A fast-focusing zoom camera module with precise and high-speed autofocus function includes a reflecting assembly, a lens assembly, and a light sensing assembly, the lens assembly is arranged between the reflecting assembly and the light sensing assembly. The reflecting assembly comprises a reflecting member and a first actuator, the first actuator driving the reflecting member to rotate around a second direction. The lens assembly comprises a lens member and a second actuator, the second actuator drives the lens member to move along a first direction. The light sensing assembly comprises a first circuit board, a sensor, and a third actuator, the sensor is electrically connected to the first circuit board, the third actuator drives the sensor to move along a third direction. The first direction, the second direction, and the third direction are perpendicular to each other.

An imaging apparatus includes a first optical system, a first separation optical system that separates the light transmitted through the first optical system into the first wavelength range light and the second wavelength range light, a second optical system that transmits the first wavelength range light obtained by the first separation optical system, a third optical system that transmits the second wavelength range light obtained by the first separation optical system, a first image sensor that receives the first wavelength range light, a second image sensor that receives the second wavelength range light, and a first light source that emits the first wavelength range light, in which the first optical system emits the first wavelength range light emitted from the first light source to a subject, and transmits subject light including first wavelength range reflected light obtained by reflecting the first wavelength range light by the subject.

A focus driving control unit 34 of a control unit 30 performs speed priority driving control in which a focus lens is driven to a focusing position in a driving pattern selected in advance by a user, for example, in a case in which a defocus amount of a ranging area is greater than a driving control determination threshold set in advance. In addition, the focus driving control unit 34 performs subject priority driving control in which a focus lens movement amount by which the focus lens is located at the focusing position in accordance with the defocus amount of the ranging area is set and the focus lens is driven in a case in which the defocus amount is equal to or less than the driving control determination threshold. The focus lens is driven to the focusing position in the driving pattern selected by the user. Thereafter, a focusing state can be maintained. Accordingly, it is possible to easily perform an auto-focus operation with the high degree of freedom.

Provided is a lens apparatus including: a lens; detectors configured to detect temperatures at a plurality of mutually different positions of the lens apparatus, respectively; and a processor configured to obtain a change amount of a temperature per unit time with respect to each of the plurality of mutually different positions based on each of the detected temperatures and a time at which each of the detected temperatures is obtained, to estimate a temperature of the lens based on the change amount with respect to each of the plurality of mutually different positions.

A focus adjustment control apparatus is provided which includes: a focus detection unit that calculates an evaluation value with regard to contrast of an image via an optical system to detect a focus adjustment state of the optical system; an acquisition unit that acquires from a lens barrel at least one of a maximum value and a minimum value of an image plane movement coefficient that represents correspondence relationship between a movement amount of a focus adjustment lens included in the optical system and a movement amount of an image plane; and a control unit that uses at least one of the maximum value and the minimum value of the image plane movement coefficient to determine a drive speed for the focus adjustment lens when the focus detection unit detects the focus adjustment state.

In a case where a microscope apparatus main body scans the bottom surface of the cultivation container by synchronously controlling a piezoelectric element and an actuator serving as optical axis-directional transport devices having different properties from each other, an objective lens of the imaging optical system is transported to a focus position in the optical axis direction.

An imaging device stores a focal length and a position of a focus lens in a storage unit in a case in which a focal state is determined to be a focus state in which a subject is in focus and at least one of the imaging device or the subject is determined to be stationary; generates tracking data for changing the position of the focus lens according to a change in focal length, using a plurality of stored focal lengths and a plurality of stored positions of the focus lens; and performs a zoom tracking control using the generated tracking data.

An optical apparatus and a driving method therefor according to an embodiment are disclosed. The optical apparatus comprises: a lens assembly including a liquid lens; and a control circuit for generating a driving signal for driving the liquid lens, wherein the driving signal includes a first section and a second section having driving signals with different waveform shapes.

An endoscope system includes an endoscope having a position/angle sensor and an amplifying circuit, a memory configured to store output error sensitivity data and a first wiring resistance value, and a processor including a signal processing circuit configured to process an output signal from the amplifying circuit. The signal processing circuit corrects an error of the output signal based on a value obtained by multiplying a difference between the first wiring resistance value and a processor wiring resistance value by the output error sensitivity data.

The present invention provides a technology whereby relative positioning in the horizontal direction between a specimen observation area in a specimen container and an imaging field of view can be reliably performed, even prior to adjusting the focal position in the vertical direction using an auto-focus system. This specimen observation apparatus: obtains a luminance value for an image at a plurality of locations in the specimen container, prior to performing auto-focus; and uses the number of high-luminance regions and the width of those regions and identifies a central position, in the horizontal direction, in the specimen container or uses the number of low-luminance regions and the width of those regions and identifies the central position, in the horizontal direction, in the specimen container.