Abstract: Embodiments of the present invention relate to the field of communications methods and technologies, and in particular, to a transmission method and apparatus. The transmission method includes: generating, by a first device, a sequence based on one or more transmission parameters, where the one or more transmission parameters include at least one of the following: a time domain resource type, transmission waveform indication information, subcarrier spacing indication information, device type information, service type indication information, multiple-input multiple-output MIMO parameter information, duplex mode indication information, control channel format indication information, and transmission carrier indication information; generating to-be-transmitted information by using the sequence; and sending the to-be-transmitted information. According to the transmission method and apparatus in the embodiments of the present invention, a new transmission error check mechanism is provided.

Abstract: A multi-axis turntable includes a base, a rocker arm and a first driving device capable of driving the rocker arm to rock around the first rotation axis on the base. A swing arm and a second driving device, which is capable of driving the swing arm to swing around the second rotation axis on the rocker arm, are provided on the rocker arm. A workbench and a third driving device for driving the workbench to rotate around the third rotation axis are provided on the swing arm. The second rotation axis and the third rotation axis are parallel to each other or on different planes. Compared with the existing double rotating shaft turntable, the multi-axis turntable of the present invention has a cutting tool system of good and stable rigidity.

Abstract: The present disclosure describes a system for analyzing biological samples. The system includes an optical waveguide. The optical waveguide includes a first end and a second end. The optical waveguide is configured to receive an excitation light at the first end. The optical waveguide further includes a first light-guiding layer disposed between the first end and the second end. The first light-guiding layer is configured to direct, at least in part, the received excitation light toward the second end of the optical waveguide along a longitudinal direction of the optical waveguide. The optical waveguide further includes a fluidic reaction channel bounded in part by the first light-guiding layer of the optical waveguide, which delivers the excitation light to biological samples disposed in the fluidic reaction channel. The system further includes a backside illumination based image sensor.

Abstract: A system includes a plurality of modular subassemblies and a plate; wherein each modular subassembly comprises an enclosure and a plurality of optical components aligned to the enclosure, and each enclosure comprises a plurality of mounting structures; and wherein each modular subassembly is mechanically coupled to the plate by attachment of a mounting structure of the modular subassembly directly to a corresponding mounting structure located on the plate, such that by mechanically coupling each modular subassembly to the plate using the mounting structure of the modular subassembly and the corresponding mounting structure on the plate, adjacent modular subassemblies are aligned to each other upon such attachment, and wherein two of the modular subassemblies mechanically coupled to the plate are also attached to each other by mechanically coupling an alignment structure on one of the two modular subassemblies to a respective alignment structure on the other of the two modular subassemblies.

Abstract: A system includes: an objective lens; a first light source to feed first illuminating light through the objective lens and into a flowcell (e.g., with a relatively thin film waveguide) to be installed in the system, the first illuminating light to be fed using a first grating on the flowcell; and a first image sensor to capture imaging light using the objective lens, wherein the first grating is positioned outside a field of view of the first image sensor. Dual-surface imaging can be performed. Flowcells with multiple swaths bounded by gratings can be used. An auto-alignment process can be performed.

Abstract: Embodiments of the present invention relate to the field of communications methods and technologies, and in particular, to a transmission method and apparatus. The transmission method includes: generating, by a first device, a sequence based on one or more transmission parameters, where the one or more transmission parameters include at least one of the following: a time domain resource type, transmission waveform indication information, subcarrier spacing indication information, device type information, service type indication information, multiple-input multiple-output MIMO parameter information, duplex mode indication information, control channel format indication information, and transmission carrier indication information; generating to-be-transmitted information by using the sequence; and sending the to-be-transmitted information. According to the transmission method and apparatus in the embodiments of the present invention, a new transmission error check mechanism is provided.

Abstract: A system includes a plurality of modular subassemblies and a plate; wherein each modular subassembly comprises an enclosure and a plurality of optical components aligned to the enclosure, and each enclosure comprises a plurality of mounting structures; and wherein each modular subassembly is mechanically coupled to the plate by attachment of a mounting structure of the modular subassembly directly to a corresponding mounting structure located on the plate, such that by mechanically coupling each modular subassembly to the plate using the mounting structure of the modular subassembly and the corresponding mounting structure on the plate, adjacent modular subassemblies are aligned to each other upon such attachment, and wherein two of the modular subassemblies mechanically coupled to the plate are also attached to each other by mechanically coupling an alignment structure on one of the two modular subassemblies to a respective alignment structure on the other of the two modular subassemblies.

Abstract: A system includes: an objective lens; a first light source to feed first illuminating light through the objective lens and into a flowcell (e.g., with a relatively thin film waveguide) to be installed in the system, the first illuminating light to be fed using a first grating on the flowcell; and a first image sensor to capture imaging light using the objective lens, wherein the first grating is positioned outside a field of view of the first image sensor. Dual-surface imaging can be performed. Flowcells with multiple swaths bounded by gratings can be used. An auto-alignment process can be performed.

Abstract: Embodiments of the present invention relate to the field of communications methods and technologies, and in particular, to a transmission method and apparatus. The transmission method includes: generating, by a first device, a sequence based on one or more transmission parameters, where the one or more transmission parameters include at least one of the following: a time domain resource type, transmission waveform indication information, subcarrier spacing indication information, device type information, service type indication information, multiple-input multiple-output MIMO parameter information, duplex mode indication information, control channel format indication information, and transmission carrier indication information; generating to-be-transmitted information by using the sequence; and sending the to-be-transmitted information. According to the transmission method and apparatus in the embodiments of the present invention, a new transmission error check mechanism is provided.

Abstract: The present disclosure describes a system for analyzing biological samples. The system includes an optical waveguide. The optical waveguide includes a first end and a second end. The optical waveguide is configured to receive an excitation light at the first end. The optical waveguide further includes a first light-guiding layer disposed between the first end and the second end. The first light-guiding layer is configured to direct, at least in part, the received excitation light toward the second end of the optical waveguide along a longitudinal direction of the optical waveguide. The optical waveguide further includes a fluidic reaction channel bounded in part by the first light-guiding layer of the optical waveguide, which delivers the excitation light to biological samples disposed in the fluidic reaction channel. The system further includes a backside illumination based image sensor.

Abstract: Embodiments of this application disclose a reference signal transmission method, a message transmission method, a transmission resource determining method, and an apparatus. When a first device needs to transmit a reference signal, the first device may determine, from a slot and based on a time domain resource parameter of the reference signal, transmission resource information related to a transmission resource used to transmit the reference signal, where the transmission resource information may include a symbol location of the transmission resource in the slot and/or a space domain resource on a symbol in the transmission resource. Compared with a conventional manner in which a reference signal can be transmitted only at a fixed location, the transmission resource for transmitting the reference signal can be dynamically determined based on the time domain resource parameter of the reference signal.

Abstract: A biosensor for detecting light signals emitted by a biological material is provided. The biosensor includes a light signal detector which comprises an array of light sensor pixels. The biosensor further includes a light signal filter layer disposed on a surface of the light sensor pixel array, a metal nanometer light focusing unit array layer, a grating array layer which comprises micro-gratings, and a biological material sample bearing area which comprises a plurality of sample gathering units. Each sample gathering unit aligns with one micro-grating and one metal nanometer light focusing unit in the vertical direction, and at least one of the light sensor pixels.

Abstract: A waveguide filter sensing unit is provided. The waveguide sensing unit includes an input waveguide for receiving an optical signal and an interference waveguide region for filtering the optical signal to remove noise therein. The waveguide sensing unit further includes a cladding layer wrapping around the input waveguide and the interference waveguide region; and an optical signal detector converting the filtered optical signal into an electrical signal. The width of the input waveguide is smaller than that of the interference waveguide region, and the refractive index of the cladding layer is smaller than that of the input waveguide and the interference waveguide region.

Abstract: A method includes: receiving first information, where the first information is used to instruct UE to send second information; obtaining a first parameter value, where the first parameter value indicates a location relationship between a first time domain resource and a second time domain resource, the first time domain resource is a time domain resource in which the first information is located, the second time domain resource is a time domain resource in which the second information is located, duration of the second time domain resource in time domain is not longer than one subframe, and an interval between the second time domain resource and the first time domain resource is shorter than four subframes; and determining the second time domain resource based on the first parameter value, and sending the second information on the second time domain resource.

Abstract: The present invention relates to the wireless communications field, and provides a scheduling method, a device, and a system, to resolve a problem that a scheduling resource is wasted when SPS transmission with a relatively short scheduling interval is applied to a V2X service. The scheduling method provided in the present invention includes: receiving, by a first device, semi-persistent scheduling SPS configuration information from a second device; receiving, by the first device, SPS activation information from the second device, where the SPS activation information is used to indicate an activated SPS resource; and sending, by the first device, the SPS instruction information to the second device, where the SPS instruction information is used to instruct to use or not to use a scheduling resource of the activated SPS resource. Embodiments of the present invention are applied to V2X communication.

Abstract: Embodiments of the present disclosure provide an information transmission method, including: determining, by a user equipment (UE), first speed information of the UE; determining, by the UE, a transmission manner of control information based on the first speed information; and sending, by the UE, the control information in the transmission manner over a first link. In the embodiments of the present disclosure, the UE may determine the transmission manner of the control information based on the first speed information. When the UE is high speed UE, an appropriate transmission manner can be selected for the high speed UE, thereby meeting a transmission requirement of the high speed UE and ensuring a transmission success rate.

Abstract: Embodiments of the present disclosure include example device-to-device communication methods and terminal devices. One example method includes determining, by a terminal device, a first resource, where the first resource is some time-frequency resources in a first resource set, where the first resource set is all time-frequency resources that can be used to detect a first transmission resource. The first transmission resource is a spectrum resource used to transmit first data. The terminal device can then perform detection for the first transmission resource in the first resource. In some instances, the terminal device can then send first data on the first transmission resource.

Abstract: A device-to-device data transmission method includes: performing signal detection on a first resource subset of a resource set used for data transmission, where a resource on which the signal detection is performed is less than the resource set; determining an available resource in the resource set based on a signal detection result; and transmitting to-be-transmitted data by selecting a resource from the available resource.

Abstract: A system includes a plurality of modular subassemblies and a plate; wherein each modular subassembly comprises an enclosure and a plurality of optical components aligned to the enclosure, and each enclosure comprises a plurality of mounting structures; and wherein each modular subassembly is mechanically coupled to the plate by attachment of a mounting structure of the modular subassembly directly to a corresponding mounting structure located on the plate, such that by mechanically coupling each modular subassembly to the plate using the mounting structure of the modular subassembly and the corresponding mounting structure on the plate, adjacent modular subassemblies are aligned to each other upon such attachment, and wherein two of the modular subassemblies mechanically coupled to the plate are also attached to each other by mechanically coupling an alignment structure on one of the two modular subassemblies to a respective alignment structure on the other of the two modular subassemblies.

Abstract: Imaging systems including an objective lens and a line generation module are described herein. The objective lens may focus a first light beam emitted by the line generation module and a second light beam emitted by the line generation module at a focal point external to a sample so as to adjust line width. Line width may be increased to lower overall power density of a light beam on a surface of the sample such that the power density of the light beam on the surface of the sample is below a photosaturation threshold of a dye on the sample.