A case for portable electronic devices including smartphones includes a feature to prevent glare from a flash from affecting images and video captured by a camera lens and also a battery to extend battery life of the electronic device. Smartphones have telephony, Internet connectivity, and camera and video features. Photos and video can be uploaded through the Internet or sent to other phones. The case has a hole for a camera flash of the smartphone to pass through. The edging of the hole is colored black or another dark color to prevent glare from appearing in the photos or video taken by the smartphone when using the camera flash.

A camera module according to an embodiment of the present invention comprises: a housing which comprises a supporting part and in which the inside space therein is divided by the supporting part into a first space and a second space; an image sensor housed in the first space; a lens unit arranged on the image sensor; a light-outputting unit arranged between the lens unit and the housing; and a light source unit arranged in the second space so as to correspond to the light-outputting unit, wherein the light-outputting unit outputs light incident from the light source unit to the outside.

A case for portable electronic devices including smartphones includes a feature to prevent glare from a flash from affecting images and video captured by a camera lens and also a battery to extend battery life of the electronic device. Smartphones have telephony, Internet connectivity, and camera and video features. Photos and video can be uploaded through the Internet or sent to other phones. The case has a hole for a camera flash of the smartphone to pass through. The edging of the hole is colored black or another dark color to prevent glare from appearing in the photos or video taken by the smartphone when using the camera flash.

A device for image analysis and recording, in particular in an explosion hazard zone, designed for observing, for example, gas meter counters, converting the observed image and transmitting alphanumeric characters converted to discrete form as recorded in the field of view of the camera. The device has inside an aluminum two-part housing of Ex design for explosion hazard zones separate miniaturized infrared light source modules, a CMOS matrix with a microcontroller (22), a single-module SOM-type computer, a power supply circuit, communication and power ports characterized in that it has lenses (25) tightly adhering to the infrared light-emitting diodes (24) and to the glass (2) of the top of the housing (1). These are symmetrically arranged in two lines, intersecting the CMOS sensor with the microcontroller (22) and the lens (23).

A surveillance camera includes a first infrared irradiation portion that irradiates first infrared light, a second infrared irradiation portion that irradiates second infrared light having a narrower irradiation angle than the first infrared light, a camera body including an imaging lens for allowing light to be incident from an irradiation region of at least one of the first and second infrared lights, and a dome cover covering the camera body. The first infrared irradiation portion includes a first light source of the first infrared light and a first pedestal on which the first light source is placed. The second infrared irradiation portion includes a second light source of the second infrared light and a second pedestal on which the second light source is placed. 10 The first light and second sources, which are provided adjacent to a side surface of the camera body, are disposed differently in an up-down direction.

In one embodiment of an enclosure device, a camera casing and light source casing are secured to a plate frame, and the enclosure device is configured to be mounted to an arm, such as a robotic welding arm. A shutter mounting arm may also be secured to the plate frame. A flap may be pivotally mounted to the distal end of the shutter mounting arm, such that the flap may be actuated between a first and second position by an actuator cooperatively engaged with the flap. The first position may be defined as to protect a camera lens positioned in the camera casing and a light source lens positioned in the light source casing. The second position may be defined as to not obscure a line-of-sight from either the light source and/or the camera to the work piece on the arm. A light source casing may be sandwiched between two side plates that are generally configured as mirror images of one another. The light source casing housing a light source may be configured as a laser designed to measure distances,

The present disclosure relates to cantilevered and divergent view wearable optical systems that redirect an optical path, and provide for optimal ergonomics coupled with vision enhancement and vision magnification. Methods of use, devices, and kits are also contemplated.

In one embodiment of an enclosure device, a camera casing and light source casing are secured to a plate frame, and the enclosure device is configured to be mounted to an arm, such as a robotic welding arm. A shutter mounting arm may also be secured to the plate frame. A flap may be pivotally mounted to the distal end of the shutter mounting arm, such that the flap may be actuated between a first and second position by an actuator cooperatively engaged with the flap. The first position may be defined as to protect a camera lens positioned in the camera casing and a light source lens positioned in the light source casing. The second position may be defined as to not obscure a line-of-sight from either the light source and/or the camera to the work piece on the arm.

In one embodiment of an enclosure device, a camera casing and light source casing are secured to a plate frame, and the enclosure device is configured to be mounted to an arm, such as a robotic welding arm. A shutter mounting arm may also be secured to the plate frame. A flap may be pivotally mounted to the distal end of the shutter mounting arm, such that the flap may be actuated between a first and second position by an actuator cooperatively engaged with the flap. The first position may be defined as to protect a camera lens positioned in the camera casing and a light source lens positioned in the light source casing. The second position may be defined as to not obscure a line-of-sight from either the light source and/or the camera to the work piece on the arm. A light source casing may be sandwiched between two side plates that are generally configured as mirror images of one another. The light source casing housing a light source may be configured as a laser designed to measure distances.

A touch panel that can detect variations in electrostatic capacity in three-dimensional space detects variations in the electrostatic capacity of the gestures of a photographer, and an input unit performs acquisition. A lens adjustment unit performs focusing as a result of the recognition by a gesture recognition unit of a gesture wherein the thumb and the forefinger of the photographer are apart, an imaging unit performs shutter release as a result of the recognition of a gesture wherein the thumb and the forefinger of the photographer are brought into contact, the lens adjustment unit performs zooming as a result of the recognition of a gesture wherein the thumb and the forefinger of the photographer are rotated while apart, a light-emission unit turns a flash on as a result of the recognition of a gesture wherein one hand of an operator goes from clasped to open, and the light-emission unit turns the flash off as a result of the recognition of a gesture wherein one hand of the operator goes from open to clasped.