Abstract: An antenna includes a patch radiator, a feed point, a first ground point, and a second ground point. The patch radiator has a first side edge and an intersecting second side edge, and a first coupling contact and a second coupling contact. The patch radiator is coupled to the first ground point and the second ground point through the first coupling contact and the second coupling contact, and is biased coupled to the feed point. A distance between the first coupling contact and the first side edge, a distance between the first coupling contact and the second side edge, a distance between the second coupling contact and the first side edge, and a distance between the second coupling contact and the second side edge are all greater than or equal to 0.05?, where ? is an operating wavelength of the antenna in an operating frequency band range of the antenna.

Abstract: The present disclosure provides a semiconductor structure and a manufacturing method thereof, and relates to the technical field of semiconductors. The semiconductor structure includes an interconnecting line layer, wherein the interconnecting line layer includes a first region and a second region, and the first region includes a first alignment mark thereon; an isolation structure disposed in the second region of the interconnecting line layer; and a redistribution layer conformally covering the first region of the interconnecting line layer and the isolation structure, wherein the redistribution layer includes a second alignment mark, and the second alignment mark is located above the first alignment mark.

Abstract: Embodiments provide a semiconductor device and a fabrication method. The fabrication method includes: providing a substrate including an alignment region and a connection region; forming a first conductive layer on the substrate; forming a spacer material layer group on the first conductive layer; forming a protective layer on the spacer material layer group, the protective layer being positioned on the alignment region; etching the spacer material layer group and the protective layer, an etching rate of the protective layer being less than an etching rate of the spacer material layer group to remove the spacer material layer group on the connection region to form a spacer layer group, and forming an alignment groove on the spacer layer group in the alignment region; and forming a second conductive layer group on the spacer layer group and the first conductive layer, the second conductive layer group covering the alignment groove.

Abstract: Aspects of the invention include splitting a first file retrieved from a first cloud computing environment of a hybrid cloud computing environment into multiple chunks. A respective chunk signature is calculated for each chunk of the multiple chunks, wherein the calculation is based at least in part on static metadata and the dynamic metadata retrieved from the first file. The respective chunk signatures are compared to chunk signatures from a metadata repository to identify a duplicate second file, wherein the first file is a variant of a second file stored in a second cloud computing environment of the hybrid cloud computing environment. Either the first file or the second file is selected as candidate for deletion. The candidate for deletion is deleted.

Abstract: A system comprises a first ear-worn electronic device configured to be worn by a wearer, and a second electronic device comprising a second ear-worn electronic device or other electronic device. A wireless transceiver operably coupled to an antenna is disposed in each of the electronic devices. One or both of the first ear-worn electronic device and the second electronic device are configured to transmit signals at a plurality of different frequencies in accordance with a frequency hopping sequence, collect 2-D RSSI data comprising an RSSI value as a function of frequency and of time in response to transmission of the signals, detect a particular input gesture of a plurality of input gestures of the wearer using the 2-D RSSI data, and implement a predetermined function of at least one of the first ear-worn electronic device and the second electronic device in response to detecting the particular input gesture.

Abstract: The present disclosure provides a method for manufacturing a low loss ferrule assembly having prefabricated optical fibers, a low loss ferrule assembly having prefabricated optical fibers manufactured according to the method and an optical fiber fixing mold for manufacturing the ferrule assembly, wherein a method for manufacturing a high-precision ferrule assembly comprises: disposing both ends of a plurality of optical fibers within a plurality of grooves at both ends of an optical fiber fixing mold, such that the plurality of optical fibers maintain a specific distance therebetween; disposing the plurality of optical fibers within a housing, and causing the plurality of optical fibers to be fixed relative to the housing, wherein the housing is of a split type; cutting and polishing the optical fibers at a first side of the housing. The solution provided by the present disclosure implements the ferrule assembly of the high-precision optical fiber connector with low costs.

Abstract: An ear-worn electronic device is configured to be worn by a wearer and comprises a wireless transceiver operably coupled to an antenna. The device is configured to transmit, from the transceiver to the antenna, signals at a plurality of different frequencies in accordance with a frequency hopping sequence. The device is configured collect two-dimensional (2-D) reflection coefficient data comprising a reflection coefficient of the antenna as a function of frequency and of time in response to transmission of the signals. The device is configured to detect a particular input gesture of a plurality of input gestures of the wearer using the 2-D reflection coefficient data, and implement a predetermined function of the ear-worn electronic device in response to detecting the particular input gesture.

Abstract: An ear-worn electronic device is configured to be worn by a wearer and comprises a housing configured to be supported at, by, in or on the wearer's ear. A processor is disposed in the housing, and a speaker or a receiver is operably coupled to the processor. A radio frequency transceiver is disposed in the housing and operably coupled to the processor. A battery/antenna module is disposed in the housing and comprises a battery, a helical antenna wrapped around the battery, and electrically insulating material disposed between the helical antenna and the battery. The helical antenna is operably coupled to the transceiver.

Abstract: An ear-worn electronic device is configured to be worn by a wearer and comprises a housing configured to be supported at, by, in or on the wearer's ear. A processor is disposed in the housing, and a speaker or a receiver is operably coupled to the processor. A radio frequency transceiver is disposed in the housing and operably coupled to the processor. A battery/antenna module is disposed in the housing and comprises a battery, a helical antenna wrapped around the battery, and electrically insulating material disposed between the helical antenna and the battery. The helical antenna is operably coupled to the transceiver.

Abstract: The present disclosure provides a method for manufacturing a low loss ferrule assembly having prefabricated optical fibers, a low loss ferrule assembly having prefabricated optical fibers manufactured according to the method and an optical fiber fixing mold for manufacturing the ferrule assembly, wherein a method for manufacturing a high-precision ferrule assembly comprises: disposing both ends of a plurality of optical fibers within a plurality of grooves at both ends of an optical fiber fixing mold, such that the plurality of optical fibers maintain a specific distance therebetween; disposing the plurality of optical fibers within a housing, and causing the plurality of optical fibers to be fixed relative to the housing, wherein the housing is of a split type; cutting and polishing the optical fibers at a first side of the housing. The solution provided by the present disclosure implements the ferrule assembly of the high-precision optical fiber connector with low costs.

Abstract: An ear-worn electronic device is adapted to be worn at, by, in or on an ear of a wearer. The device comprises a housing configured to be supported at, by, in or on the wearer's ear. A processor is disposed in the housing. A speaker or a receiver is coupled to the processor. A radio frequency transceiver is disposed in the housing and coupled to the processor. An antenna arrangement is disposed in or on the housing and coupled to the transceiver. The antenna arrangement comprises a primary antenna and a chip antenna connected to the primary antenna. The primary antenna serves as a counterpoise for the chip antenna and feeds the chip antenna.

Abstract: An ear-worn electronic device is configured to be worn by a wearer and comprises a housing configured to be supported at, by, in or on the wearer's ear. A processor is disposed in the housing, and a speaker or a receiver is operably coupled to the processor. A radio frequency transceiver is disposed in the housing and operably coupled to the processor. A battery/antenna module is disposed in the housing and comprises a battery, a helical antenna wrapped around the battery, and electrically insulating material disposed between the helical antenna and the battery. The helical antenna is operably coupled to the transceiver.

Abstract: An ear-worn electronic device is adapted to be worn at, by, in or on an ear of a wearer. The device comprises a housing configured to be supported at, by, in or on the wearer's ear. A processor is disposed in the housing. A speaker or a receiver is coupled to the processor. A radio frequency transceiver is disposed in the housing and coupled to the processor. An antenna arrangement is disposed in or on the housing and coupled to the transceiver. The antenna arrangement comprises a primary antenna and a chip antenna connected to the primary antenna. The primary antenna serves as a counterpoise for the chip antenna and feeds the chip antenna.

Abstract: A tool for preparing the end of a fiber optic cable for termination to a fiber optic connector can include a hand-held tool capable of scoring the jacket of the cable and cutting the cable. The scoring and cutting operations can be performed in one action or motion. The scoring and cutting locations can be spaced by a predetermined distance to bare a predetermined length of optical fiber. The tool may include a staging area for holding a heat-shrink sleeve, clamp, and boot in alignment while the cable is being processed. The tool also may include a cutting component for cutting strength members of the cable; and a clamp docking station to align the cable with the cutting component.

Abstract: Measurements made by a multi-component induction logging tool are corrected for tool eccentricity in a deviated borehole. The eccentricity angle is determined from single frequency skin-effect corrected data and is then used to correct multifrequency data. Multifrequency focusing is then applied to the corrected multifrequency data. An inversion is then used to recover formation resistivity and relative dip and azimuth of the borehole.

Abstract: Measurements made by a multi-component induction logging tool are corrected for tool eccentricity in a deviated borehole. The eccentricity angle is determined from single frequency skin-effect corrected data and is then used to correct multifrequency data. Multifrequency focusing is then applied to the corrected multifrequency data. An inversion is then used to recover formation resistivity and relative dip and azimuth of the borehole.

Abstract: Measurements made by a multi-component induction logging tool are corrected for tool eccentricity in a deviated borehole. The eccentricity angle is determined from single frequency skin-effect corrected data and is then used to correct multifrequency data. Multifrequency focusing is then applied to the corrected multifrequency data. An inversion is then used to recover formation resistivity and relative dip and azimuth of the borehole. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Measurements made by a multi-component induction logging tool are corrected for tool eccentricity in a deviated borehole. The eccentricity angle is determined from single frequency skin-effect corrected data and is then used to correct multifrequency data. Multifrequency focusing is then applied to the corrected multifrequency data. An inversion is then used to recover formation resistivity and relative dip and azimuth of the borehole. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).