The present application relates to the field of security and protection, and provides a pan-tilt control method, device and system. The method comprises: detecting whether there is a signal source within a monitored region of a pan-tilt camera, the pan-tilt camera comprising a pan-tilt and a camera attached to the pan-tilt; judging, when there is a signal source within the monitored region, whether signals emitted from the signal source are position adjusting signals for indicating a position adjustment on the pan-tilt; and adjusting a position of the pan-tilt according to a position of the signal source when the signals emitted from the signal source are position adjusting signals. In the present application, the trigger delay of the control operation on the pan-tilt camera is reduced.

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.

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.

The present document describes an electronic device with a structural midframe and associated methods. The architectural design of the electronic device (e.g., a security camera) is such that its components are assembled onto the midframe to form a subassembly and the housing is assembled after the subassembly. The midframe includes various features that enable multiple printed circuit boards, a camera subassembly, a front housing member, a heatsink, and a heat spreader to be assembled onto the midframe outside of the housing. The midframe can also include a hinge-bearing surface forming a portion of a ball joint for supporting rotational movement of the electronic device. Accordingly, the electronic device uses the midframe, rather than the housing, as a structural member.

The present document describes a camera device with an adjustable stand. The camera device includes a head assembly and a stand assembly pivotally connected together by a stem forming a hinge. The stem provides a 360-degree range of pan and a 45-degree range of tilt of the head assembly relative to the stand assembly. The stand assembly is rotatably movable relative to the head assembly to configure the camera device in different configuration states, including a tabletop state and a wall state. The tabletop state has a low profile for resting on a horizontal surface, and the wall state has a high profile, which provides additional clearance between the head assembly and a vertical surface to which the stand assembly is affixed. In the wall state, a cable of the camera device can be routed through and constrained by the stand assembly.

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.

Disclosed is a system for deterring criminal activity by providing a visual indication of active surveillance including a time server, a first client device having a first LED and an internal clock, the first client device configured to connect to the time server and synchronize its internal clock with the time server, a second client device having a first LED and an internal clock, the second client device configured to connect to the time server and synchronize its internal clock with the time server, wherein the first client device and the second client device are each configured to be selectively set to a “monitor mode” in which the respective first LEDs of the first client device and the second client device pulse in unison.

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.

This document describes a thermal-control system that is integrated into a security camera. The thermal-control system includes a combination of heatsinks and thermal interface materials with high thermal conductivities. The thermal-control system may transfer and spread energy from a high thermal-loading condition effectuated upon the security camera to concurrently maintain temperatures of multiple thermal zones on or within the security camera at or below prescribed temperature thresholds.

The present document describes an electronic device with a structural midframe and associated methods. The architectural design of the electronic device (e.g., a security camera) is such that its components are assembled onto the midframe to form a subassembly and the housing is assembled after the subassembly. The midframe includes various features that enable multiple printed circuit boards, a camera subassembly, a front housing member, a heatsink, and a heat spreader to be assembled onto the midframe outside of the housing. The midframe can also include a hinge-bearing surface forming a portion of a ball joint for supporting rotational movement of the electronic device. Accordingly, the electronic device uses the midframe, rather than the housing, as a structural member.