A photographing device, comprising a memory for storing relationships between movement of the focus adjustment lens and image plane movement amount, a controller for setting movement amount of the focus adjustment lens constituting a specified image plane movement amount with respect to unit rotation amount of the ring member, based on a relationship that is stored in the memory, and controlling movement of the focus adjustment lens in accordance with rotation amount and rotation direction of the ring member based on the movement amount, and a rotation velocity detector for detecting rotation velocity of the ring member, wherein the control section, when rotation velocity is smaller than a specified value, sets a movement amount of the focus adjustment lens constituting a specified image movement amount with respect to unit rotation amount of the ring member, based on a relationship that is stored in the storage section.

A photographing device, comprising a memory for storing relationships between movement of the focus adjustment lens and image plane movement amount, a controller for setting movement amount of the focus adjustment lens constituting a specified image plane movement amount with respect to unit rotation amount of the ring member, based on a relationship that is stored in the memory, and controlling movement of the focus adjustment lens in accordance with rotation amount and rotation direction of the ring member based on the movement amount, and a rotation velocity detector for detecting rotation velocity of the ring member, wherein the control section, when rotation velocity is smaller than a specified value, sets a movement amount of the focus adjustment lens constituting a specified image movement amount with respect to unit rotation amount of the ring member, based on a relationship that is stored in the storage section.

A method for generating a three-dimensional luminescence image includes setting a focal interval between two-dimensional images in accordance with localization of luminescence in a three-dimensional sample. The three-dimensional sample contains a plurality of cells prepared to be luminescent and has a three-dimensional shape. The two-dimensional images have mutually different focal planes and are acquired at the focal interval. The method further includes acquiring a two-dimensional image set including two-dimensional images at the focal interval that is set by imaging the three-dimensional sample under an unirradiated condition; and generating a three-dimensional luminescence image by combining the two-dimensional images included in the two-dimensional image set together.

A method for generating a three-dimensional luminescence image includes setting a focal interval between two-dimensional images in accordance with localization of luminescence in a three-dimensional sample. The three-dimensional sample contains a plurality of cells prepared to be luminescent and has a three-dimensional shape. The two-dimensional images have mutually different focal planes and are acquired at the focal interval. The method further includes acquiring a two-dimensional image set including two-dimensional images at the focal interval that is set by imaging the three-dimensional sample under an unirradiated condition; and generating a three-dimensional luminescence image by combining the two-dimensional images included in the two-dimensional image set together.

This application provides a compact camera module, which includes a first actuator, an optical lens component, a ray adjustment component, and an image sensor. The ray adjustment component and the image sensor are sequentially disposed along a direction of a principal optical axis of the optical lens component. The optical lens component is configured to receive rays from a photographed object. The ray adjustment component is configured to fold an optical path of the rays propagated from the optical lens component. The first actuator is configured to drive the ray adjustment component to move, so that the rays whose optical path is folded are focused on the image sensor.

This application provides a compact camera module, which includes a first actuator, an optical lens component, a ray adjustment component, and an image sensor. The ray adjustment component and the image sensor are sequentially disposed along a direction of a principal optical axis of the optical lens component. The optical lens component is configured to receive rays from a photographed object. The ray adjustment component is configured to fold an optical path of the rays propagated from the optical lens component. The first actuator is configured to drive the ray adjustment component to move, so that the rays whose optical path is folded are focused on the image sensor.

An optical instrument, comprising an optical system including a focus lens group, an aperture that restricts light flux that passes through the optical system, an aperture motor that sets opening amount for the aperture, a memory that stores first information that represents a relationship between position of the focus lens group and appropriate aperture value and second information that represents a relationship between the aperture value and opening amount of the aperture, and a controller that, when controlling opening amount of the aperture using the aperture motor in accordance with position of the focus lens group, calculates an appropriate aperture value based on the first information and position of the focus lens group, calculates opening amount of the aperture based on the second information and the aperture value that has been calculated, and controls the opening amount to the opening amount of the aperture that has been calculated.

An optical instrument, comprising an optical system including a focus lens group, an aperture that restricts light flux that passes through the optical system, an aperture motor that sets opening amount for the aperture, a memory that stores first information that represents a relationship between position of the focus lens group and appropriate aperture value and second information that represents a relationship between the aperture value and opening amount of the aperture, and a controller that, when controlling opening amount of the aperture using the aperture motor in accordance with position of the focus lens group, calculates an appropriate aperture value based on the first information and position of the focus lens group, calculates opening amount of the aperture based on the second information and the aperture value that has been calculated, and controls the opening amount to the opening amount of the aperture that has been calculated.

According to an embodiment of the present disclosure, a lens assembly may include at least seven lenses sequentially arranged from an object side to an image sensor side, where a first lens may have negative refractive power and may include a concave object side surface and a convex image sensor side surface, a second lens may have positive refractive power and may include an object side surface and an image sensor side surface at least one of which is aspherical, a third lens may have positive refractive power, one of the second lens and the third lens may have a refractive index of 1.6 or more, the refractive index of the seventh lens disposed seventh from the side may be 1.6 or more, and the lens assembly may have a half-field angle of 50 degrees or more. Various other embodiments are possible.

The present invention discloses a display device including an optical film including a through hole; a display panel disposed on a surface of one side of the optical film, wherein the display panel includes a transparent area corresponding to the through hole; a camera including a camera lens, wherein the camera is inserted into the through hole and faces the transparent area; and a plurality of LED chips evenly arranged around the camera lens, wherein the LED chips are disposed in the through hole and between the camera and the transparent area.