Provided are a camera module and an imaging apparatus including the same. The camera module includes a printed circuit board (PCB); a first imaging device on the PCB, the first imaging device configured to generate first image data based on a received optical signal; a second imaging device on the PCB, the second imaging device configured to generate second image data based on the received optical signal; a power management integrated circuit (PMIC) on the PCB, the PMIC configured to generate a plurality of power voltages based on an external power voltage received from an external power supply and provide the plurality of power voltages to the first imaging device and the second imaging device; and a connector configured to receive the external power voltage from the external power supply and provide the external power voltage to the PMIC.

A method of controlling the performance of a night vision device includes supplying, by a power supply, to a microchannel plate of a light intensifier tube, a control voltage that controls a gain of the microchannel plate, determining an amount of compensation to apply to the control voltage based on a change to the control voltage attributed to a change in temperature of an operating environment of the night vision device, adjusting the control voltage in accordance with the amount of compensation to obtain a compensated control voltage, and supplying, by the power supply, the compensated control voltage to the microchannel plate of the light intensifier tube. The method may further include determining whether the night vision device has been used for a predetermined amount of time, and only after that predetermined amount of time, is the method configured to supply the compensated control voltage.

One embodiment of a camera module may comprise: a lens barrel provided with at least one lens; a holder to which the lens barrel is coupled; a printed circuit board coupled on the bottom of the holder to face the lens; an adhering portion coupling the holder and the printed circuit board; an opening portion opening a portion of a first space formed through the coupling of the printed circuit board and the holder; and a housing coupled with the holder, wherein a second space separated from the first space may be formed through the coupling of the holder and the housing, and the opening portion may communicate the first space with the second space.

One embodiment of a camera module may comprise: a lens barrel provided with at least one lens; a holder to which the lens barrel is coupled; a printed circuit board coupled on the bottom of the holder to face the lens; an adhering portion coupling the holder and the printed circuit board; an opening portion opening a portion of a first space formed through the coupling of the printed circuit board and the holder; and a housing coupled with the holder, wherein a second space separated from the first space may be formed through the coupling of the holder and the housing, and the opening portion may communicate the first space with the second space.

A display panel and a terminal are provided. The display panel includes a light-emitting module, and scanning lines, data lines, and power lines which are electrically connected to the light-emitting module. Each of the power lines extends along a short side direction of the display panel, a number of power lines are arranged spaced apart along a long side direction of the display panel.

A sensor-stabilization assembly includes: a housing including a first portion of a first electromagnetic assembly and of a second electromagnetic assembly and defining a housing aperture; a first frame having first guides that permit relative motion between the first frame and the housing and defining a first frame aperture; and a second frame having second guides that permit relative motion between the second frame and the first frame. The second frame includes: a second portion of the first electromagnetic assembly adapted to interact with the first portion to cause the first frame and second frame to move relative to the housing; and a second portion of the second electromagnetic assembly adapted to interact with the first portion to cause the second frame to move relative to the first frame and housing. A sensor is coupled to the second frame to capture light through the housing aperture and first frame aperture.

A sensor-stabilization assembly includes: a housing including a first portion of a first electromagnetic assembly and of a second electromagnetic assembly and defining a housing aperture; a first frame having first guides that permit relative motion between the first frame and the housing and defining a first frame aperture; and a second frame having second guides that permit relative motion between the second frame and the first frame. The second frame includes: a second portion of the first electromagnetic assembly adapted to interact with the first portion to cause the first frame and second frame to move relative to the housing; and a second portion of the second electromagnetic assembly adapted to interact with the first portion to cause the second frame to move relative to the first frame and housing. A sensor is coupled to the second frame to capture light through the housing aperture and first frame aperture.

An optical element driving mechanism is provided. The optical element driving mechanism includes a movable portion, a fixed portion, and a driving assembly. The movable portion is used to connect the optical element. The movable portion may move relative to the fixed portion. The driving assembly is used to drive the movable portion to move relative to the fixed portion.

An optical element driving mechanism is provided. The optical element driving mechanism includes a movable portion, a fixed portion, and a driving assembly. The movable portion is used to connect the optical element. The movable portion may move relative to the fixed portion. The driving assembly is used to drive the movable portion to move relative to the fixed portion.

This application provides an image processing method and an image collection device. A haze intensity of a first image is calculated. When the haze intensity of the first image is greater than a first threshold, control information is sent, where the control information is used to control a haze penetration optical component to move into a lens. Because the haze penetration optical component can improve quality of optical imaging, the lens into which the haze penetration optical component is moved has a function of optical haze penetration. It can be learned that, when the haze intensity of the first image is greater than the first threshold, the function of the optical haze penetration is enabled, so as to improve quality of an image obtained in a haze environment.