Abstract: A night hyper-spectral remote sensing imaging system for multi-component atmospheric trace constituents includes a light source unit, a detection light path unit, an unmanned aerial vehicle tracking light path unit, and a control and processing unit, where the light source unit couples and outputs first light source light with different wavelength ranges capable of imaging at night; the detection light path unit collimates and outputs the first light source light, and receive remote sensing light fed back based on the first light source light; the unmanned aerial vehicle tracking light path unit tracks and positions an unmanned aerial vehicle based on an unmanned aerial vehicle tracking light path; and the control and processing unit collects an original spectrum of the first light source light and a remote sensing spectrum and perform imaging analysis and process on the multi-component atmospheric trace constituents, and adjust and control the tracking light path.

Abstract: A drive structure, including a frame. A carrier assembly and a drive assembly are disposed in the frame; the carrier assembly includes a first carrier and a second carrier disposed on the first carrier; the drive assembly includes a first drive device and a second drive device, the first drive device is mounted in the frame, an output end of the first drive device is connected to and drives the first carrier, the second drive device is mounted on the first carrier, and the second drive device is connected to and drives the second carrier. Further, a drive device and an electronic equipment are disclosed.

Abstract: Provided are an optical anti-shaking mechanism, a lens driving device, and an imaging equipment. The optical anti-shaking mechanism includes: a movable body configured to install a sensor, a fixed body configured to support the movable body, a resilient anti-shaking frame resiliently connected to the fixed body and the movable body and configured to make the movable body overhang the fixed body, and a driving assembly including: an X-axis driving assembly configured to drive the movable body to move along an X-axis in a horizontal plane perpendicular to an optical axis, and a Y-axis driving assembly configured to drive the movable body to move along a Y-axis in the horizontal plane perpendicular to the optical axis. The translation movement of the image sensor perpendicular to the optical axis is realized, and the object of optical anti-shake of the translation movement of the image sensor is achieved.

Abstract: An optical anti-shake resilient support mechanism, an anti-shake driving device, a lens driving fitting, an imaging equipment and an electronic apparatus are provided. The optical anti-shake resilient support mechanism includes two X-direction resilient sheets symmetrically distributed with an optical axis of an optical component as an axis of symmetry and used to connect a focusing motor assembly and an optical anti-shake frame or to connect a base and the optical anti-shake frame; and two Y-direction resilient sheets symmetrically distributed with the optical axis of the optical component as an axis of symmetry and used to connect the base and the optical anti-shake frame or to connect the focusing motor assembly and the optical anti-shake frame. The unidirectional translation is one of X-axis unidirectional translation and Y-axis unidirectional translation, unidirectional performance is better than that of other optical anti-shake mechanisms, which can greatly simplify production process and reduce cost.

Abstract: An optical anti-shake resilient support mechanism, an anti-shake driving device, a lens driving fitting, an imaging equipment and an electronic apparatus are provided. The optical anti-shake resilient support mechanism includes two X-direction resilient sheets symmetrically distributed with an optical axis of an optical component as an axis of symmetry and used to connect a focusing motor assembly and an optical anti-shake frame or to connect a base and the optical anti-shake frame; and two Y-direction resilient sheets symmetrically distributed with the optical axis of the optical component as an axis of symmetry and used to connect the base and the optical anti-shake frame or to connect the focusing motor assembly and the optical anti-shake frame. The unidirectional translation is one of X-axis unidirectional translation and Y-axis unidirectional translation, unidirectional performance is better than that of other optical anti-shake mechanisms, which can greatly simplify production process and reduce cost.

Abstract: Provided are an optical anti-shaking mechanism, a lens driving device, and an imaging equipment. The optical anti-shaking mechanism includes: a movable body configured to install a sensor, a fixed body configured to support the movable body, a resilient anti-shaking frame resiliently connected to the fixed body and the movable body and configured to make the movable body overhang the fixed body, and a driving assembly including: an X-axis driving assembly configured to drive the movable body to move along an X-axis in a horizontal plane perpendicular to an optical axis, and a Y-axis driving assembly configured to drive the movable body to move along a Y-axis in the horizontal plane perpendicular to the optical axis. The translation movement of the image sensor perpendicular to the optical axis is realized, and the object of optical anti-shake of the translation movement of the image sensor is achieved.

Abstract: A drive structure, including a frame. A carrier assembly and a drive assembly are disposed in the frame; the carrier assembly includes a first carrier and a second carrier disposed on the first carrier; the drive assembly includes a first drive device and a second drive device, the first drive device is mounted in the frame, an output end of the first drive device is connected to and drives the first carrier, the second drive device is mounted on the first carrier, and the second drive device is connected to and drives the second carrier. Further, a drive device and an electronic equipment are disclosed.

Abstract: A lens driving device is described that includes a housing, a spacer, a lens supporting body, a coil, a magnet, and a base. The lens supporting body is disposed on the base, the spacer is disposed within the housing, and the housing covers the spacer, the lens supporting body, the coil and the magnet, and is connected to the base. The lens driving device further includes at least three elastic pieces. The at least three elastic pieces are respectively disposed on the base and the spacer and are connected to the base and the lens supporting body.

Abstract: A variable aperture device is described that includes a casing, a base with a light transmission hole, conductive terminals on the base, a terminal connecting portion, a shape memory metal wire, a movable portion, and a driven portion for forming an aperture together with the movable portion. One end of the shape memory metal wire is connected to the terminal connecting portion and the movable portion is connected to the base via a first rotating shaft. A side of the movable portion far from the light transmission hole around the first rotating shaft is connected to other end of the shape memory metal wire. A side of the movable portion near the light transmission hole around the first rotating shaft is connected to an elastic structure of the terminal connecting portion and the terminal connecting portion is attached to the conductive terminal.

Abstract: A variable aperture device is described that includes a casing, a base with a light transmission hole, conductive terminals on the base, a terminal connecting portion, a shape memory metal wire, a movable portion, and a driven portion for forming an aperture together with the movable portion. One end of the shape memory metal wire is connected to the terminal connecting portion and the movable portion is connected to the base via a first rotating shaft. A side of the movable portion far from the light transmission hole around the first rotating shaft is connected to other end of the shape memory metal wire. A side of the movable portion near the light transmission hole around the first rotating shaft is connected to an elastic structure of the terminal connecting portion and the terminal connecting portion is attached to the conductive terminal.

Abstract: A variable aperture device is described that includes a casing, a base with a light transmission hole, conductive terminals on the base, a terminal connecting portion, a shape memory metal wire, a movable portion, and a driven portion for forming an aperture together with the movable portion. One end of the shape memory metal wire is connected to the terminal connecting portion and the movable portion is connected to the base via a first rotating shaft. A side of the movable portion far from the light transmission hole around the first rotating shaft is connected to other end of the shape memory metal wire. A side of the movable portion near the light transmission hole around the first rotating shaft is connected to an elastic structure of the terminal connecting portion and the terminal connecting portion is attached to the conductive terminal.

Abstract: A variable aperture device is described that includes a casing, a base with a light transmission hole, conductive terminals on the base, a terminal connecting portion, a shape memory metal wire, a movable portion, and a driven portion for forming an aperture together with the movable portion. One end of the shape memory metal wire is connected to the terminal connecting portion and the movable portion is connected to the base via a first rotating shaft. A side of the movable portion far from the light transmission hole around the first rotating shaft is connected to other end of the shape memory metal wire. A side of the movable portion near the light transmission hole around the first rotating shaft is connected to an elastic structure of the terminal connecting portion and the terminal connecting portion is attached to the conductive terminal.

Abstract: A lens driving device is described that includes a housing, a spacer, a lens supporting body, a coil, a magnet, and a base. The lens supporting body is disposed on the base, the spacer is disposed within the housing, and the housing covers the spacer, the lens supporting body, the coil and the magnet, and is connected to the base. The lens driving device further includes at least three elastic pieces. The at least three elastic pieces are respectively disposed on the base and the spacer and are connected to the base and the lens supporting body.

Abstract: A driving device includes a first driving unit and an anti-shake driving unit. The first driving unit includes a lens carrier for carrying a lens, a fixing frame body for movably supporting the lens carrier in an optical axis direction of the lens; and a first driving mechanism for driving the lens carrier in the optical axis direction of the lens. The anti-shake driving unit is disposed on a rear side in the optical axis direction of the lens of the first driving unit, includes a sensor carrier for carrying an image sensor and for allowing the image sensor to generate an image signal according to light transmitted by the lens, and further includes a second driving mechanism for driving the sensor carrier to move in a direction perpendicular to the optical axis direction of the lens according to the shake of the lens carrier.