A screen control method is provided. The method is implemented in a terminal device having a first screen, a second screen, and a lens, the first screen and the second screen being disposed facing against one another. The method includes obtaining a command configured to instruct to display the image captured by the lens on the second screen. The method also includes controlling display of the image captured by the lens on the second screen based on the command.

A digital camera with which a captured image can be easily recognized through an electronic viewfinder regardless of whether the digital camera is oriented vertically or horizontally. A camera having an imaging lens, an electronic viewfinder to observe the image captured by the imaging lens, a guide mechanism guiding the vertical movement of the electronic viewfinder, and a biaxial rotation mechanism capable of causing the electronic viewfinder to rotate according to the vertical screen position or the horizontal screen position. The biaxial rotation mechanism is provided with a linking part linking the electronic viewfinder and the guide mechanism; a first shaft part for supporting the electronic viewfinder on the linking part so as to rotate in a first direction; and a second shaft part supporting the linking part on the guide mechanism so as to rotate in a second direction.

A digital camera with which a captured image can be easily recognized through an electronic viewfinder regardless of whether the digital camera is oriented vertically or horizontally. A camera having an imaging lens, an electronic viewfinder to observe the image captured by the imaging lens, a guide mechanism guiding the vertical movement of the electronic viewfinder, and a biaxial rotation mechanism capable of causing the electronic viewfinder to rotate according to the vertical screen position or the horizontal screen position. The biaxial rotation mechanism is provided with a linking part linking the electronic viewfinder and the guide mechanism; a first shaft part for supporting the electronic viewfinder on the linking part so as to rotate in a first direction; and a second shaft part supporting the linking part on the guide mechanism so as to rotate in a second direction.

The present disclosure provides an imaging device including a wide-angle camera and a telephoto camera. A field of view of the telephoto camera is located in a field of view of the wide-angle camera, the telephoto camera includes a telephoto lens. The telephoto lens includes: at least one first lens element, a light reflecting element and at least one second lens element arranged sequentially from an object side to an image side along a light axis. The light reflecting element is configured to make the light axis to reflect from a first direction to a second direction. An electronic device including the imaging device is further provided. In the imaging device and the electronic device above, the light axis of the telephoto camera is reflected, lowering a height of the telephoto lens and a height of the telephoto camera.

The shape of a camera body of a digital camera including a printer viewed from the front surface is a square shape, and an imaging optical system is positioned at the center of a camera body. An axis crossing an optical axis of the imaging optical system in a vertical direction is referred to as a vertical axis, and an axis crossing the optical axis in a horizontal direction is referred to as a horizontal axis. A grip portion is formed on the camera body at positions that are symmetric with respect to the vertical axis and symmetric with respect to the horizontal axis. The grip portion has an annular shape and a concave shape that is concave from the surface around the grip portion. The imaging optical system is positioned at the center of the annular grip portion in a case where the digital camera including a printer is viewed from the front surface of the camera body.

A system and method for dust mitigation in an environment with high amounts of debris is disclosed. The system may include an optical device disposed within an interior volume of an enclosure. A positive flow of clean air may be maintained into an air input aperture of the enclosure, around the optical device, over a lens of the optical device, and out a lens aperture of the enclosure. The system may be affixed to a piece of equipment, machine, or similar structure via a positionable or pivotable mount.

A system and method for dust mitigation in an environment with high amounts of debris is disclosed. The system may include an optical device disposed within an interior volume of an enclosure. A positive flow of clean air may be maintained into an air input aperture of the enclosure, around the optical device, over a lens of the optical device, and out a lens aperture of the enclosure. The system may be affixed to a piece of equipment, machine, or similar structure via a positionable or pivotable mount.

An imaging apparatus includes: a first display panel unit for executing display toward a user side; a second display panel unit for executing display toward a subject side; an imaging processing unit for subjecting incident light from the subject side to photoelectric conversion to obtain a captured image signal; a recording processing unit for executing a recording process to a recording medium regarding the captured image signal obtained at the imaging processing unit; and a control unit for controlling the display states of the first display panel unit and the second display panel unit for each of a plurality of various types of operation periods changing along with the operation of the imaging processing unit or the recording processing unit, and executing display control wherein the first display panel unit and the second display panel unit can have different display content during at least a single operation period.

An imaging apparatus includes: a first display panel unit for executing display toward a user side; a second display panel unit for executing display toward a subject side; an imaging processing unit for subjecting incident light from the subject side to photoelectric conversion to obtain a captured image signal; a recording processing unit for executing a recording process to a recording medium regarding the captured image signal obtained at the imaging processing unit; and a control unit for controlling the display states of the first display panel unit and the second display panel unit for each of a plurality of various types of operation periods changing along with the operation of the imaging processing unit or the recording processing unit, and executing display control wherein the first display panel unit and the second display panel unit can have different display content during at least a single operation period.

An imaging apparatus includes: a first display panel unit for executing display toward a user side; a second display panel unit for executing display toward a subject side; an imaging processing unit for subjecting incident light from the subject side to photoelectric conversion to obtain a captured image signal; a recording processing unit for executing a recording process to a recording medium regarding the captured image signal obtained at the imaging processing unit; and a control unit for controlling the display states of the first display panel unit and the second display panel unit for each of a plurality of various types of operation periods changing along with the operation of the imaging processing unit or the recording processing unit, and executing display control wherein the first display panel unit and the second display panel unit can have different display content during at least a single operation period.