Abstract: A metal 3D printing device comprises a building platform, a first powder spreading arm, a second powder spreading arm, a gas stream unit and a scanning module. The building platform is for supporting the powder. The first and second powder spreading arms are spaced and configured for spreading powder. The gas stream unites comprises a gas blowing port and a gas suction port, the gas blowing port is provided in the first powder spreading arm, and the gas suction port is provided in the second powder spreading arm. The scanning module is for emitting a laser to the powder preplaced between the first and second powder spreading arms to solidify the powder to form the product.

Abstract: An exclusive agent pool allocation method including collecting business data of agents; grouping agents according to the business data of the agents and forming multiple exclusive agent pools; calculating business skill values of agents according to the business data of the agents and classifying priorities of the agents; classifying priorities of agent pools according to the business data of the exclusive agent pools; and allocating calling user to the corresponding agent in the exclusive agent pool according to predetermined allocation strategy. The method solves the matching of the user and the agent in the region and the business level, allocates the agent resource according to the priority of the business skill, realizes the high match between the business skill of the agent and the business handled by the user, improves the pertinence and effectiveness of the agent service and promotes the satisfaction of the users.

Abstract: A portable sample loading device (1,4,7) include a base (11,41,71) and a fixing device (11,41,71) connected to the base (12,42,72). The base (12,42,72) can support a chip (2,5) and a sample loading connector (3,6). The fixing device (12,42,72) can detachably retain the chip (2,5) and the sample loading connector (3,6) on the base (11,41,71). The base (11,41,71) includes a front surface (110,410,710) and a back surface (111,411,711) opposite to the front surface (110,410,710). The front surface (110,410,710) includes a supporting surface for supporting the chip (2,5). A region of the supporting surface (112,412,712) corresponds to a sample inlet of the chip (2,5) is recessed toward the back surface (111,411,711) to form a receiving space (114,117,414,714) for receiving the sample loading connector (3,6). The receiving space (114,117,414,714) further defines a sample injection hole (115, 415,715) corresponding to the sample inlet of the chip (2,5).

Abstract: An exclusive agent pool allocation method including collecting business data of agents; grouping agents according to the business data of the agents and forming multiple exclusive agent pools; calculating business skill values of agents according to the business data of the agents and classifying priorities of the agents; of classifying priorities of agent pools according to the business data of the exclusive agent pools; and allocating calling user to the corresponding agent in the exclusive agent pool according to predetermined allocation strategy. The method solves the matching of the user and the agent in the region and the business level, allocates the agent resource according to the priority of the business skill, realizes the high match between the business skill of the agent and the business handled by the user, improves the pertinence and effectiveness of the agent service and promotes the satisfaction of the users.

Abstract: The present disclosure discloses a remote interview signature agent matching method, an electronic device and a computer memory readable storage medium, said method comprising the following steps: Step 01, an user end inquiring whether there is an interview signature task, if so, then going to Step 02, otherwise ending the method; Step 02, the user end sending an interview signature request to an agent end, wherein the interview signature request includes user information and business information, the agent end confirming the user information and the business information; Step 03, the agent end allocating the interview signature request to a matching agent according to preset allocation strategy; Step 04, the matching agent performing matching check of user information and business information on the interview signature request, if matching is successful, connecting to incoming call user, otherwise returning to Step 03 for reallocation.

Abstract: A method includes applying a voltage to a wafer or a device under test (DUT). The wafer or the DUT is illuminated with an electron beam after applying the voltage to the wafer or the DUT. Cathodoluminescent light emitted from the wafer or the DUT in response to the electron beam is detected. One or more characteristics of the wafer or the DUT are determined based on the detected cathodoluminescent light.

Abstract: The present invention relates to use of an Anaplasma phagocytophilum protein APH1384 as diagnostic antigen for granulocytic anaplasmosis. The protein can remedy the drawback of missed detection of an existing diagnostic antigen P44 for granulocytic anaplasmosis, improve sensitivity of detection for granulocytic anaplasmosis, and facilitate rapid and accurate clinical diagnosis of granulocytic anaplasmosis.

Abstract: The application discloses a method for remote interview signature, an electronic device and a computer-readable medium, comprising steps of: step 01, the client end inquiring whether there is an interview signature task, if so, then going to step 02, if not, exits; Step 02, the user terminal sending the interview signature request to the agent end, the interview signature request including the user information and the service information, the agent end confirming the user information and the service information; Step 03, the agent end authenticating the user, if the authentication passes, then going to step 04, and if the authentication fails, the user is reminded to go to the counter to handle the interview signature; Step 04, the agent end sending the face tag file to the user terminal, the signature file being named and archived at the agent end. user terminal.

Abstract: The present invention relates to use of an Anaplasma phagocytophilum protein APH1384 as diagnostic antigen for granulocytic anaplasmosis. The protein can remedy the drawback of missed detection of an existing diagnostic antigen P44 for granulocytic anaplasmosis, improve sensitivity of detection for granulocytic anaplasmosis, and facilitate rapid and accurate clinical diagnosis of granulocytic anaplasmosis.

Abstract: A method includes applying a voltage to a wafer or a device under test (DUT). The wafer or the DUT is illuminated with an electron beam after applying the voltage to the wafer or the DUT. Cathodoluminescent light emitted from the wafer or the DUT in response to the electron beam is detected. One or more characteristics of the wafer or the DUT are determined based on the detected cathodoluminescent light.

Abstract: A wafer and DUT inspection apparatus and a wafer and DUT inspection method using thereof are provided. The apparatus includes a vacuum chamber, a stage, an electron gun, a lens system, an optical mirror and a detector. In the vacuum chamber, the stage is disposed near a first end, and the electron gun is disposed near a second end opposite to the first end. The lens system disposed between the stage and the electron gun is a total reflective achromatic lens system including a first lens and a second lens. The second lens having a second aperture is disposed between the electron gun and the first lens having a first aperture aligned with the second aperture. The optical mirror is disposed between the lens system and the electron gun. The detector is horizontally aligned with the optical mirror and configured to detect cathodoluminescence reflected from the optical mirror.

Abstract: A wafer and DUT inspection apparatus and a wafer and DUT inspection method using thereof are provided. The apparatus includes a vacuum chamber, a stage, an electron gun, a lens system, an optical mirror and a detector. In the vacuum chamber, the stage is disposed near a first end, and the electron gun is disposed near a second end opposite to the first end. The lens system disposed between the stage and the electron gun is a total reflective achromatic lens system including a first lens and a second lens. The second lens having a second aperture is disposed between the electron gun and the first lens having a first aperture aligned with the second aperture. The optical mirror is disposed between the lens system and the electron gun. The detector is horizontally aligned with the optical mirror and configured to detect cathodoluminescence reflected from the optical mirror.

Abstract: Crosslinkable compounds useful for making hole-transporting materials for organic light-emitting devices, hole-transporting layers made from the crosslinkable compounds, and light-emitting devices that include the hole-transporting layers.

Abstract: Crosslinkable compounds useful for making hole-transporting materials for organic light-emitting devices, hole-transporting layers made from the crosslinkable compounds, and light-emitting devices that include the hole-transporting layers.

Abstract: Polymers and compounds having high-triplet-energy; guest-host films comprising the polymers or compounds as hosts and phosphorescent compounds as guests; and electroluminescent devices that include the films.

Abstract: An electroluminescent device having improved efficiency and stability through the incorporation of a surfactant layer intermediate the cathode and emissive layer.

Abstract: A light microscope comprises a light source and a first acousto-optic tunable filter responsive to the light source for producing two light streams of different polarization. A control circuit is provided for tuning the first filter to a plurality of frequencies. A mechanism, such as steering optics, is provided for combining the two light streams into a combined light stream. Input optics focus the combined light stream. A condenser, such as a darkfield condenser, receives the focused, combined, light stream and projects it onto a sample. A second acousto-optic tunable filter is responsive to light from the sample. A second control circuit is provided for tuning the second acousto-optic filter to a plurality of frequencies. The light from the second acousto-optic tunable filter may be captured and stored for future processing.

Abstract: An imaging system comprises an acousto-optic tunable filter for receiving light at an input end thereof and outputting light at an output end thereof. A control circuit is provided for tuning the filter. A prism is responsive to the light output by the tunable filter. The prism is oriented at an angle with respect to the filter to compensate for dispersion of the output light caused by the tunable filter.