Abstract: A modular blade connection structure includes a first module, a second module and a structural adhesive module. The first module is provided on an end face thereof with a bonding flange extending into the second module; a gap between the butting surfaces of the first module and the second module is injected with a structural adhesive, which is extruded and cured to form a structural adhesive module; and the thickness of the first module at the starting end of the bonding flange extends towards the inner surface to form a first reinforcement, and the structural adhesive module extends inside the second module in a direction away from the bonding flange to form a second reinforcement. The present disclosure facilitates the control the bonding quality of the double-sided overlapping of the modular blade by means of the bonding flange and the improvement of the fatigue resistance at the assembling position.

Abstract: Methods and apparatuses for AM of all-in-one radiation shielding components from multi-material metal alloys, metal matrix, MMCs, and/or gradated compositions of the same are disclosed, comprising: providing an apparatus having: an energy source; a scanner; a powder system for powder(s); a powder delivery system; a shielding gas; and a computer coupled to and configured to control the energy source, scanner, powder system, and powder delivery system to deposit layers of the sample; programming the computer with specifications of the sample; using the computer to control electromagnetic radiation, mixing ratio, and powder deposition parameters based on the specifications of the sample; and using the autofocusing scanner to focus and scan the electromagnetic radiation onto the sample while the powders are concurrently deposited by the powder delivery system onto the sample to create a melting pool to deposit one or more layers onto the sample. Other embodiments are described and claimed.

Abstract: Methods and systems for surface structuring to increase emissivity of one or more samples comprising: generating electromagnetic radiation from a femtosecond fiber laser, wherein the electromagnetic radiation comprises a wavelength, a pulse repetition rate, a pulse width, a pulse energy, and an average power; coupling the electromagnetic radiation from the femtosecond fiber laser to an autofocusing scanner, wherein the autofocusing scanner is configured to scan and focus the electromagnetic radiation onto the one or more samples; and using a computer to adjust the pulse repetition rate and the pulse energy of the femtosecond fiber laser and to control the autofocusing scanner to scan and focus the electromagnetic radiation onto the one or more samples to fabricate micro spikes onto the surface of the one or more samples in order to increase the emissivity of the one or more samples. Other embodiments are described and claimed.

Abstract: A video editing apparatus includes a recognition unit that recognizes a target that is captured in a video for a time period, a registration unit that registers therein the target, recognized by the recognition unit, in association with the time period, and a display that displays, in response to reception of information, an image in which the target associated with the time period and identified by the information is recognized.

Abstract: Methods and systems for enhanced SERS sensing are disclosed, including generating electromagnetic radiation from a fiber laser; coupling the radiation to a SERS sensor comprising: a fiber comprising a first end and a second end, wherein the first end is coupled to the fiber laser and the second end is deposited with one or more metal nanoparticles; an in-line fiber grating integrated into the fiber between the first and the second end; a spectrometer configured to measure a spectrum produced by the in-line fiber grating; and a micro-processor configured to control the fiber laser and the spectrometer; exciting one or more molecules adsorbed on the surface of the one or more metal nanoparticles to generate a Raman signal; coupling the signal into the fiber; separating the signal into its wavelength components with the in-line fiber grating; and measuring the wavelength components with the spectrometer. Other embodiments are described and claimed.

Abstract: The present invention concerns dosing of anti-EGFL7 antibodies for cancer therapy.

Abstract: Methods and systems for enhanced SERS sensing are disclosed, including generating electromagnetic radiation from a fiber laser; coupling the radiation to a SERS sensor comprising: a fiber comprising a first end and a second end, wherein the first end is coupled to the fiber laser and the second end is deposited with one or more metal nanoparticles; an in-line fiber grating integrated into the fiber between the first and the second end; a spectrometer configured to measure a spectrum produced by the in-line fiber grating; and a micro-processor configured to control the fiber laser and the spectrometer; exciting one or more molecules adsorbed on the surface of the one or more metal nanoparticles to generate a Raman signal; coupling the signal into the fiber; separating the signal into its wavelength components with the in-line fiber grating; and measuring the wavelength components with the spectrometer. Other embodiments are described and claimed.