An enclosure for an outdoor smart camera includes an environmentally sealed main housing with a core formed by a hollow heatsink. The heatsink runs through the interior of the housing with openings on either end of the heatsink to allow airflow. Heat emitting electronics inside the sealed main housing are mounted directly to the heatsink to conduct the heat passively through the heatsink to the external environment. The heatsink and main housing can be cut to any desired length to adjust the size of the enclosure and accommodate variable size and quantity of internal components. Mounting slots are included for mounting the enclosure easily to poles and other structures.

A remote surveillance assembly includes a base that is positionable in a vehicle and a pole that is coupled to and extends upwardly from the base. A pan tilt zoom (PTZ) video camera is movably disposed on the pole to capture surveillance of the environment around the vehicle. A pair of articulated arms is each of the articulated arms is movably coupled to the pole. A pair of digital cameras is each coupled to a respective one of the articulated arms to capture surveillance of the environment around the vehicle. A digital video recorder is coupled to the base and a transceiver is coupled to the base. The transceiver is in wireless communication with an extrinsic communication network to broadcast the data stored in the digital video recorder to a remote data storage device.

Oftentimes a site owner requires onsite capture devices (e.g., still or video cameras, microphones) for reasons of security, increasing revenue (e.g., streaming content to subscribed users), or otherwise. In the current state of the art various capture devices come from a variety of vendors and are often only adapted to work with software from the same manufacturer. It can be frustrating for a site owner to attempt to cobble together a capture and distribution system from individual parts and devices. Discussed herein is an approach to producing a capture and distribution system customized to an owner's particular needs and a site's particular characteristics in which capture devices are at least partially factory wired, aimed, and commissioned so to reduce both time on site to install of said capture devices and potential errors in the installation, and in a manner that in at least some cases adds value for the owner.

Provided is a monitoring system and a method of controlling a panning-tilt zoom (PTZ) camera by using a fisheye camera when the fisheye camera and the PTZ camera are adjacently installed. The method includes selecting a region of interest (ROI) in an entire surveillance-target area image captured by the fisheye camera and adjusting a panning angle P and a tilting angle T of the PTZ camera to acquire an accurate image of the selected ROI.

Provided are an image detection device, an image detection method and a program, which are capable of improving correspondence to a target deformation by optimizing a template shape, when performing target detection using template matching. An image detection device 100 for detecting a target from an input image comprises: a template generation unit 10 that generates a template for detecting a target; a mask generation unit 20 that generates a mask which shields a portion of the template, on the basis of temporal variations of a feature point extracted from an area including the image target; and a detection unit 30 that detects the target from the image using the template a portion of which is shielded by the mask.

Techniques are described for using an integrated lightbulb camera system for monitoring a property. The integrated lightbulb camera system can have a housing that includes one or more cameras, a power-line communication (PLC) chip, and one or more processors. The PLC chip can be configured to enable communications between the lightbulb camera system and one or more external devices. The one or more processors can be configured to control the one or more cameras to capture one or more images and control the PLC chip to transmit at least one of the one or more captured images over a power-line to at least one of the one or more external devices. The integrated lightbulb camera can also have a lightbulb compatible screw base that is configured to mount the housing to a lightbulb socket and accept electrical current that is provided to the housing.

An assignment control apparatus includes an assignment device connected to multiple cameras and multiple specialized devices connected to the assignment device and each corresponding to one of preset multiple categories. The assignment device includes multiple determination units connected to the cameras one-to-one and each configured to determine the category of image data received from the camera to which the determination unit is connected, the category being one of the categories, and to output the image data along with category data indicating the determined category. The assignment device also includes an assignment unit configured to output the image data outputted from each specialized device to the specialized device corresponding to the category indicated by the category data outputted along with the image data.

Methods and apparatus, including computer program products, for determining a presence of an object located close to a lens (301) of a camera monitoring a scene. A first infrared illumination source (302) arranged to illuminate the scene from a first angle is activated. A first image (304) is acquired by the image capturing device (300). The first infrared illumination source (302) is deactivated, and a second infrared illumination source (306) arranged to illuminate the scene from a second angle is activated. A second image (308) is acquired by the image capturing device (300). Intensity information of the first image (304) and the second image (308) is compared to determine the presence of an object located close to the lens (301).

To solve the above problem, a monitoring apparatus according to an embodiment of the present invention comprises: a communication unit for receiving an original image acquired by a camera; a storage unit for storing the original image; a screen unit for displaying the original image and a corrected image obtained by dewarping the original image; and a control unit for controlling operations of the communication unit, the storage unit, and the screen unit, wherein the screen unit displays an icon in a dewarping area of the original image where the corrected image is obtained by dewarping the original image, indicates that the dewarping area is selected when the icon located in the dewarping area is selected, and displays a polygon representing the selected dewarping area.

A device receives position information from a sensor of the device, wherein the position information indicates a position of a user of the device and a position of a person proximate to the user. The device receives lighting information from the sensor, wherein the lighting information indicates lighting conditions around the device and the user. The device calculates a position adjustment for an infrared element of the device based on the position information and the lighting information, and calculates an intensity adjustment for the infrared element based on the position information and the lighting information. The device receives, via an input element of the device, input data provided by the user, and implements the position adjustment and the intensity adjustment to enable the infrared element, when illuminated, to reflect light away from the input element and to prevent image or video capture of the input data.