs 20 (S601). For example, the ICV 20 that has detected the occurrence of an incident establishes a communication link with one drone 30.

The drone 30 having established the communication link transmits an ICV ID request to the ICV 20 (S602) and receives an ICV ID response from the ICV 20 (S603). The ICV ID is information for identifying the ICV 20. Note that instead of the ICV ID, information (for example, vehicle ID) for identifying the patrol car including the ICV 20 may be used.

The drone 30 stores the ICV ID of S603 in the memory (S604). Thereby, the ICV ID of the ICV 20 which is establishing the communication link is stored in the memory of the drone 30.

Similar to S107 to S109 of FIG. 5, the drone 30 starts recording drone recording data (S605), transmits video and audio streams (S606), and tracks the BWC 10 (S607). Note that in S605, unlike in S107, the record ID does not have to be associated.

When the drone 30 stops recording the drone record data, the drone 30 associates the ICV ID stored in the memory with the drone record data (S608). The drone 30 may perform at least part of the processing shown in FIG. 7 and/or FIG. 8 until the drone recording data is stopped.

Then, the drone 30 transmits the drone recording data associated with the ICV ID to the center server 40 (S609).

According to the above processing, the center server 40 can identify which drone recording data is recorded by the instruction from which ICV 20 by referring to the ICV ID. Further, the center server 40 receives, from the ICV 20, the incident information, the BWC record data, and the ICV record data in which the ICV ID is associated instead of the record ID described in the first embodiment, and thus the common ICV ID is used as a key. As, it is possible to manage and retrieve incident information, BWC record data, ICV record data and drone record data relating to a common site and/or target.

Next, a modification of the sequence chart shown in FIG. 11 will be described with reference to the sequence chart shown in FIG.

The drone 30 establishes a communication link with one of the ICVs 20 as in S601 of FIG. 11 (S701). Then, the drone 30 performs the same processing as S605 to S607 in FIG. 11 (S702 to S704). That is, unlike the case of FIG. 11, the drone 30 does not need to store the ICV ID in the memory.

When the drone 30 stops recording the drone recording data (S705), the drone 30 transmits the drone recording data to the ICV 20 (S706).

Upon receiving the drone recording data in S706, the ICV 20 associates the ICV ID of the ICV 20 with the drone recording data (S707).

The same processing as in FIG. 11 can be realized by the above processing.

(Embodiment 3)
FIG. 13 is a diagram showing a configuration example of the security system 1 according to the third embodiment. In FIG. 13, a plurality of LPR (License Plate Recognition) cameras 60 are added to the configuration of FIG. Note that the contents already described in the first embodiment may be omitted in the third embodiment.

The LPR camera 60 is an example of a surveillance camera and is installed on a road or the like. The LPR camera 60 can detect the license plate of the vehicle by image processing or the like. Further, the LPR camera 60 may be capable of transmitting/receiving data to/from the ICV 20, the drone 30, and/or the center server 40.

Next, an example of the processing of the security system 1 shown in FIG. 13 will be described with reference to the sequence chart shown in FIG.

When the LPR camera 60 detects the license plate of the target (vehicle) from the captured image (S801), the target information (here, the license plate) of the target and information indicating the position of the LPR camera 60 (hereinafter referred to as “LPR camera”). A tracking command including "60 position information" is transmitted to the ICV 20 (S802).

Upon receiving the tracking command in S802, the ICV 20 starts recording ICV recording data (S803). Further, the ICV 20 transmits the tracking command similar to S802 to the drone 30 (S804).

Upon receiving the tracking command of S804, the drone 30 starts recording drone recording data (S805). Further, the drone 30 stream-transmits the video and audio to the ICV 20 (and the center server 40) (S806).

Then, the drone 30 flies toward the position indicated by the LPR camera 60 position information included in the tracking command of S804 (S807). When the target is moving, the target may be detected by another LPR camera 60 while the drone 30 is flying. In that case, the drone 30 may fly towards the position of the LPR camera 60 that last detected its target.

After arriving at the position indicated by the LPR position information, the drone 30 tracks the specified target when the license plate indicated by the target information is specified from the video (S808).

As described above, the drone 30 uses the detection of the target by the LPR camera 60 as a trigger to track the target while recording the drone recording data. Thereby, the target video and audio can be recorded from the drone 30 without performing a complicated operation.

Note that the LPR camera 60 detects the target in the process of FIG. 14, but another device may detect the target. For example, the LPR camera 60 may transmit the captured image to the center server 40, and the center server 40 may detect the target from the received image. In this case, the center server 40 may send the tracking commands of S802 and S804 to the ICV 20 and the drone 30.

(Embodiment 4)
FIG. 15 is a diagram showing a configuration example of the security system 1 according to the fourth embodiment. The security system 1 shown in FIG. 15 includes a drone 30 and a mobile terminal 70 carried by a police officer.

The drone 30 has a patrol mode of patrol a predetermined route, a manual mode of operating in response to an operation from the mobile terminal 70, and a tracking mode of tracking a target. However, the drone 30 does not necessarily have to have all of these modes, and may have at least one mode.

The mobile terminal 70 can send and receive data to and from the drone 30 through the communication network. The mobile terminal 70 may be, for example, a smartphone, a tablet terminal, a mobile PC 50, or the like. On the mobile terminal 70, a UI for operating the drone 30 (hereinafter referred to as “drone UI”) is displayed.

Next, an example of the drone UI will be described with reference to FIGS. 16, 17, and 18.

As shown in FIGS. 16 to 18, the drone UI 200 has a mode display area 201, a video display area 202, and operation buttons 203.

In the mode display area 201, which mode the drone 30 is in is displayed. 16 is a display example when the drone 30 is in patrol mode, FIG. 17 is a display example when the drone 30 is in manual mode, and FIG. 18 is a display example when the drone 30 is in tracking mode. . In the image display area 202, an image captured by the camera 1203 of the drone 30 and stream-transmitted from the drone 30 is displayed. The operation button 203 is a button for operating the drone 30.

In the patrol mode or the tracking mode, when the operation button 203 is operated (for example, the operation of the finger 211 in FIG. 16), the drone 30 may be switched to the manual mode. Further, in the patrol mode or the manual mode, when an operation of designating a target is performed on the image display area 202 (for example, an operation of the finger 212 in FIG. 17), the drone 30 switches to the tracking mode of tracking the target. You can Further, in the manual mode, if the operation button 203 is not operated for a certain period of time or longer, the drone 30 may switch to the patrol mode.

Further, in the tracking mode, when an operation of designating another target is performed on the image display area 202, the drone 30 may be in the tracking mode in which the another target is tracked. Also, in tracking mode, if the drone 30 loses sight of the target, the drone 30 may switch to manual mode or patrol mode.

Next, an example of the processing in the security system 1 shown in FIG. 15 will be described with reference to the sequence chart shown in FIG.

The drone 30 stream-transmits video and audio to the mobile terminal 70 (S900). The mobile terminal 70 receives this video and displays it in the video display area 202 of the drone UI 200. Note that the drone 30 may stream the video to the mobile terminal 70 while it is connected to the mobile terminal 70.

The drone 30 in patrol mode patrols a predetermined route (S901). When the drone 30 is in the patrol mode, the mobile terminal 70 displays the “patrol mode” in the mode display area 201 of the drone UI 200 as shown in FIG. 16 (S902).

As shown in FIG. 16, when the police officer operates the operation button 203 of the drone UI 200 (S903), the mobile terminal 70 transmits an operation command including the operation content to the drone 30 (S904).

Upon receiving the operation command of S904, the drone 30 switches to the manual mode and moves according to the operation command (S905). When the drone 30 is in the manual mode, the mobile terminal 70 displays the “manual mode” in the mode display area 201 of the drone UI 200 as shown in FIG. 17 (S906).

As shown in FIG. 17, when a police officer performs an operation of designating a target in the video display area 202 of the drone UI 200 (S907), the mobile terminal 70 performs tracking including target information regarding the designated target. The command is transmitted to the drone 30 (S908). The target information may include coordinates of the designated target on the video display area 202. Alternatively, the target information may include characteristics (color, shape, etc.) of the image of the designated target.

Upon receiving the tracking command in S908, the drone 30 switches to the tracking mode. Then, the drone 30 uses the target information included in the tracking command to identify the target from the video being captured, and tracks the identified target (S909). When the drone 30 is in the tracking mode, the mobile terminal 70 displays the “tracking mode” in the mode display area 201 of the drone UI 200 as shown in FIG. 18 (S910). Note that the drone 30 may start recording drone recording data by using the reception of the tracking command as a trigger.

If the target loses the specified target from the video being shot (S911), such as when the target has moved out of the video being shot or has entered the building (S911), the drone 30 notifies the mobile device that additional recording is not possible. 70 (S912), and the mode is switched to the manual mode.

When the mobile terminal 70 receives the tracking-disabled notification in S912, the mobile terminal 70 displays "manual mode" in the mode display area 201 of the drone UI 200 (S913).

As described above, the operation of the drone 30 is switched to the patrol mode, the manual mode, or the tracking mode according to the operation from the mobile terminal 70. Thereby, the police officer can easily monitor and track the target using the drone 30 by appropriately switching the mode of the drone 30. The current mode of the drone 30 is displayed on the drone UI 200 of the mobile terminal 70. This allows the police officer to know which mode the drone 30 is currently in.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the functions of the above-described devices such as the BWC 10, the ICV 20, the drone 30, the center server 40, the PC 50, and the mobile terminal 70 are realized by a computer program. Can be done.

The present disclosure can be realized by software, hardware, or software that is linked with hardware.

Each functional block used in the description of the above embodiments is partially or wholly realized as an LSI that is an integrated circuit, and each process described in the above embodiments is partially or wholly It may be controlled by one LSI or a combination of LSIs. The LSI may be composed of individual chips, or may be composed of one chip so as to include some or all of the functional blocks. The LSI may include data input and output. The LSI may be referred to as an IC, a system LSI, a super LSI, or an ultra LSI depending on the degree of integration.

The method of circuit integration is not limited to LSI, and may be realized by a dedicated circuit, a general-purpose processor, or a dedicated processor. A field programmable gate array (FPGA) that can be programmed after the LSI is manufactured, or a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used. The present disclosure may be implemented as digital or analog processing.

Furthermore, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. The application of biotechnology is possible.

The communication includes not only data communication using a cellular system, a wireless LAN system, a communication satellite system, etc., but also data communication using a combination thereof.

One aspect of the present disclosure is useful for security systems.

1 Security system 10 BWC (Body-Worn Camera)
20 ICV (In Car Video System)
30 Drone 40 Center server 50 PC
60 LPR (License Plate Recognition) camera 70 Mobile terminal

Claims (6)

An unmanned aerial vehicle that can operate in multiple different modes and that transmits the images captured by the camera,
A terminal for displaying a video transmitted from the unmanned aerial vehicle, information on the mode in the unmanned aerial vehicle, and a UI (User Interface) having an operation interface for the unmanned aerial vehicle;
Security system with The unmanned aerial vehicle is
When the operation interface is operated, it is switched to a manual mode which operates according to the operation,
When a position for the image is designated, the mode is switched to a tracking mode for tracking the target imaged at the position,
The security system according to claim 1. The unmanned aerial vehicle, in the tracking mode, if it loses sight of the target from within the video, sends a notification to the terminal indicating that it has lost sight of the target, and switches to the manual mode.
The security system according to claim 2. The unmanned aerial vehicle records the footage during the tracking mode,
The security system according to claim 2. The unmanned aerial vehicle, in the manual mode, switches to a patrol mode of patrol a predetermined route when the operation interface is not operated for a predetermined time or longer,
The security system according to claim 2. An unmanned aerial vehicle that can operate in several different modes transmits the video captured by the camera,
The terminal displays a video transmitted from the unmanned aerial vehicle, information on the mode in the unmanned aerial vehicle, and a UI (User Interface) having an operation interface for the unmanned aerial vehicle,
Security method.

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