Abstract: The caching method for F-RAN based communications in a mmWave communication system includes receiving a request for a network function generated from a requesting mobile station at a layer-two fog node closest to the requesting mobile station. In a clustered caching method, the network functions a cached on a layer-three cluster fog node servicing a cluster or layer two fog nodes. In a distributed caching method, a single, unique network function is cached on each of the layer-two fog nodes in the cluster, which are serially polled until the requested network function. The requested network function is executed at the layer-two or layer three fog node having the network function cached thereon in order to reduce fronthaul communications with layer four cloud nodes for greater efficiency.

Abstract: The initial beam access method for a mobile station in a mmWave cellular network having a base station and multiple mobile stations includes a method having steps of probing a channel for information about the base station from the multiple mobile stations; receiving information from the multiple mobile stations on the direction of the base station in relation to a reference point; and adjusting the direction of the base station based on the received information and the reference point using a digital compass.

Abstract: A health monitoring device is provided, and may be used in population health monitoring and disease tracing, as well as for individual subject health purposes. The health monitoring device comprises a triboelectric nanogenerator (TENG) for generating and storing electrical energy from mechanical activity of a user. The device provides a continuous and uninterrupted stream of physiological data received at a surface of the device in contact with a surface of the user. The triboelectric nanogenerator is a paper-based device comprising a paper-based material layer and a polydimethylsiloxane/polytetrafluoroethylene (PDMS/PTFE) material layer, each on a copper film. The device has enhanced sensitivity to motion, providing an improved device capable of converting small amounts of movement into electrical energy, and of recording and transmitting data of small physiological changes of a user to a receiver. The device is lithium free, and eliminates the necessity of recharging.

Abstract: A power and/or electricity generating source and/or component that is TENG-based, and that may be configured as an assembly and/or component for powering one or more electronic devices, is disclosed, A case, carrier or other carrying container, for example a case for a cell phone, ipad, electronic tablet, personal computer, or any similar device, that provides an electricity source to power the cell phone, ipad, electronic tablet, is disclosed. The energy generating carriers and/or containers and configurations thereof, also provide an electricity energy storage source. This electronic energy storage source may be incorporated within an electronic device itself, or may be incorporated within the case and/or covering. Upon walking or touching a surface of an electronic device, the power generating source will harness mechanical energy, and provide for the generation of electricity with the one or more TENG components (TESTEC) that comprise the energy generating unit. Metal particles (silver, copper, etc.

Abstract: A health monitoring device is provided, and may be used in population health monitoring and disease tracing, as well as for individual subject health purposes. The health monitoring device comprises a triboelectric nanogenerator (TENG) for generating and storing electrical energy from mechanical activity of a user. The device provides a continuous and uninterrupted stream of physiological data received at a surface of the device in contact with a surface of the user. The triboelectric nanogenerator is a paper-based device comprising a paper-based material layer and a polydimethylsiloxane/polytetrafluoroethylene (PDMS/PTFE) material layer, each on a copper film. The device has enhanced sensitivity to motion, providing an improved device capable of converting small amounts of movement into electrical energy, and of recording and transmitting data of small physiological changes of a user to a receiver. The device is lithium free, and eliminates the necessity of recharging.

Abstract: A method for forming a metallic nanoparticle and semiconductor coated fiber material is provided. The method can include the steps of coating at least one surface of a material, for example a textile material, with a semiconducting layer, and growing metallic nanoparticles on the semiconducting layer. The steps for coating the surface of the material with a semiconducting layer can include forming a titanium dioxide film on the surface of the textile material. The steps for forming metallic nanoparticles on a semiconducting layer can include immersing the coated textile layer in a metallic nanoparticle precursor solution, drying the coated textile layer and exposing the textile layer to UV radiation. The metallic nanoparticles can include gold and/or silver nanoparticles. Also disclosed are materials having a least one treated surface coated with metallic nanoparticles. The treated surface may comprise the surface of a textile material treated according to the methods provided herein.

Abstract: A method for forming superior and stable metallic nanoparticle and semiconductor coated fiber materials is provided. The method can include the steps of coating at least one surface of a material, for example a textile material, with a semiconducting layer, and growing metallic nanoparticles directly on the semiconducting layer. The steps for coating the surface of the material with a semiconducting layer can include forming a titanium dioxide film on the surface of the textile material, immersing the coated textile layer in a metallic nanoparticle precursor solution, drying the coated textile layer and exposing the textile layer to UV radiation. The metallic nanoparticles can include gold and/or silver nanoparticles. Also disclosed are materials resistant to microbes, including bacteria and viruses. These materials comprise at least one treated surface coated with metallic nanoparticles. The treated surface may comprise the surface of a textile material, such as a cotton fiber surface.