Certain exemplary embodiments can provide a system, machine, device, manufacture, circuit, composition of matter, and/or user interface adapted for and/or resulting from, and/or a method and/or machine-readable medium comprising machine-implementable instructions for, activities that can comprise and/or relate to, via a device comprising an electro-active lens, automatically acquiring at least two images of a scene.

The present disclosure provides a method for calculating a focusing evaluation value. The method may be applied in a scene having a dynamic light source and include: dividing an image region of a camera into a plurality of sub-regions; selecting a first sub-region which is affected by a dynamic light source from the plurality of sub-regions; correcting a focusing evaluation value of the first sub-region with the focusing evaluation value of each of sub-regions adjacent to the first sub-region; and calculating a focusing evaluation value of the whole image region based on the focusing evaluation value of each of the sub-regions. The present disclosure improves the performance of auto-focusing in a scene having a dynamic light source.

An electronic apparatus determines that only a first touch operation moved by a predetermined movement amount in a predetermined time period is a valid operation, and determines that another touch operation is an invalid operation, when a user captures an image while looking into a finder. Then, even when a movement amount by which the touch determined to be the valid operation once is moved in the predetermined time period falls below the predetermined movement amount, the electronic apparatus continuously determines that this touch is the valid operation. Even when a Touch-Up is performed regarding the touch determined to be the valid operation, the electronic apparatus continuously determines that the touch determined to be the invalid operation is the invalid operation.

A multi-focal length range image capturing device including a device body, an image capturing circuit, and a processing circuit is provided. The image capturing circuit performs image capturing based on a focal length setting value and generates an image signal. The processing circuit controls the image capturing circuit to be operated in one of plural image capturing modes. When the image capturing circuit is operated in a first image capturing mode, the image capturing circuit sets a focal length range thereof to a first preset focal length range, so as to select the focal length setting value within the first preset focal length range. When the image capturing circuit is operated in a second image capturing mode, the image capturing circuit sets the focal length range to a second preset focal length range, so as to select the focal length setting value within the second preset focal length range.

An image pickup apparatus includes a focus adjustment unit, an image sensor, a focus evaluation value calculation unit, and a control unit configured to drive the focus adjustment unit based on a focus evaluation value to perform an in-focus operation. A change curve representing a change amount of a focus evaluation value indicating a focusing state of an object image includes a first slope before inversion of a sign of an inclination of the change curve at a peak value on the change curve and a second slope after inversion of a sign of an inclination of the change curve at a peak value on the change curve. The control unit determines whether the focus evaluation value corresponding to the peak value on the change curve is used for the in-focus operation based on an inclination of the first slope and an inclination of the second slope.

Spatial resolution can be improved in multi-lens digital cameras. Each lens can have the same or similar field of view, but can be associated with different modulation transfer functions defining varying sharpness based on location within the field of view. The image information received from each lens can be combined to form an image based on the sharpness of the image information received from each lens.

A focus estimating device has an area setting unit which sets an area in which focusing of an image is determined and divides the area into a plurality of blocks, a block selecting unit which selects a block to be used for focus determination, a block focus determination unit which performs focus determination for each block from an edge in each color component of the block selected by the block selecting unit, and a focus determination unit which determines focusing of the area based on the focus determination.

The endoscope apparatus includes a focus control section that performs a focus control process that controls a plurality of in-focus object plane position, the plurality of in-focus object plane positions being set discretely, a switch control section that switches the focus control process between an autofocus control process and a manual focus control process, and an operation section that is operated by a user, when the operation section has been operated by the user during a period in which the focus control section performs the autofocus control process, the switch control section switching the focus control process from the autofocus control process to the manual focus control process, and the focus control section moving the in-focus object plane position to an in-focus object plane position among the plurality of in-focus object plane positions that differs from the in-focus object plane position when the operation section has been operated.

Methods, apparatuses, systems and software for focusing a camera are disclosed. The camera focusing system includes a distance measuring device, a video receiver that receives video/images, a graphics overlay unit, and a monitor. The distance measuring device includes an emitter that emits a radiation beam, a detector that detects reflected radiation, and logic that determines and processes distance information for subject(s) or object(s) in detection zones from the reflections. The graphics overlay unit receives video/image information from the video receiver and the distance information from the distance measuring device, and includes a video overlay and data processing unit that generates graphics indicating a field of detection and position for each detection zone and a direction and/or magnitude of a change in focus setting(s) to bring subjects or objects within each detection zone into focus. The monitor displays the video/image and the graphics overlaid thereon.

Disclosed is a camera module including a substrate which is provided with an electrode pad and an image sensor; a housing which is stacked on the substrate and of which an upper portion is opened so that light is incident to the image sensor; a MEMS actuator which is installed at the housing and has an electrode terminal at one side thereof, and a conductive pattern which is formed at the housing, wherein a lower end of the conductive pattern is connected with the electrode pad of the substrate, and an upper end thereof is connected with the electrode terminal of the MEMS actuator, whereby it is possible to improve electrical reliability between the electrode terminal of the MEMS actuator and the electrode pad of the substrate and facilely form the electrical connection therebetween, thereby reducing the number of processes.