An object of the present disclosure is to improve operability of an imaging apparatus. The present disclosure is an imaging apparatus including: first operation part 15 for receiving selection of a first numerical value from a first numerical value group that specifies a photography setting condition; second operation part 14 for receiving selection of an operation from an operation group for the first numerical value; and a controller for determining a set value set by combining the first numerical value selected via first operation part 15 and the operation selected via the second operation part 14.

An electronic device is provided. The electronic device includes an image sensor for capturing an image; a barrel including a lens group arranged about a first axis perpendicular to the image sensor, a first housing fixed to the barrel; a second housing disposed under the first housing and coupled to the first housing; at least one magnetic substance disposed at one side of the first housing; and at least one coil disposed at one side of the second housing. When power is supplied to the at least one coil, electromagnetic force is generated between the at least one coil and the at least one magnetic substance. And if the electromagnetic force is generated, the first housing rotates clockwise or counterclockwise, and the barrel moves along the first axis.

An electronic device is provided. The electronic device includes an image sensor for capturing an image; a barrel including a lens group arranged about a first axis perpendicular to the image sensor, a first housing fixed to the barrel; a second housing disposed under the first housing and coupled to the first housing; at least one magnetic substance disposed at one side of the first housing; and at least one coil disposed at one side of the second housing. When power is supplied to the at least one coil, electromagnetic force is generated between the at least one coil and the at least one magnetic substance. And if the electromagnetic force is generated, the first housing rotates clockwise or counterclockwise, and the barrel moves along the first axis.

A thermal detection device includes a first camera, a second camera, a thermal camera, and a processor. The thermal camera is disposed between the first camera and the second camera, and detects a to-be-measured object to generate a first temperature value. The processor includes a control unit, which controls the first camera and the second camera according to settings of a first measurement mode and a second measurement mode. In the first measurement mode, the control unit captures images from the first camera and the second camera to measure a first distance between the to-be-measured object and an installation surface. In the second measurement mode, the control unit captures images from the first camera to measure a size of the to-be-measured object. The processor determines a second temperature value of the to-be-measured object according to the first temperature value, the first distance, and the size of the to-be-measured object.

A thermal detection device includes a first camera, a second camera, a thermal camera, and a processor. The thermal camera is disposed between the first camera and the second camera, and detects a to-be-measured object to generate a first temperature value. The processor includes a control unit, which controls the first camera and the second camera according to settings of a first measurement mode and a second measurement mode. In the first measurement mode, the control unit captures images from the first camera and the second camera to measure a first distance between the to-be-measured object and an installation surface. In the second measurement mode, the control unit captures images from the first camera to measure a size of the to-be-measured object. The processor determines a second temperature value of the to-be-measured object according to the first temperature value, the first distance, and the size of the to-be-measured object.

A thermal detection device includes a first camera, a second camera, a thermal camera, and a processor. The thermal camera is disposed between the first camera and the second camera, and detects a to-be-measured object to generate a first temperature value. The processor includes a control unit, which controls the first camera and the second camera according to settings of a first measurement mode and a second measurement mode. In the first measurement mode, the control unit captures images from the first camera and the second camera to measure a first distance between the to-be-measured object and an installation surface. In the second measurement mode, the control unit captures images from the first camera to measure a size of the to-be-measured object. The processor determines a second temperature value of the to-be-measured object according to the first temperature value, the first distance, and the size of the to-be-measured object.

A thermal detection device includes a first camera, a second camera, a thermal camera, and a processor. The thermal camera is disposed between the first camera and the second camera, and detects a to-be-measured object to generate a first temperature value. The processor includes a control unit, which controls the first camera and the second camera according to settings of a first measurement mode and a second measurement mode. In the first measurement mode, the control unit captures images from the first camera and the second camera to measure a first distance between the to-be-measured object and an installation surface. In the second measurement mode, the control unit captures images from the first camera to measure a size of the to-be-measured object. The processor determines a second temperature value of the to-be-measured object according to the first temperature value, the first distance, and the size of the to-be-measured object.

An object of the present disclosure is to improve operability of an imaging apparatus. The present disclosure is an imaging apparatus including: first operation part 15 for receiving selection of a first numerical value from a first numerical value group that specifies a photography setting condition; second operation part 14 for receiving selection of an operation from an operation group for the first numerical value; and a controller for determining a set value set by combining the first numerical value selected via first operation part 15 and the operation selected via the second operation part 14.

An object of the present disclosure is to improve operability of an imaging apparatus. The present disclosure is an imaging apparatus including: first operation part 15 for receiving selection of a first numerical value from a first numerical value group that specifies a photography setting condition; second operation part 14 for receiving selection of an operation from an operation group for the first numerical value; and a controller for determining a set value set by combining the first numerical value selected via first operation part 15 and the operation selected via the second operation part 14.

A camera filter unit (10) includes a front ring (4) for holding a polarization filter (2) and a rear ring (5) for rotatably holding the front ring (4). The front ring (4) includes a rear annular wall portion (18) extending in a radial direction (R), a rear annular plate portion (19) extending rearward from the inner peripheral end of the rear annular wall portion (18), and an annular projection portion (20) projecting for a short distance from the rear end of the rear annular plate portion (19) toward the outer peripheral side. The rear annular wall portion (18), the rear annular plate portion (19), and the annular projection portion (20) form an annular recess (21) on the outer peripheral surface of the front ring (4). The rear ring (5) includes an annular protrusion (45) protruding to the inner peripheral side. The annular protrusion (45) is inserted into the annular recess (21) of the front ring (4).