Abstract: Disclosed are TCR-enriched clonotypes, and an acquisition method and use thereof. Amino acid sequences of the TCR-enriched clonotypes are: CAANRGSGYSTLTF (SEQ ID NO: 1)_CSARGERGEKLFF (SEQ ID NO: 2), CASSSGGSYIPTF (SEQ ID NO: 3)_CASSLAGGHETQYF (SEQ ID NO: 4), CAVNSYNTDKLIF (SEQ ID NO: 5)_CATSREEDNTYEQYF (SEQ ID NO: 6), CAVGGNEKLTF (SEQ ID NO: 7)_CASSQGTGRSSPLHF (SEQ ID NO: 8), or CAASAVGGAQKLVF (SEQ ID NO: 9)_CATSRGTLYGYTF (SEQ ID NO: 10), respectively. The TCR-enriched clonotypes can be used for vaccine development.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: A side beam for a battery tray is provided. The battery tray has an accommodating groove for accommodating a battery core. The side beam includes a first body and a second body. The first body includes a main portion and a supporting portion, and the supporting portion is connected to the main portion and is configured to support the battery core. The second body is fixed to the first body. The second body and the first body are separated workpieces. At least a part of the second body is located on a side of the supporting portion away from the accommodating groove.

Abstract: A radome is provided. The radome includes a substrate layer and a reinforcement layer, and the reinforcement layer is formed at least on an inner surface and/or an outer surface of the substrate layer. The reinforcement layer includes a fiber layer and thermoplastic resin attached to the fiber layer, the fiber layer includes a first fiber, and a length of the first fiber is greater than or equal to 25 mm; and the substrate layer includes thermoplastic resin, and the thermoplastic resin in the reinforcement layer is made of a same material as the thermoplastic resin in the substrate layer. According to the radome provided in this application, the reinforcement layer is provided on the substrate layer, so that impact resistance performance of the entire radome is improved by using the reinforcement layer. This is conducive to implementing lightweight of the radome and meeting an impact resistance performance requirement.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: The invention includes methods of forming electronic circuitry on a target surface using intense pulsed light-induced mass transfer (IPLMT) of metal nanoparticles (NPs) by applying a pliable mask to a target surface, coating a carrier film with metal NPs, mounting the carrier film to the target surface and over the pliable mask so that the pliable mask is sandwiched between the target surface and the metal NPs. and exposing the metal NPs to light energy to cause atoms of the metal NPs to evaporate and transport through openings of the pliable mask and condense on the target surface, producing a conductive pattern of condensed metal on the target surface. Certain implementations may utilize a kirigami-patterned pliable mask to enhance conformity to a freeform 3D target surface. In certain implementations, zinc (Zn) may be formed by IPLMT of Zn NPs to the target surface.

Abstract: A rotatable optical reflector device of a Light Detection and Ranging (LiDAR) scanning system used in a motor vehicle is disclosed. The rotatable optical reflector device comprises a glass-based optical reflector including a plurality of reflective surfaces and a flange. The rotatable optical reflector device further comprises a metal-based motor rotor body at least partially disposed in an inner opening of the glass-based optical reflector. The rotatable optical reflector device further comprises an elastomer piece having a first surface and a second surface. The first surface of the elastomer piece is in contact with a second mounting surface of the flange. The rotatable optical reflector device further comprises a clamping mechanism compressing the elastomer piece at the second surface of the elastomer piece, wherein movement of the metal-based motor rotor body causes the glass-based optical reflector to optically scan light in a field-of-view of the LiDAR scanning system.

Abstract: An application interface display method includes: receiving a first operation performed by a user for a target application program interface, where the target application program interface includes at least one function option; in response to the first operation, controlling the target application program interface to be displayed in a first display area through shrinking; receiving a second operation performed by the user for a target function option in the target application program interface; and displaying, in a second display area, a function option at a level that corresponds to the second operation and that is of the target function option; or displaying, in the first display area and a second display area, function options at two adjacent levels of the target function option, respectively. The second display area is an area outside the first display area in a current display interface.

Abstract: A laser device for providing light to a LiDAR system comprises a plurality of seed lasers configured to provide multiple seed light beams, at least two of the seed light beams having different wavelengths. An amplifier is optically coupled to the plurality of seed lasers to receive the multiple seed light beams. A power pump is configured to provide pump power to the amplifier, where the amplifier amplifies the multiple seed light beams using the pump power to obtain amplified light beams. A second light coupling unit is configured to demultiplex the amplified light beams to obtain a plurality of output light beams, at least two of the output light beams having wavelengths corresponding to the wavelengths of the at least two seed light beams.

Abstract: A light scanning device comprises a rotatable polygon-shaped structure comprising a frame, a plurality of mirror bonding plates configured to reflect light, and one or more flexures. At least some mirror bonding plates of the plurality of mirror bonding plates are adjustably attached to the frame based on corresponding flexures of the one or more flexures. A plurality of adjustment mechanisms is inserted between the frame and corresponding mirror bonding plates of the plurality of mirror bonding plates, where the plurality of adjustment mechanisms is configured to adjust tilt angles of the corresponding mirror bonding plates.

Abstract: A laser device for providing light to a LiDAR system comprises a plurality of seed lasers configured to provide multiple seed light beams, at least two of the seed light beams having different wavelengths. An amplifier is optically coupled to the plurality of seed lasers to receive the multiple seed light beams. A power pump is configured to provide pump power to the amplifier, where the amplifier amplifies the multiple seed light beams using the pump power to obtain amplified light beams. A second light coupling unit is configured to demultiplex the amplified light beams to obtain a plurality of output light beams, at least two of the output light beams having wavelengths corresponding to the wavelengths of the at least two seed light beams.

Abstract: A rotatable optical reflector device of a Light Detection and Ranging (LiDAR) scanning system used in a motor vehicle is disclosed. The rotatable optical reflector device comprises a glass-based optical reflector including a plurality of reflective surfaces and a flange. The rotatable optical reflector device further comprises a metal-based motor rotor body at least partially disposed in an inner opening of the glass-based optical reflector. The rotatable optical reflector device further comprises an elastomer piece having a first surface and a second surface. The first surface of the elastomer piece is in contact with a second mounting surface of the flange. The rotatable optical reflector device further comprises a clamping mechanism compressing the elastomer piece at the second surface of the elastomer piece, wherein movement of the metal-based motor rotor body causes the glass-based optical reflector to optically scan light in a field-of-view of the LiDAR scanning system.

Abstract: A battery pack includes: a battery box having a distribution cavity; a distribution box disposed in the distribution cavity; the distribution box including a panel; the panel having a first flow channel and a refrigerant inlet/outlet joint in communication with the first flow channel; and a thermoregulation member connected with the battery box; the thermoregulation member having a second flow channel in communication with the first flow channel.

Abstract: An apparatus of a light detection and ranging (LiDAR) scanning system for at least partial integration with a vehicle is disclosed. The apparatus comprises an optical core assembly including an oscillating reflective element, an optical polygon element, and transmitting and collection optics. The apparatus includes a first exterior surface at least partially bounded by at least a first portion of a vehicle roof or at least a portion of a vehicle windshield. A surface profile of the first exterior surface aligns with a surface profile associated with at least one of the first portion of the vehicle roof or the portion of the vehicle windshield. A combination of the first exterior surface and the one or more additional exterior surfaces form a housing enclosing the optical core assembly including the oscillating reflective element, the optical polygon element, and the transmitting and collection optics.

Abstract: A screenshot method includes: receiving a first input performed on a first display interface; obtaining a target long preview screenshot of the first display interface in response to the first input; receiving a second input performed on the target long preview screenshot; in response to the second input, obtaining a target screenshot of a second display interface, where the second display interface is a display sub-interface of the first display interface; and generating a long screenshot according to the target long preview screenshot and the target screenshot.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: A motorized optical scanner device of a Light Detection and Ranging (LiDAR) scanning system used in a motor vehicle is disclosed. The motorized optical scanner device comprises a glass-based optical reflector including a plurality of reflective surfaces and a flange. The rotatable optical reflector device further comprises an adjustment ring and a metal-based motor rotor body at least partially disposed in an inner opening of the glass-based optical reflector. The flange extends from an inner sidewall of the glass-based optical reflector towards the metal-based motor rotor body. The flange includes a first mounting surface that is in contact with the adjustment ring. The motorized optical scanner device further comprises a plurality of fastening mechanisms. The plurality of fastening mechanisms facilitates applying adjustment forces to the adjustment ring to reduce wobble associated with rotation of the glass-based optical reflector.

Abstract: A light detection and ranging (LiDAR) system for detecting objects in blind-spot areas is provided. The system comprises a housing, a scanning-based LiDAR assembly disposed in the housing, and a non-scanning-based LiDAR assembly also disposed in the housing. The scanning-based LiDAR assembly is configured to scan a plurality of light beams to illuminate a first field-of-view (FOV). The non-scanning-based LiDAR assembly is configured to transmit laser light to illuminate a second FOV without scanning. The scanning-based LiDAR assembly's detection distance range extends beyond the detection distance range of the non-scanning-based LiDAR assembly.

Abstract: An isolation system for a light detection and ranging (LiDAR) optical core assembly is provided. The LiDAR optical core assembly comprises a polygon-motor rotating element, an oscillating reflective element, and transmitting and collection optics. The isolation system comprises a polygon-motor base element coupled to the polygon-motor rotating element and a plurality of isolators substantially fixed to the polygon-motor base element and disposed relative to each other around a spatial location determined based on a center of gravity of at least one of the optical core assembly and the polygon-motor rotating element. The plurality of isolators is adapted to mitigate acoustic noise caused by at least the polygon-motor rotating element during operation of the optical core assembly.