The present disclosure relates to systems and methods for determining automatically a target field angle of an image capturing device. The method may include obtaining, by the image capturing device, at least two images for determining a target field angle of the image capturing device. The method may also include obtaining a field angle range of the image capturing device. Further, the method may include determining the target field angle by matching the at least two images based on the field angle range.

An imaging apparatus includes: a display unit configured to display on a display a live image of a subject and previously captured images; an image capturing unit configured to capture an image of the subject; and a recording unit configured to record in a recording medium the captured image of the subject which has been captured by the image capturing unit and the previously captured images in association with disposition information which includes a display position of the captured image of the subject and display positions of the previously captured images.

The present invention relates to a new universal control interface for cameras and other audio-visual recording/using instruments, and more specifically a multi-axis visual interface for simultaneous display and control of aperture (Av), shutter speed (Tv), ISO, and/or other parameters like exposure value (EV). The invention relates to either a triangular, rectangle or clover shape interface where the parameters are visually represented on one of the axis, side or branch of the interface and where the user instead of altering the parameters, will provide intention such as (a) depth-of field, (b) motion blur, (c) granularity, or the composite (d) exposure. The invention further describes how in some cases, one or more of these parameters can be locked or not available based on the technology used for the delay and control interface.

The present invention relates to a new universal control interface for cameras and other audio-visual recording/using instruments, and more specifically a multi-axis visual interface for simultaneous display and control of aperture (Av), shutter speed (Tv), ISO, and/or other parameters like exposure value (EV). The invention relates to either a triangular, rectangle or clover shape interface where the parameters are visually represented on one of the axis, side or branch of the interface and where the user instead of altering the parameters, will provide intention such as (a) depth-of field, (b) motion blur, (c) granularity, or the composite (d) exposure. The invention further describes how in some cases, one or more of these parameters can be locked or not available based on the technology used for the delay and control interface.

An image capturing device includes a first controller operable to control image capturing; an operation section including a switch; a detector operable to detect a change to an image capturing mode and to send a signal representing the change; a second controller operable to monitor and process the sent signal, the second controller having a power consumption less than that of the first controller; and a power supply operable to supply power to the first controller, the second controller, and a functional section of the device. When the second controller receives the signal sent from the detecting section in a power saving state in which power is supplied from the power supply to the second controller, the power saving state is changed to a power supplying state capable of image capturing by supplying power from the power supply to portions of the device including the first controller.

Security guards at big facilities, such as airports, monitor multiple screens that display images from individual surveillance cameras dispersed throughout the facility. If a guard zooms with a particular camera, he will lose image resolution, along with perspective on the surrounding area. Embodiments of the inventive Imaging System for Immersive Surveillance (ISIS) solve these problems by combining multiple cameras in one device. When properly mounted, example ISIS systems offer 360-degree, 100-megapixel views on a single screen. (Other resolutions may also be employed.) Image-stitching software merges multiple video feeds into one scene. The system also allows operators to tag and follow targets, and can monitor restricted areas and sound an alert when intruders breach them.

Examples are disclosed that relate to adapting image output from a camera based on output from an orientation sensor. One example provides a display device comprising a display, a movable mount, a camera having an optical field-of-view, an orientation sensor, and a controller. The controller may be configured to receive image output from the camera, generate, based on the image output, a first clipped field-of-view of the camera comprising a target, and in response to a change in an orientation of the camera identified by output from the orientation sensor, generate, based on the image output and the output from the orientation sensor, a second clipped field-of-view comprising the target, the first and second clipped field-of-views being subsets of the optical field-of-view.

Techniques to selectively capture media using a single user interface element are described. In one embodiment, an apparatus may comprise a touch controller, a visual media capture component, and a storage component. The touch controller may be operative to receive a haptic engagement signal. The visual media capture component may be operative to be configured in a capture mode based on whether a haptic disengagement signal is received by the touch controller before expiration of a first timer, the capture mode one of a photo capture mode or video capture mode, the first timer started in response to receiving the haptic engagement signal, the first timer configured to expire after a first preset duration. The storage component may be operative to store visual media captured by the visual media capture component in the configured capture mode. Other embodiments are described and claimed.

Provided is an electronic device. The electronic device includes: a main body mounted with an electronic unit including a controller, including a bezel disposed at the outer side thereof, and having a locking groove formed in the bezel; and a band part mounted with an additional device for exchanging an electric signal with the electronic unit and an electronic part providing information related to the additional device for the electronic unit, and including a coupling part detachably coupled to the locking groove. Here, the controller switches an operation mode of the main body according to the information related to the additional device provided by the electronic part when the main body and the band part are coupled to each other. Thus, when the band part mounted with the additional device is connected to the main body, the operation mode of the main body is automatically switched to a mode corresponding to the additional device, thereby providing convenience of use.

An image display system includes an image acquisition unit which acquires an image, an area setting unit which sets a plurality of viewing areas to which the image is to be assigned according to a direction of the image, an image assignment unit which assigns the image to each of the plurality of viewing areas, an operation determination unit which discriminates an operation in a first viewing area among the plurality of viewing areas each having the image assigned thereto, and a display control unit which displays the image in the first viewing area and the image in a second viewing area other than the first viewing area among the plurality of viewing areas concurrently based on a result of the discrimination by the operation determination unit.