A method and system for field treatment. The method comprising a data collection unit for collecting data on a portion of a field; an interface for receiving a first parameter to be considered for treatment of said portion of said field and a first probability score threshold for said parameter; a calculation unit for calculating a first probability score of said first parameter in said data collected; and, a treatment unit for treating said portion of the field based on said first probability score for said first parameter and said first threshold.

Provided are a method and an apparatus for detecting fire spots, an electronic device, and a storage medium. In this embodiment of the present application, the target position of a focus lens group is determined based on the minimum object distance and the maximum object distance in a collected image so that collected images based on the target position of the focus lens group can achieve maximum detection clarity. In the detection of a suspected fire spot region, moving the focus lens group from the closest position corresponding to the minimum object distance to the farthest position corresponding to the maximum object distance achieves dimensional movement of the camera lens focus group, which solves the problem of insufficient depth of field of the lens and the inability to cover all fire spots in a multi-object-distance scene.

Provided are a method and an apparatus for detecting fire spots, an electronic device, and a storage medium. In this embodiment of the present application, the target position of a focus lens group is determined based on the minimum object distance and the maximum object distance in a collected image so that collected images based on the target position of the focus lens group can achieve maximum detection clarity. In the detection of a suspected fire spot region, moving the focus lens group from the closest position corresponding to the minimum object distance to the farthest position corresponding to the maximum object distance achieves dimensional movement of the camera lens focus group, which solves the problem of insufficient depth of field of the lens and the inability to cover all fire spots in a multi-object-distance scene.

System and method for identifying a weapon, and tracking and generating an alert in response to the weapon identification are disclosed. The system includes an image capturing unit installed at a structure. The image capturing unit includes an image sensor and an infrared sensor. The infrared sensor identifies weapons being carried by persons or vehicles in its field of view. Concurrently, the image sensor captures and records the images of the person and/or the vehicle. The image capturing unit notifies law enforcement officers of the person and/or the vehicle having the weapons. In one implementation, the image capturing unit connects to an unmanned aerial vehicle (UAV). The UAV deploys and tracks the location after the person and/or the vehicle moves away from the field of view of the image capturing unit. The UAV tracks the person and/or the vehicle until the law enforcement officers capture the person and/or the vehicle.

System and method for identifying a weapon, and tracking and generating an alert in response to the weapon identification are disclosed. The system includes an image capturing unit installed at a structure. The image capturing unit includes an image sensor and an infrared sensor. The infrared sensor identifies weapons being carried by persons or vehicles in its field of view. Concurrently, the image sensor captures and records the images of the person and/or the vehicle. The image capturing unit notifies law enforcement officers of the person and/or the vehicle having the weapons. In one implementation, the image capturing unit connects to an unmanned aerial vehicle (UAV). The UAV deploys and tracks the location after the person and/or the vehicle moves away from the field of view of the image capturing unit. The UAV tracks the person and/or the vehicle until the law enforcement officers capture the person and/or the vehicle.

A thermal imaging system for use with a respirator mask comprising an in-mask display unit, and methods of configuring and operating such a system. The system uses a thermal imaging camera to capture a thermal image. The system is configured with the capability to shift from a default view in which an in-mask micro-display of the in-mask display unit shows a primary subimage of the captured thermal image but does not show a secondary subimage of the captured thermal image, to an auxiliary view in which the secondary subimage is now shown in place of at least a portion of the primary subimage.

A thermal imaging system for use with a respirator mask comprising an in-mask display unit, and methods of configuring and operating such a system. The system uses a thermal imaging camera to capture a thermal image. The system is configured with the capability to shift from a default view in which an in-mask micro-display of the in-mask display unit shows a primary subimage of the captured thermal image but does not show a secondary subimage of the captured thermal image, to an auxiliary view in which the secondary subimage is now shown in place of at least a portion of the primary subimage.

A unit cell inspecting device includes an inspection unit which captures an image of an edge of a unit cell using long-wave infrared rays and measures a position of an edge of an electrode provided in the unit cell. The inspection unit includes: a main heating part configured to heat the edge of the unit cell, thereby raising a temperature of the edge of the electrode provided in the unit cell; and an image capturing part configured to capture the image of the edge of the unit cell by using the long-wave infrared rays, thereby acquiring a thermal image of the edge of the electrode provided in the unit cell; and an inspection part configured to measure the edge of the electrode in the thermal image captured by the image capturing part, thereby measuring the position of the electrode by using the measured edge of the electrode.

A unit cell inspecting device includes an inspection unit which captures an image of an edge of a unit cell using long-wave infrared rays and measures a position of an edge of an electrode provided in the unit cell. The inspection unit includes: a main heating part configured to heat the edge of the unit cell, thereby raising a temperature of the edge of the electrode provided in the unit cell; and an image capturing part configured to capture the image of the edge of the unit cell by using the long-wave infrared rays, thereby acquiring a thermal image of the edge of the electrode provided in the unit cell; and an inspection part configured to measure the edge of the electrode in the thermal image captured by the image capturing part, thereby measuring the position of the electrode by using the measured edge of the electrode.

A remotely-operable portable trail camera includes a processing unit, an image sensor, a zoom lens, and a zoom level detecting and adjusting circuit. A panhead permits the image sensor to be adjusted azimuthally in a left-right direction and elevationally in an upward-downward direction. A panning control circuit controls a motion of the panhead azimuthally in the left-right direction. A tilting control circuit controls a motion of the panhead elevationally in the upward-downward direction. An object detection circuit detects a motion of a target object. In response to the detection of the motion, the processing unit controls the panning control circuit, the tilting control circuit, and the zoom level detecting and adjusting circuit so as to aim the image sensor towards the target object. The panning control circuit, the tilting control circuit, and the zoom level detecting and adjusting circuit are operatively coupled to a cellular transceiver and can be controlled over a cellphone network using an application on a smartphone or other mobile device.