Abstract: Disclosed are an image processing method and an electronic device, applied to the field of image processing technologies. The method includes: turning on a camera; obtaining a zoom ratio and an environmental illuminance in a current photographing environment; and performing photographing in a first mode when the zoom ratio is greater than or equal to a first ratio and the environmental illuminance is greater than or equal to a first luminance threshold, where in the first mode, the camera is configured to: process an acquired image signal in a non-binning mode and in a cropping manner, to output first image data, where a first image format is used for the first image data.

Abstract: An image processing method and an electronic device are disclosed. The image processing method includes: displaying a first screen in a first shooting mode, where the first screen includes a first control; detecting a first operation on the first control; in response to the first operation, determining a first mapping in gamma processing and a second mapping in a two-dimensional lookup table, where the first mapping corresponds to the first control, the second mapping corresponds to the first control, and the first mapping is associated with the second mapping; obtaining a to-be-processed image; and processing the to-be-processed image based on the first mapping and the second mapping to obtain a first image. On the basis of the technical method of this application, computational load of electronic devices during image processing can be effectively reduced.

Abstract: The described technology is generally directed towards interoperability between distributed units (DUs) and radio units (RUs) in a radio access network (RAN) network. Various embodiments are presented to enable automated determination and/or automated implementation of various configurations and functionalities on a physical random access channel (PRACH) between a DU and a RU. The automated operations presented herein enable a DU to discover and verify PRACH functionality (e.g., regarding PRACH time offset) supported by a RU and/or implementation of the PRACH functionality at the RU to enable interoperability between the DU and the RU, thereby satisfying the interoperability requirement of the O-RAN specification.

Abstract: A method for manufacturing a flexible sensor, including: dispersing graphene in a polymeric material; adding a carbon nanotube into the polymeric material; applying an alternating electric field to the polymeric material added with the carbon nanotube to obtain a composite material; attaching a polymeric material film to the obtained composite material; pre-embedding carbon fibers; and heating and curing to obtain a sensor. A CNT bridging effect and an electric field induced arrangement are introduced at an appropriate ratio of polymeric materials such as graphene-PDMS or PMMA to improve a dry-blended method. The flexible sensor manufactured by the improved dry-blended method improves electrical conductivity, a piezoresistive property and a mechanical property of CNT-graphene-PDMS or PMMA and other polymeric materials.

Abstract: The presently disclosed subject matter provides methods, compositions, and kits for assessing the viability of bacteria from a selected genus, assessing the antibiotic susceptibility of bacteria from the selected genus, and identifying compounds with anti-persister activity for bacteria from the selected genus. The bacteria include, but are not limited to, Borrelia burgdorferi, Staphylococcus aureus, Escherichia coli, Klebsiella pneumoniae, Acinetobacter baumanii, and Mycobacterium tuberculosis. Compositions include compounds with high activity against Borrelia persisters and their combinations with current Lyme antibiotics for more effect treatment of Lyme disease. Methods for inhibiting the growth and/or survival of bacteria from the Borrelia genus and for treating Lyme disease using appropriate drug combinations in a subject are also provided.