Abstract: A pendant housing for a camera. The housing comprises a substantially cylindrical casing. The substantially cylindrical casing further includes a top end portion that may be removeably mounted to a tube without a tool, a dome structure that may house at least a lens portion of a camera, a bottom end portion that may be removeably mounted to the dome structure without a tool, and a waterproof seal positioned between the bottom end portion and the dome structure.

Abstract: A physical security system that includes multiple server nodes may be upgraded by receiving an upgrade installation package from a client and propagating the installation package between at least two of the server nodes. One of the server nodes (“source server”) receives the installation package from the client and another of the server nodes (“requesting server”) requests and receives the installation package from the source server. To transfer the installation package from the source to the requesting server, the source server notifies the requesting server that the installation package is present at the source server, the requesting server then sends the source server a request for the installation package, and the source server then sends the installation package to the requesting server in response to the request. The requesting server may then be upgraded by running the installation package.

Abstract: A camera system is provided that provides a smooth and centered zoom, even at high levels of magnification. The camera system corrects for misalignment between the optical axis of a lens and center of an image sensor. As a result of the misalignment, the center of an image will move during a zoom movement. The current camera system corrects for the misalignment as the zoom movement occurs. The correction is matched to the speed of the zoom in order to provide a fluid zoom movement.

Abstract: A computer implemented method for managing data received from a video source device is disclosed. At least a first storage tier and a second storage tier on a storage medium are identified for respectively storing different categories of data. As data streams are received from the video source, the data streams are associated with at least the first storage tier or the second storage tier and data from the received streams are stored in the associated storage tier. When the storage medium is full or meets some other specified maximum capacity threshold, data is deleted beginning with data that has an age that exceeds one or more specified maximum retention times, followed by data with the oldest age from one or both of the first and second storage tiers.

Abstract: A mounting housing for a camera includes a surface contacting member and a sliding member that is slidable within an interior conduit within the surface contacting member. The surface contacting member has a back end that is located behind a mounting surface when the mounting housing is mounted and a front end, connected to the back end, that is located in front of the mounting surface when the mounting housing is mounted. A spring is pivotably coupled to and extends outwardly from the back end, and the spring is pivotable to apply force on to a back side of the mounting surface when the mounting housing is mounted. The sliding member is slidable along the interior conduit between mounted and un-mounted positions. The sliding member is lockable in the mounted position to bias the spring against the mounting surface when the mounting housing is mounted.

Abstract: A camera system is provided that provides a smooth and centered zoom, even at high levels of magnification. The camera system corrects for misalignment between the optical axis of a lens and center of an image sensor. As a result of the misalignment, the center of an image will move during a zoom movement. The current camera system corrects for the misalignment as the zoom movement occurs. The correction is matched to the speed of the zoom in order to provide a fluid zoom movement.

Abstract: A method, system and apparatus for image capture, analysis and transmission are provided. A link aggregation method involves identifying controller network ports to a source connected to the same subnetwork; producing packets associating corresponding controller network ports selected by the source CPU for substantially uniform selection; and transmitting the packets to their corresponding network ports. An image analysis method involves producing by a camera an indication whether a region of an image differs by a threshold extent from a corresponding region of a reference image; transmitting the indication and image data to a controller via a communications network; and storing at the controller the image data and the indication in association therewith. The controller may perform operations according to positive indications.

Abstract: A method adjusts an auto exposure target in an auto-exposure operation on a sequence of images, such as a sequence of infrared images. The method comprises: obtaining a histogram of at least one of the images; applying a weighted histogram table to the histogram to obtain weighted histogram bins wherein at least some bins in the histogram containing saturated pixels are assigned a higher weighting value and at least some bins in the histogram containing unsaturated pixels are assigned a lower weighting value, and summing the weighted histogram bins to obtain a saturation score and decreasing an auto exposure target for an auto exposure operation when the saturation score exceeds a first threshold value, and increasing the auto-exposure target when the saturation score is below the first threshold value and the image is underexposed.

Abstract: Methods, systems, and techniques for adjusting camera focus to facilitate infrared imaging are employed to account for a difference in wavelength between visible and infrared light to permit sharp imaging regardless of whether imaging is performed using visible or infrared light. Camera focus is adjusted in accordance with base and offset values. The base value may be determined in accordance with a curve relating focus motor position and object distance and the offset value may be manually set by the user or automatically set by performing an autofocus method when the camera is operating in low light conditions.

Abstract: An articulating camera arm permits a camera to be positioned includes multiple sections connected together in series at joints. At least one of the joints is movable, and each of the joints connects one of the sections to an immediately preceding one of the sections. The articulating arm may also be connected to one or both of a camera and a mounting plate via movable joints such as swivel joints. The arm's interior includes a wiring conduit that allows wiring for the camera to pass through it while being protected by the arm.

Abstract: A method for generating an infrared (IR) beam for illuminating a scene to be imaged comprises providing at least two IR emitters, including a first IR emitter operable to emit a wide beam component of the IR beam, and a second IR emitter operable to emit a narrow beam component of the IR beam, wherein the wide beam component has a linear profile that has a lower standard deviation than a linear profile of the narrow beam component. The method also comprises selecting a desired linear profile for the IR beam, and selecting a power ratio of power directed to the first IR emitter and power directed to the second IR emitter that produces the IR beam with the desired linear profile when the narrow beam component and wide beam component are combined.

Abstract: A pendant housing for a camera. The housing comprises a substantially cylindrical casing. The substantially cylindrical casing further includes a top end portion that may be removeably mounted to a tube without a tool, a dome structure that may house at least a lens portion of a camera, a bottom end portion that may be removeably mounted to the dome structure without a tool, and a waterproof seal positioned between the bottom end portion and the dome structure.

Abstract: A security camera includes a camera head and a cable assembly with an integrated processing module. The camera head contains a lens and an image sensor, while the processing module contains image processing circuitry for processing images obtained using the image sensor and power circuitry used to power the image processing circuitry and the camera head. A cable connects the camera head and the processing module. The processing module is sized to fit through an aperture in a mounting surface that can be covered by the camera head when the camera head is mounted to the mounting surface, which facilitates ease of installation.

Abstract: A security camera with an adjustable lens aiming mechanism comprises a dome base, an eyeball camera, a dome cover, and a fastener for fastening the dome cover to the dome base. The dome base comprises a camera seat. The eyeball camera comprises a lens and is movably seated on the camera seat. The dome cover covers the eyeball camera and comprises a bottom opening for engaging the dome base, a circular contact ring with a diameter smaller than the camera diameter and defining an opening through which the lens and a portion of the camera protrudes; and a fastener removably fastening the dome cover to the dome base such that when fully fastened, the contact ring makes contact with the camera and applies a sufficient pressure to fix the camera in place on the seat, and when partially or completely unfastened, the pressure is reduced such that the camera is movable on the seat and the lens is movable within the contact ring.