KR102256471B1 - Surveillance system and operating method for the same - Google Patents

Abstract

In the monitoring system including a battery camera and a gateway according to an embodiment for solving the problem to be solved by the present invention, the battery camera, a battery that supplies power to the inside, and acquires an image by photographing a monitoring area. When the camera module, a connector for direct connection with the gateway, a network module for performing communication with the gateway, and the connector are connected to the gateway, the battery camera is operated in a charging mode, and the connector is connected to the gateway. When separated, it includes a processor for operating the battery camera in a normal mode, and in the charging mode, the battery receives power from the gateway through the connector, and the camera module transmits the image through the connector. It transmits continuously to the gateway, and in the normal mode, the camera module discontinuously transmits the image to the gateway through the network module.

Description

Surveillance system and operating method for the same}

The present invention relates to a monitoring system and a method of operation thereof.

In recent years, cameras are increasingly installed inside, outside, or on the street for various purposes such as crime prevention and security. Cameras may be connected to each other through a network to perform a function as a network camera.

In addition, the manager who manages the place where the camera is installed can access the camera through a personal computer or the like and remotely manage a remote location such as a building or a store.

Meanwhile, in order to expand the surveillance area without increasing the number of cameras, it is necessary to change the camera installation location. At this time, it is also necessary to supply power to the camera.

Korean Patent Publication No. 717171

A problem to be solved by the present invention is to provide a monitoring system in which a user can freely select a monitoring area and an operation method thereof.

In the monitoring system including a battery camera and a gateway according to an embodiment for solving the problem to be solved by the present invention, the battery camera, a battery that supplies power to the inside, and acquires an image by photographing a monitoring area. When the camera module, a connector for direct connection with the gateway, a network module for performing communication with the gateway, and the connector are connected to the gateway, the battery camera is operated in a charging mode, and the connector is connected to the gateway. When separated, it includes a processor for operating the battery camera in a normal mode, and in the charging mode, the battery receives power from the gateway through the connector, and the camera module transmits the image through the connector. It transmits continuously to the gateway, and in the normal mode, the camera module discontinuously transmits the image to the gateway through the network module.

In this embodiment, further comprising a sensing module for detecting an event, in the charging mode, the camera module transmits the image to the gateway in a real-time streaming method, and in the normal mode, the camera module is the sensing module The image can be transmitted to the gateway only when the event is detected by.

In this embodiment, the battery includes a rechargeable battery and a non-rechargeable battery, and in the charging mode, the rechargeable battery supplies power to the inside while receiving power from the gateway through the connector, and in the normal mode , The non-rechargeable battery may supply power to the inside.

In this embodiment, in the charging mode, the camera module acquires a high-definition image, in the normal mode, the camera module acquires a low-quality image, and the high-definition image is a frame rate than the low-quality image, At least one of resolution and bitrate may be high.

In this embodiment, the connector includes a magnet, and may be directly connected to the gateway by an attractive force with a magnet provided in the gateway.

In a monitoring system including a battery camera and a gateway according to an embodiment for solving the problem to be solved by the present invention, the gateway includes a memory, a charging module for supplying power to the outside, and directly with the battery camera. A connector to be connected, a network module for performing communication with the battery camera, and when the connector is connected to the battery camera, the gateway is operated in a charging mode, and when the connector is separated from the battery camera, the gateway And a processor operating in a normal mode, wherein in the charging mode, the charging module supplies power to the battery camera through the connector, and the memory continuously receives an image from the battery camera through the connector. And, in the normal mode, the memory discontinuously receives and stores an image from the battery camera through the network module.

In this embodiment, a panning module that rotates left and right may be further included, and the processor may activate the panning module in the charging mode.

In this embodiment, the processor may rotate the panning module at a predetermined speed.

In this embodiment, the processor may rotate the panning module according to a control signal received through the network module.

In this embodiment, the control signal may be an event detection signal of the battery camera.

In this embodiment, the network module may communicate with an internal network device different from the battery camera, and the control signal may be an event detection signal of the internal network device.

In this embodiment, the network module may communicate with a user terminal through an external network, and the control signal may be a signal corresponding to a user input of the user terminal.

In this embodiment, in the charging mode, the memory stores the image received in a real-time streaming method through the connector, and the image is a high-definition image, and in the normal mode, the image is a low-quality image, and the high-definition image An image may have at least one of a frame rate, a resolution, and a bitrate higher than that of the low-quality image.

In this embodiment, the connector includes a magnet, and may be directly connected to the battery camera by an attractive force with a magnet provided in the battery camera.

In the operating method of a monitoring system including a battery camera and a gateway according to an embodiment for solving the problem to be solved by the present invention, the step of connecting a first connector of the battery camera and a second connector of the gateway, Operating the battery camera and the gateway in a charging mode, separating the first connector and the second connector, and operating the battery camera and the gateway in a normal mode, wherein in the charging mode , Power is supplied to the battery camera from the gateway through the first connector and the second connector, the panning module of the gateway is activated, and in the normal mode, the panning module of the gateway is deactivated.

In this embodiment, in the charging mode, the image acquired by the battery camera is continuously transmitted from the battery camera to the gateway through the first connector and the second connector, and in the normal mode, the battery camera The image acquired by the battery camera may be discontinuously transmitted from the battery camera to the gateway through the first network module of and the second network module of the gateway.

In this embodiment, in the charging mode, the panning module may rotate at a predetermined speed.

In this embodiment, in the charging mode, the panning module includes a first event detection signal received from the battery camera, a second event detection signal received from an internal network device different from the battery camera, and a user received from a user terminal. It can rotate in response to at least one of the inputs.

In this embodiment, the gateway receives the first event detection signal from the battery camera through the second connector, receives the second event detection signal from the internal network device through a network module, and the network module The user input may be received from the user terminal through via.

In this embodiment, when the first connector and the second connector are connected, the battery camera may rotate in response to the rotation of the panning module.

According to embodiments of the present invention, a user can freely select a surveillance area by moving a camera constituting a surveillance system.

In addition, since the surveillance area can be expanded using a limited number of cameras, it is more economical.

In addition, by simply charging the battery of the camera, it is possible to supply power to the camera easily and continuously.

In addition, by charging the battery of the camera and receiving a high-quality video from the camera at the same time, monitoring can be further enhanced.

1 is a diagram for describing a monitoring system according to an exemplary embodiment.
2 is a block diagram showing the configuration of a portable battery camera 100a included in a monitoring system according to an exemplary embodiment.
3 is a block diagram showing the configuration of a battery 101 included in the mobile battery camera 100a according to an exemplary embodiment.
4A and 4B are diagrams for explaining the configuration of a mobile battery camera 100a according to an exemplary embodiment.
5 is a block diagram showing the configuration of the gateway 200 included in the monitoring system according to an embodiment.
6 is a diagram illustrating a configuration of a gateway 200 according to an embodiment.
7 is a flowchart illustrating a method of operating the portable battery camera 100a according to an exemplary embodiment.
8 is a flowchart illustrating a method of operating a monitoring system according to an exemplary embodiment.
9A and 9B are diagrams for explaining a panning operation of the gateway 200 according to an exemplary embodiment.

Since the present invention can apply various transformations and have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In the following embodiments, terms such as first and second may be used to describe various elements, but the elements should not be limited by terms. The terms are used only for the purpose of distinguishing one component from other components.

The terms used in the following examples are used only to describe specific examples, and are not intended to limit the present invention. Singular expressions include multiple expressions unless the context clearly indicates otherwise. In the following examples, terms such as "comprises" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more It is to be understood that other features or possibilities of the presence or addition of numbers, steps, actions, components, parts, or combinations thereof are not preliminarily excluded.

Embodiments of the present invention may be represented by functional block configurations and various processing steps. These functional blocks may be implemented with various numbers of hardware or/and software configurations that perform specific functions. For example, embodiments of the present invention can directly control one or more microprocessors or execute various functions by other control devices, such as memory, processing, logic, and look-up tables. Circuit configurations can be employed. Similar to how the components of an embodiment of the present invention can be implemented with software programming or software elements, an embodiment of the present invention includes various algorithms implemented with a combination of data structures, processes, routines or other programming components. , C, C++, Java, assembler (assembler), such as programming or scripting language. Functional aspects can be implemented with an algorithm running on one or more processors. Further, embodiments of the present invention may employ conventional techniques for electronic environment setting, signal processing, and/or data processing. Terms such as mechanism, element, means, and configuration may be widely used, and are not limited to mechanical and physical configurations. The term may include a meaning of a series of routines of software in connection with a processor or the like.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram for describing a monitoring system according to an exemplary embodiment.

Referring to FIG. 1, the monitoring system 10 includes an internal network device 100, a gateway 200, an external network 300, a server 400, and a user terminal 500.

When the information of the internal network device 100 collected by the gateway 200 is transmitted to the server 400 through the external network 300, the monitoring system 10 uses the user terminal 500 to the server ( 400) can provide a configuration to monitor the transmitted information.

One or more internal network devices 100 may be provided. The internal network device 100 may include, but is not limited to, a mobile battery camera 100a, a fixed battery camera 100b, and a sensor 100n.

The mobile battery camera 100a and the fixed battery camera 100b may each capture a surveillance area to obtain an image of the surveillance area. The mobile battery camera 100a and the fixed battery camera 100b may capture a surveillance area in real time for monitoring or security purposes.

The monitoring area of the mobile battery camera 100a may be changed according to the installation location of the mobile battery camera 100a. For example, the mobile battery camera 100a placed on a flat floor may continuously photograph a predetermined surveillance area. The mobile battery camera 100a placed on the upper part of the gateway 200 may horizontally photograph the surveillance area while rotating left and right as the upper part of the gateway 200 rotates. The mobile battery camera 100a installed on the wall or ceiling by the fixed module may photograph a predetermined monitoring area at a predetermined angle.

Meanwhile, the mobile battery camera 100a may be a zoom camera in which a zoom magnification of a lens is adjustable. The mobile battery camera 100a may enlarge or reduce the surveillance area by adjusting the zoom magnification of the lens.

The mobile battery camera 100a may be a battery-powered low-power camera. The mobile battery camera 100a may operate in a normal mode or a charging mode depending on whether the battery is charged. The mobile battery camera 100a may include a rechargeable battery 1011 (FIG. 3) and a non-rechargeable battery 1012 (FIG. 3). In the charging mode, the rechargeable battery 1011 (FIG. 3) may be charged by power supplied from the gateway 200. In the normal mode, at least one of the rechargeable battery 1011 (FIG. 3) and the non-rechargeable battery 1012 (FIG. 3) may be consumed.

In the normal mode, the mobile battery camera 100a may normally maintain a sleep mode and periodically wake up to check whether an event has occurred. When an event occurs, the mobile battery camera 100a may switch to an active mode to acquire an image, and when an event does not occur, the mobile battery camera 100a may return to the sleep mode again. Accordingly, the mobile battery camera 100a operating in the normal mode may obtain images discontinuously.

In the charging mode, the mobile battery camera 100a may acquire an image regardless of whether an event has occurred. In other words, the mobile battery camera 100a operating in the charging mode may continuously acquire images. In this case, the mobile battery camera 100a operating in the charging mode may acquire an image in real time.

The image acquired by the mobile battery camera 100a operating in the normal mode may be a low-quality image, and the image acquired by the mobile battery camera 100a operating in the charging mode may be a high quality image. The high-definition image may be an image having a higher frame rate, resolution, and bitrate than the low-definition image.

As described above, when the mobile battery camera 100a is charging the battery, surveillance may be further enhanced by obtaining a high-definition image from the mobile battery camera 100a. When the battery charging of the mobile battery camera 100a is stopped, power consumption can be reduced by maintaining the active mode of the mobile battery camera 100a only when an event occurs.

The monitoring area of the fixed battery camera 100b may be constant. For example, the fixed battery camera 100b installed on the wall or ceiling by the fixed module may photograph a predetermined surveillance area at a predetermined angle.

The fixed battery camera 100b may be a Pan Tilt Zoom (PTZ) camera in which panning and tilting are possible, and a zoom magnification of a lens is adjustable. The fixed battery camera 100b may change the surveillance area as it is panned or tilted. In addition, the fixed battery camera 100b may enlarge or reduce the surveillance area by adjusting the zoom magnification of the lens.

The fixed battery camera 100b may be a battery-powered low-power camera. The fixed battery camera 100b may normally maintain the sleep mode and periodically wake up to check whether an event has occurred. The fixed battery camera 100b may switch to an active mode when an event occurs, and may return to a sleep mode when an event does not occur. In this way, the fixed battery camera 100b can reduce power consumption by maintaining the active mode only when an event occurs.

The sensor 100n detects a change in the sensing area. The sensing area may mean an area other than a surveillance area that is respectively photographed by the mobile battery camera 100a and the fixed battery camera 100b. The sensing area may include a surveillance area photographed by the mobile battery camera 100a and the stationary battery camera 100b and areas other than the surveillance area. The sensor 100n may detect in real time whether an event occurs in the sensing area for monitoring or security purposes. When an event occurs, the sensor 100n may generate an event detection signal and transmit it to the gateway 200.

The sensor 100n may include an infrared sensor, an audio sensor, a motion sensor, a gas sensor, a leak sensor, a temperature sensor, a humidity sensor, an acceleration sensor, a gyro sensor, a tactile sensor, a pressure sensor, a vibration sensor, and the like.

The internal network device 100 is another internal network device using various communication methods such as wired and wireless LAN (Local Area Network), Wi-Fi, ZigBee, Bluetooth, and Near Field Communication. It is possible to communicate with at least one of 100 and the gateway 200. For example, the internal network device 100 may communicate with the gateway 200 according to a low-power wireless communication protocol using a radio frequency of an Industrial Scientific Medical band (ISM).

The gateway 200 may be connected to the internal network device 100 by wire or wirelessly. Accordingly, the gateway 200 may recognize the state of the internal network device 100 based on the information transmitted from the internal network device 100, and the internal network device 100 ) Or, a command or notification may be transmitted to the user terminal 500.

The gateway 200 may supply power to the internal network device 100 such as the mobile battery camera 100a.

The gateway 200 may transmit information to the server 400 using various wired/wireless communication methods such as Ethernet, Wi-Fi, and Bluetooth, or may receive a command from the server 400.

The external network 300 may include a wired network or a wireless network. The wireless network may be a 2G (Generation) or 3G cellular communication system, a 3rd Generation Partnership Project (3GPP), a 4G communication system, a Long-Term Evolution (LTE), a World Interoperability for Microwave Access (WiMAX), or the like.

The server 400 may transmit a notification to the user terminal 500 based on information transmitted from the gateway 200 through the external network 300. For example, the server 400 may transmit a risk detection alarm to the user terminal 500 based on information on an event detected by the sensor 100n and information on an image acquired by the mobile battery camera 100a. .

The server 400 may transmit a command transmitted from the user terminal 500 to the gateway 200 through the external network 300. For example, the server 400 may transmit a command to sound a siren included in the internal network device 100 to the gateway 200.

The user terminal 500 may display and store information transmitted from the server 400. For example, the user terminal 500 may display a notification transmitted from the server 400. The user terminal 500 may include at least one or more processors. The user terminal 500 may be driven in a form included in another hardware device such as a microprocessor or a general-purpose computer system. The user terminal 500 may be a personal computer or a mobile terminal.

Hereinafter, the mobile battery camera 100a constituting the monitoring system will be described in detail with reference to FIGS. 2, 3, 4A and 4B.

2 is a block diagram showing the configuration of a portable battery camera 100a included in a monitoring system according to an exemplary embodiment.

3 is a block diagram showing the configuration of a battery 101 included in the mobile battery camera 100a according to an exemplary embodiment.

4A and 4B are diagrams for explaining the configuration of a mobile battery camera 100a according to an exemplary embodiment.

1 and 2, the mobile battery camera 100a includes a battery 101, a sensing module 102, a camera module 103, a first connector 104, a first network module 105, and a first It includes a processor 106 and an encoder 107.

In the monitoring system 10 including the mobile battery camera 100a and the gateway 200, the mobile battery camera 100a includes a battery 101 that supplies power to the inside, and a camera that captures an image by photographing a monitoring area. The module 103, a first connector 104 for direct connection with the gateway 200, a first network module 105 for performing communication with the gateway 200, and the first connector 104 are provided with a gateway ( When connected to 200), the mobile battery camera 100a is operated in the charging mode, and when the first connector 104 is separated from the gateway 200, the mobile battery camera 100a is operated in the normal mode. Includes (106). In the charging mode, the battery 101 receives power from the gateway 200 through the first connector 104, and the camera module 103 continuously transmits the image to the gateway 200 through the first connector 104. And, in the normal mode, the camera module 103 discontinuously transmits the image to the gateway 200 through the first network module 105.

The battery 101 supplies power to the inside of the mobile battery camera 100a.

For example, when the mobile battery camera 100a operates in the sleep mode, the battery 101 supplies power to at least one of the sensing module 102, the first network module 105, and the first processor 106. Can supply. The battery 101 is a sensing module 102, a camera module 103, a first connector 104, a first network module 105, and a first when the mobile battery camera 100a operates in an active mode or a charging mode. 1 Power may be supplied to at least one of the processor 106 and the encoder 107.

1 and 3, the battery 101 of the mobile battery camera 100a includes at least one of a rechargeable battery 1011 and a non-rechargeable battery 1012.

The rechargeable battery 1011 may be charged by power supplied from the outside. When the first connector 104 is connected to the gateway 200, the rechargeable battery 1011 may receive power from the gateway 200 through the first connector 104. The rechargeable battery 1011 may be charged more than once. The rechargeable battery 1011 can be replaced.

The rechargeable battery 1011 may supply power to the inside of the mobile battery camera 100a when the first connector 104 is connected to the gateway 200. That is, the mobile battery camera 100a may receive power from the rechargeable battery 1011 in the charging mode.

The rechargeable battery 1011 may supply power to the inside of the mobile battery camera 100a when the first connector 104 is separated from the gateway 200. The rechargeable battery 1011 may supply power to the inside of the mobile battery camera 100a when the first connector 104 is separated from the gateway 200 and the remaining battery capacity of the non-rechargeable battery 1012 is less than the reference remaining amount.

The non-rechargeable battery 1012 can be replaced.

The non-rechargeable battery 1012 may supply power to the inside of the portable battery camera 100a when the first connector 104 is separated from the gateway 200. That is, the mobile battery camera 100a may receive power from the non-rechargeable battery 1012 in the normal mode.

The non-rechargeable battery 1012 may supply power to the inside of the mobile battery camera 100a when the first connector 104 is separated from the gateway 200 and the remaining battery capacity of the rechargeable battery 1011 is less than the reference remaining amount.

Referring back to FIGS. 1 and 2, the sensing module 102 detects an event. The sensing module 102 may include an infrared sensor, an audio sensor, a motion sensor, a gas sensor, a water leak sensor, a temperature sensor, a humidity sensor, an acceleration sensor, a gyro sensor, a tactile sensor, a pressure sensor, a vibration sensor, and the like. The sensing module 102 may generate an event detection signal when an event is detected.

The camera module 103 acquires an image by capturing a surveillance area.

In the charging mode, the camera module 103 may acquire a high-quality image, and in the normal mode, the camera module 103 may acquire a low-quality image.

Meanwhile, in the normal mode, the camera module 103 captures an image only when an event is detected by the sensing module 102, and in the charging mode, the camera module 103 continuously captures an image regardless of whether an event is detected. I can.

Accordingly, in the normal mode, the camera module 103 transmits an image to the gateway 200 only when an event is detected by the sensing module 102, and the camera module 103 transmits the image to the gateway 200 in the charging mode. ) Can be transmitted in a real-time streaming method.

The camera module 103 may be formed of an image sensor such as a Charge-Coupled Device (CCD) sensor and a Complementary Metal-Oxide-Semiconductor (CMOS) sensor.

The camera module 103 may zoom in to magnify an object to be photographed. For example, when an event is detected in the surveillance area by the sensing module 102, the camera module 103 may zoom in toward the object to be photographed.

The camera module 103 may zoom out to enlarge the photographing range. For example, when an event is detected in a sensing area other than the monitoring area by the sensing module 102, the camera module 103 may zoom out.

The first connector 104 is a module for electrically connecting to the gateway 200. For example, the first connector 104 may be electrically connected to the gateway 200 by contacting the second connector 204 (FIG. 5) of the gateway 200. At this time, the first connector 104 includes a magnet, and may be directly connected to the gateway 200 by attractive force with the magnet included in the second connector 204 (FIG. 5) of the gateway 200. Accordingly, not only can the battery charging efficiency be improved, but events occurring in the monitoring area can be more accurately captured by determining the direction of the lens of the portable battery camera 100a located on the gateway 200 in advance.

In the charging mode, not only can the power of the mobile battery camera 100a be charged simply and efficiently through the first connector 104, but also the high-definition image acquired by the mobile battery camera 100a is transmitted in real time to the gateway ( 200), the server 400, or the user terminal 500 can be transmitted to further enhance monitoring.

1, 4A and 4B, the camera module 103 may be located on the side of the cylindrical mobile battery camera 100a. When the user places the mobile battery camera 100a on a flat floor opposite to the monitoring area, the camera module 103 can photograph the monitoring area in front.

The first connector 104 may be located on the lower surface of the cylindrical mobile battery camera 100a. The user contacts the first connector 104 provided on the lower surface of the mobile battery camera 100a to the second connector 204 (FIG. 5) provided on the upper surface of the gateway 200, thereby connecting the mobile battery camera 100a and the gateway. 200 can be electrically connected.

When the first connector 104 and the second connector 204 (FIG. 5) are electrically connected, the operation mode of the mobile battery camera 100a may be switched to the charging mode. That is, the mobile battery camera 100a may charge the battery through the first connector 104 and the second connector 204 (FIG. 5) and transmit a high-definition image to the gateway 200.

The first connector 104 may be a pin type connector. For example, the first connector 104 may be a pogo pin connector. The connection direction of the mobile battery camera 100a on the upper surface of the gateway 200 may be determined according to the shape of the first connector 104, for example, the shape of the pogo pin connector.

The first connector 104 may include magnets M11 and M12. For example, the first connector 104 may include a pair of magnets M11 and M12 on both sides of the pogo pin connector. The first connector 104 may be directly connected to the gateway 200 by an attractive force with the magnets M21 and M22 (FIG. 6) included in the gateway 200. The connection direction of the mobile battery camera 100a on the upper surface of the gateway 200 may be determined according to the shape of the first connector 104, for example, the positions of the magnets M11 and M12.

The portable battery camera 100a may output an alarm when the electrical connection with the gateway 200 is successful. For example, the mobile battery camera 100a may output a beep notifying that it is properly connected to the gateway 200 through a speaker. The portable battery camera 100a may indicate that the electrical connection with the gateway 200 is successful by outputting green light through an alarm lamp. Whether the mobile battery camera 100a and the gateway 200 are properly connected may be determined by whether the connection direction between the mobile battery camera 100a and the gateway 200 coincides with a predetermined connection direction.

When the user places the mobile battery camera 100a on the upper surface of the gateway 200 located opposite the monitoring area, the camera module 103 rotates left and right as the upper part of the gateway 200 rotates to horizontally adjust the monitoring area. 1 and 2, the first network module 105 is a module for performing communication with another internal network device 100 or gateway 200. For example, the first network module 105 may transmit at least one of battery information, event information, and an image of the mobile battery camera 100a to the gateway 200. The battery information may be information related to the remaining amount of the battery. Event information may include an event type, an event detection location, and the like.

In the normal mode, the first network module 105 may discontinuously transmit the image acquired by the camera module 103 to the gateway 200. For example, in the normal mode, the first network module 105 may transmit an image acquired through the camera module 103 to the gateway 200 according to an event detection.

The first network module 105 may receive a command from the gateway 200.

The first network module 105 may perform at least one communication function among wired and wireless LAN (Local Area Network), Wi-Fi, ZigBee, Bluetooth, and Near Field Communication. have.

The first processor 106 controls the overall operation of the portable battery camera 100a.

The first processor 106 may determine an operation mode of the mobile battery camera 100a according to whether the battery is charged.

When the mobile battery camera 100a and the gateway 200 are electrically connected, the first processor 106 operates the mobile battery camera 100a in a charging mode, and the mobile battery camera 100a and the gateway 200 are electrically connected to each other. In the case of separation, the mobile battery camera 100a can be operated in a normal mode.

The first processor 106 may activate the rechargeable battery 1011 in the charging mode and activate the non-rechargeable battery 1012 in the normal mode.

The first processor 106 may activate the rechargeable battery 1011 in the charging mode, and activate the rechargeable battery 1011 or the non-rechargeable battery 1012 based on the remaining amount of the rechargeable battery 1011 in the normal mode. . That is, in the normal mode, the first processor 106 activates the rechargeable battery 1011 when the remaining battery capacity of the rechargeable battery 1011 is greater than or equal to the reference remaining capacity, and when the remaining battery capacity of the rechargeable battery 1011 is less than the reference remaining capacity, The non-rechargeable battery 1011 can be activated.

The first processor 106 may activate the rechargeable battery 1011 in the charging mode and activate the rechargeable battery 1011 or the non-rechargeable battery 1012 based on the remaining battery capacity of the non-rechargeable battery 1012 in the normal mode. have. That is, in the normal mode, the first processor 106 activates the non-rechargeable battery 1012 when the remaining battery capacity of the non-rechargeable battery 1012 is greater than or equal to the reference remaining amount, and the battery remaining amount of the non-rechargeable battery 1012 If it is less than that, the rechargeable battery 1011 may be activated.

Activation of the rechargeable battery 1011 means activation of the charging function and power supply function of the rechargeable battery 1011, and activation of the non-rechargeable battery 1011 means activation of the power supply function of the non-rechargeable battery 1011. I can.

The first processor 106 may control the camera module 103 in the charging mode to continuously acquire a high-definition image, and control the camera module 103 in a normal mode to obtain a low-quality image discontinuously.

The first processor 106 controls the camera module 103 in the charging mode to continuously transmit a high-definition image to the gateway 200 through the first connector 104, and controls the camera module 103 in the normal mode. The low-quality image may be discontinuously transmitted to the gateway 200 through the first network module 105.

The first processor 106 controls the encoder 107 in the charging mode to encode the image acquired through the camera module 103 at a low compression rate, and controls the encoder 107 in the normal mode to control the camera module 103. The image obtained through it can be encoded at a high compression rate.

The encoder 107 encodes an image into a digital signal. The encoder 107 may encode an image at a high compression rate in the normal mode and may encode the image at a low compression rate in the charging mode.

Hereinafter, the gateway 200 constituting the monitoring system will be described in detail with reference to FIGS. 5 and 6.

5 is a block diagram showing the configuration of the gateway 200 included in the monitoring system according to an embodiment.

6 is a diagram illustrating a configuration of a gateway 200 according to an embodiment.

1, 5, and 6, the gateway 200 includes a charging module 201, a panning module 202, a memory 203, a second connector 204, a second network module 205, and A second processor 206, and a user interface 207.

In the monitoring system 10 including the mobile battery camera 100a and the gateway 200, the gateway 200 includes a memory 203, a charging module 201 for supplying power to the outside, and a mobile battery camera 100a. ), a second connector 204 for direct connection with the mobile battery camera 100a, a second network module 205 for performing communication with the mobile battery camera 100a, and the second connector 204 connected to the mobile battery camera 100a. In this case, the gateway 200 operates in a charging mode, and when the second connector 204 is separated from the mobile battery camera 100a, the gateway 200 includes a second processor 206 that operates in a normal mode. . In the charging mode, the charging module 201 supplies power to the mobile battery camera 100a through the second connector 204, and the memory 203 supplies video from the mobile battery camera 100a through the second connector 204. Is continuously received and stored, and in the normal mode, the memory 203 discontinuously receives and stores an image from the mobile battery camera 100a through the second network module 205.

The charging module 201 is a module for supplying power to the outside. The gateway 200 may receive power by wire or may receive power from a built-in large-capacity battery. The charging module 201 may transmit power supplied by the gateway 200 via wire or from a large-capacity battery to the mobile battery camera 100a electrically connected through the second connector 204.

The panning module 202 is a module that rotates left and right. That is, the panning module 202 may rotate clockwise or counterclockwise.

The panning module 202 may be activated in the charging mode and deactivated in the normal mode. The panning module 202 may rotate under the control of the second processor 206 when the second connector 204 and the first connector 104 of the mobile battery camera 100a are electrically connected. For example, in the charging mode, the panning module 202 may continuously rotate at a predetermined speed or periodically rotate at a predetermined speed. The panning module 202 may rotate by a predetermined angle every predetermined time in the charging mode. In this case, the predetermined time and the predetermined angle may be the same or different. The panning module 202 may rotate by a predetermined angle according to a control signal. The control signal may be generated by the second processor 206 or transmitted from the user terminal 500.

The panning module 202 may be located above the gateway 200. When the first connector 104 provided on the lower surface of the portable battery camera 100a and the second connector 204 provided on the upper surface of the gateway 200 are electrically connected, the operation mode of the gateway 200 is changed to the charging mode. Can be converted. As the panning module 202 of the gateway 200 rotates in the charging mode, the mobile battery camera 100a rotates together to capture the surveillance area horizontally.

The memory 203 may store battery information, event information, images, etc. received from the mobile battery camera 100a. The memory 203 may store a control signal generated by the second processor 206 or a control signal transmitted from the user terminal 500.

When the gateway 200 operates in the charging mode, the memory 203 may store a high-definition image of the mobile battery camera 100a received through the second connector 204 in a real-time streaming method. When the gateway 200 operates in the normal mode, the memory 203 may store a low-quality image of the mobile battery camera 100a received through the second network module 205.

The second connector 204 is a module for directly connecting to the mobile battery camera 100a. The second connector 204 is located on the upper surface of the gateway 200 and may contact the first connector 104 located on the lower surface of the mobile battery camera 100a.

Power of the gateway 200 may be supplied to the mobile battery camera 100a through the second connector 204, and a high-definition image of the mobile battery camera 100a may be transmitted to the gateway 200.

The second connector 204 may be a contact terminal capable of being electrically connected to a pin type connector. For example, the second connector 204 may be electrically connected to the mobile battery camera 100a by contacting the pogo pin connector of the mobile battery camera 100a. The connection direction of the battery camera 100a on the upper surface of the gateway 200 may be determined according to the shape of the second connector 204, for example, the shape of the contact terminal.

The second connector 204 may include magnets M21 and M21. For example, the second connector 204 may include a pair of magnets M21 and M21 on both sides of the contact terminal. The second connector 204 may be directly connected to the mobile battery camera 100a by attractive force with the magnets M11 and M12 provided in the mobile battery camera 100a. The connection direction of the mobile battery camera 100a on the upper surface of the gateway 200 may be determined according to the shape of the second connector 204, for example, the positions of the magnets M21 and M21.

The gateway 200 may output an alarm when the electrical connection with the mobile battery camera 100a is successful. For example, the gateway 200 may output a beep notifying that it is properly connected to the mobile battery camera 100a through a speaker. The gateway 200 may indicate that the electrical connection with the mobile battery camera 100a is successful by outputting green light through the alarm lamp.

The second network module 205 is a module for performing communication with the internal network device 100. For example, the second network module 205 may communicate with the mobile battery camera 100a, the fixed battery camera 100b, and the sensor 100n. For example, the second network module 205 may receive at least one of battery information and an event information image from the internal network device 100. The second network module 205 may transmit a command to the internal network device 100.

In addition, the second network module 205 connects the gateway 200 and the external network 300 so that the gateway 200 can connect the internal network device 100 and the user terminal 500. That is, the second network module 205 may communicate with the server 400 or the user terminal 500 through the external network 300. For example, the second network module 205 may receive a command from the server 400 or the user terminal 500 through the external network 300. The second network module 205 may transmit a notification to the user terminal 500 through the server 400.

The second processor 206 controls the overall operation of the gateway 200.

The second processor 206 operates the gateway 200 in a charging mode when the second connector 204 is connected to the mobile battery camera 100a, and the second connector 204 is separated from the mobile battery camera 100a. In this case, the gateway 200 may be operated in a normal mode.

The second processor 206 may perform communication through the second connector 204 or the second network module 205 according to the operation mode of the gateway 200.

When the gateway 200 operates in the charging mode, the second processor 206 controls the charging module 201 to supply power to the mobile battery camera 100a through the second connector 204, and the second connector The high-definition image of the mobile battery camera 100a successively received through the 204 may be stored in the memory 203.

When the gateway 200 operates in the charging mode, the second processor 206 may activate the panning module 202. Activation of the panning module 202 may mean activation of a rotation function of the panning module 202.

In this case, the second processor 206 may rotate the panning module 202 according to the control signal received through the second network module 205. The control signal may be an event detection signal of the mobile battery camera 100a, an event detection signal of another internal network device 100, or a signal corresponding to a user input of the user terminal 500, but is not limited thereto.

That is, the second processor 206 rotates the panning module 202 according to the event detection signal of the mobile battery camera 100a received through the second network module 205, thereby Can be changed. Meanwhile, the second processor 206 may rotate the panning module 202 according to the event detection signal of the mobile battery camera 100a received through the second connector 204.

The second processor 206 changes the monitoring area of the mobile battery camera 100a by rotating the panning module 202 according to the event detection signal of the internal network device 100 received through the second network module 205. I can. In this case, the second processor 206 may receive an event detection signal from the internal network device 100 regardless of whether the second connector 204 and the internal network device 100 are connected.

The second processor 206 may change the monitoring area of the mobile battery camera 100a by rotating the panning module 202 according to a user input of the user terminal 500 received through the external network 300.

The second processor 206 may rotate the panning module 202 at a predetermined speed. The second processor 206 may rotate the panning module 202 continuously or periodically.

The second processor 206 may rotate the panning module 202 in response to the control signal. That is, the second processor 206 may rotate the panning module 202 to face the event detection position included in the control signal. In this case, the panning module 202 may rotate by a predetermined angle so that the lens of the camera module 103 included in the mobile battery camera 100a faces the event detection position under the control of the second processor 206.

Meanwhile, when the gateway 200 operates in the normal mode, the second processor 206 may deactivate the charging module 201 and the panning module 202.

When the gateway 200 operates in the normal mode, the second processor 206 stores the low-quality image of the mobile battery camera 100a discontinuously received through the second network module 205 in the memory 203. I can.

The user interface 207 controls the operation of the gateway 200, registers or deletes the internal network device 100 in the gateway 200, or controls the internal network device 100 through the gateway 200. Can be received.

The user interface 207 may include an input module such as a touch screen, a keypad, and a microphone, and an output module such as a display, a speaker and an alarm lamp.

7 is a flowchart illustrating a method of operating the portable battery camera 100a according to an exemplary embodiment.

1, 2, and 7, when the power is turned on (S101), the mobile battery camera 100a determines whether the rechargeable battery 1011 is charged (S103). The mobile battery camera 100a may determine whether the rechargeable battery 1011 is charged at any time while the power is on.

The rechargeable battery 1011 may be charged by power received from the gateway 200 through the first connector 104.

When the rechargeable battery 1011 is being charged, the mobile battery camera 100a is switched to the charging mode to obtain a high quality image (S105). In step S105, the mobile battery camera 100a may acquire a high-definition image.

In this case, the mobile battery camera 100a connected to the gateway 200 may change the monitoring area left and right according to the panning operation of the panning module 202 of the gateway 200.

When the rechargeable battery 1011 is not being charged, the mobile battery camera 100a is switched to the normal mode and detects an event (S107).

When an event is detected, the mobile battery camera 100a switches from the sleep mode to the active mode to obtain a low-quality image (S109). In step S109, the mobile battery camera 100a may acquire a low-quality image.

In step S109, the mobile battery camera 100a may be switched to the active mode according to not only an event detected by the mobile battery camera 100a itself, but also an event detected by another internal network device 100.

Hereinafter, the operation of the gateway 200 constituting the monitoring system will be described in detail with reference to FIGS. 8, 9A, and 9B.

8 is a flowchart illustrating a method of operating a monitoring system according to an exemplary embodiment.

9A and 9B are diagrams for explaining a panning operation of the gateway 200 according to an exemplary embodiment.

1, 2, 5, and 8, when the first connector 104 of the portable battery camera 100a and the second connector 204 of the gateway 200 are connected (S201), the gateway ( 200) charges the rechargeable battery 1011 of the mobile battery camera 100a through the first connector 104 and the second connector 204 (S203).

That is, when the first connector 104 of the mobile battery camera 100a and the second connector 204 of the gateway 200 are electrically connected, the mobile battery camera 100a and the gateway 200 operate in a charging mode. , Power is supplied from the gateway 200 to the mobile battery camera 100a through the first connector 104 and the second connector 204.

The mobile battery camera 100a operating in the charging mode acquires a high-definition image (S205) and transmits it to the gateway 200 (S207).

In this case, the image acquired by the mobile battery camera 100a may be continuously transmitted from the mobile battery camera 100a to the gateway 200 through the first connector 104 and the second connector 204.

Meanwhile, the panning module 202 of the gateway 200 performs panning according to the control signal (S209). That is, the gateway 200 operating in the charging mode may activate the panning module 202. The control signal may be an event detection signal received from the mobile battery camera 100a.

When a fixed battery camera 100b different from the mobile battery camera 100a detects an event (S211) and transmits an event notification to the gateway 200 (S213), the panning module 202 of the gateway 200 is a fixed battery Panning is performed according to the event detection signal of the camera 100b (S209).

The fixed battery camera 100b may communicate with the gateway 200 through an internal network without being electrically connected to the gateway 200. That is, the fixed battery camera 100b may transmit an event notification to the gateway 200 through an internal network.

At this time, the fixed battery camera 100b acquires a low-quality image according to an event detection (S215), and discontinuously transmits the obtained low-quality image to the gateway 200 (S217).

When the user terminal 500 receives a user input related to the rotation of the panning module 202 of the gateway 200 (S219) and transmits a panning command according to the user input to the gateway 200 (S221), the gateway 200 ), the panning module 202 performs panning according to a user input (S223).

The panning module 202 of the gateway 200 may rotate at a predetermined speed. In this case, the panning module 202 may rotate continuously or periodically. Alternatively, the panning module 202 may temporarily rotate by a predetermined angle according to a control signal. After the panning module 202 rotates by a predetermined angle, when a predetermined time elapses, the panning module 202 may rotate again toward the original direction. For example, the panning module 202 may rotate by a predetermined angle in the clockwise direction and then, when a predetermined time elapses, rotate by a predetermined angle in the counterclockwise direction.

2, 5, 9A, and 9B, the gateway 200 has a mobile battery camera 100a disposed thereon, and the second connector 204 and the mobile battery camera 100a of the gateway 200 When the first connector 104 of) contacts, the panning module 202 can be rotated counterclockwise, for example, and thus the surveillance area of the mobile battery camera 100a can be changed.

As described above, according to embodiments of the present invention, since the mobile battery camera 100a is free to move, unlike the fixed battery camera 100b, the user can freely select a surveillance area using the mobile battery camera 100a.

In addition, according to embodiments of the present invention, since the rechargeable battery 1011 of the mobile battery camera 100a can be charged simply by simply connecting the mobile battery camera 100a with the gateway 200, the mobile battery camera Power can be supplied continuously to (100a).

In addition, according to embodiments of the present invention, by charging the rechargeable battery 1011 of the mobile battery camera 100a and receiving a high-definition image in real time from the mobile battery camera 100a, monitoring may be further enhanced.

Referring back to FIGS. 1, 2, 5, and 8, on the other hand, when the first connector 104 of the portable battery camera 100a and the second connector 204 of the gateway 200 are separated (S225) , The mobile battery camera 100a and the gateway 200 operate in a normal mode, so that power supply to the mobile battery camera 100a through the first connector 104 and the second connector 204 is stopped.

The mobile battery camera 100a operating in the normal mode acquires a low-quality image (S227) and transmits it to the gateway 200 (S229).

At this time, the image acquired by the mobile battery camera 100a is transmitted from the mobile battery camera 100a through the first network module 105 of the mobile battery camera 100a and the second network module 205 of the gateway 200. It may be discontinuously transmitted to the gateway 200.

Meanwhile, the panning module 202 of the gateway 200 operating in the normal mode may be deactivated. That is, the panning module 202 of the gateway 200 may stop rotating.

The gateway 200 operating in the normal mode can communicate with the internal network device 100 through the second network module 205, and the server 400 or the user terminal 500 through the external network 300 And communication.

According to the embodiments of the present invention, when charging of the rechargeable battery 1011 of the mobile battery camera 100a is stopped, limited resources can be efficiently used by receiving a low-quality image only when an event is detected. have.

So far, we have looked at the center of the preferred embodiment for the present invention. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention.

Therefore, the disclosed embodiments should be considered from an explanatory point of view rather than a limiting point of view. The scope of the present invention is shown in the claims rather than the above description, and the invention claimed by the claims and the inventions equivalent to the claimed invention should be construed as being included in the invention.

100: internal network device
100a: portable battery camera
100b: fixed battery camera
100n: sensor
200: gateway
300: external network
400: server
500: user terminal

Claims (20)

In a surveillance system including a battery camera and a gateway,
The battery camera,
A battery that supplies power to the inside;
A camera module for capturing a surveillance area to acquire an image;
A connector for direct connection in contact with the connector of the gateway;
A network module for performing communication with the gateway; And
The battery camera is operated in a charging mode or a normal mode according to a connection state between the connector of the battery camera and the connector of the gateway, and when the connector of the battery camera is connected to the connector of the gateway, the battery camera is set to the charging mode. A processor for operating the battery camera and operating the battery camera in the normal mode when the connector of the battery camera is separated from the connector of the gateway; and
In the charging mode, the battery receives power from the gateway through a connector of the battery camera, and the camera module continuously transmits the image to the gateway through a connector of the battery camera,
In the normal mode, the camera module discontinuously transmits the image to the gateway through the network module. The method of claim 1,
A sensing module for detecting an event; further includes,
In the charging mode, the camera module transmits the video to the gateway in a real-time streaming method,
In the normal mode, the camera module transmits the image to the gateway only when the event is detected by the sensing module. The method of claim 1,
The battery includes a rechargeable battery and a non-rechargeable battery,
In the charging mode, the rechargeable battery supplies power to the inside while receiving power from the gateway through a connector of the battery camera,
In the normal mode, the non-rechargeable battery supplies power to the inside of the monitoring system. The method of claim 1,
In the charging mode, the camera module acquires a high-definition image,
In the normal mode, the camera module acquires a low-quality image,
The high-definition image has at least one of a frame rate, a resolution, and a bitrate higher than that of the low-definition image. The method of claim 1,
The connector of the battery camera includes a magnet, and is directly connected to the gateway by an attractive force with a magnet provided in the connector of the gateway. In a surveillance system including a battery camera and a gateway,
The gateway,
Memory;
A charging module for supplying power to the outside;
A connector for direct connection in contact with the connector of the battery camera;
A network module for performing communication with the battery camera; And
The gateway is operated in a charging mode or a normal mode according to a connection state between the connector of the battery camera and the connector of the gateway, and when the connector of the gateway is connected to the connector of the battery camera, the gateway is operated in a charging mode, When the connector of the gateway is separated from the connector of the battery camera, a processor for operating the gateway in a normal mode; Including,
In the charging mode, the charging module supplies power to the battery camera through a connector of the gateway, and the memory continuously receives and stores an image from the battery camera through a connector of the gateway,
In the normal mode, the memory discontinuously receives and stores an image from the battery camera through the network module. The method of claim 6,
A panning module positioned above the gateway and rotating left and right; further includes,
Wherein the processor activates the panning module in the charging mode. The method of claim 7,
The processor rotates the panning module at a predetermined speed. The method of claim 7,
The processor rotates the panning module according to a control signal received through the network module. The method of claim 9,
The control signal is an event detection signal of the battery camera, monitoring system. The method of claim 9,
The network module,
Communicates with an internal network device different from the battery camera,
The control signal is an event detection signal of the internal network device, a monitoring system. The method of claim 9,
The network module,
Communicates with the user terminal through an external network,
The control signal is a signal corresponding to a user input of the user terminal, the monitoring system. The method of claim 6,
In the charging mode, the memory stores the image received through a real-time streaming method through the connector of the gateway, and the image is a high-definition image,
In the normal mode, the image is a low-quality image,
The high-definition image has at least one of a frame rate, a resolution, and a bitrate higher than that of the low-definition image. The method of claim 6,
The connector of the gateway includes a magnet, and is directly connected to the battery camera by an attraction with a magnet provided in the battery camera. ◈ Claim 15 was abandoned upon payment of the set registration fee.◈ In the method of operating a surveillance system including a battery camera and a gateway,
Operating the battery camera and the gateway in a charging mode when the battery camera and the gateway are directly connected by contacting the first connector of the battery camera with the second connector of the gateway; And
When the first connector and the second connector are separated, operating the battery camera and the gateway in a normal mode; Including,
In the charging mode,
Power is supplied to the battery camera from the gateway through the first connector and the second connector,
The panning module of the gateway is activated, and the battery camera rotates in response to the rotation of the panning module,
In the above normal mode,
The method of operating a monitoring system, wherein the panning module of the gateway is deactivated. ◈ Claim 16 was abandoned upon payment of the set registration fee. The method of claim 15,
In the charging mode,
The image acquired by the battery camera is continuously transmitted from the battery camera to the gateway through the first connector and the second connector,
In the above normal mode,
An operating method of a monitoring system, wherein an image obtained by the battery camera is discontinuously transmitted from the battery camera to the gateway through a first network module of the battery camera and a second network module of the gateway. ◈ Claim 17 was abandoned upon payment of the set registration fee. The method of claim 15,
In the charging mode,
The panning module rotates at a predetermined speed. ◈ Claim 18 was abandoned upon payment of the set registration fee.◈ The method of claim 15,
In the charging mode,
The panning module rotates in response to at least one of a first event detection signal received from the battery camera, a second event detection signal received from an internal network device different from the battery camera, and a user input received from a user terminal, How the surveillance system works. ◈ Claim 19 was abandoned upon payment of the set registration fee.◈ The method of claim 18,
The gateway receives the first event detection signal from the battery camera through the second connector, receives the second event detection signal from the internal network device through a network module, and the user terminal through the network module Receiving the user input from, a method of operating a monitoring system. delete

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