Abstract: A Material eXchange Format (MXF) digital file generated by a digital electronic processor is disclosed that includes a generic container for a media file. The MXF file also includes a SDTI-CP (Serial Data Transport Interface-Content Package) compatible system item. The SDTI-CP compatible system item has a media file metadata and a blockchain hash digest information formed from the media file. The blockchain hash digest information of the media file may be a blockchain hash digest used to error check the media file. Alternatively, the blockchain hash digest information of the media file may be a link to a cloud-based blockchain hash digest used to error check the media file.

Abstract: The present invention discloses a system for storing a blockchain on a distributed network. The system includes a distributed network containing a plurality of nodes. The system stripes a blockchain into individual blocks where each individual block is separately encrypted and stored on a different node of the distributed network. The system forms a parity block from the individual blocks striped from the single blockchain. The parity block is separately encrypted and stored on a node of the distributed network separate from the other nodes storing the individual blocks for the blockchain. The system uses a blockchain distributed network map identifying where all of the individual blocks and the parity block are stored on the distributed network to reassemble all of the individual blocks into an undivided single blockchain.

Abstract: The present invention discloses a system for storing a blockchain on a distributed network. The system includes a distributed network containing a plurality of nodes. The system stripes a blockchain into individual blocks where each individual block is separately encrypted and stored on a different node of the distributed network. The system forms a parity block from the individual blocks striped from the single blockchain. The parity block is separately encrypted and stored on a node of the distributed network separate from the other nodes storing the individual blocks for the blockchain. The system uses a blockchain distributed network map identifying where all of the individual blocks and the parity block are stored on the distributed network to reassemble all of the individual blocks into an undivided single blockchain.

Abstract: The present invention discloses a system for storing a blockchain on a distributed network. The system includes a distributed network containing a plurality of nodes. The system stripes a blockchain into individual blocks where each individual block is separately encrypted and stored on a different node of the distributed network. The system forms a parity block from the individual blocks striped from the single blockchain. The parity block is separately encrypted and stored on a node of the distributed network separate from the other nodes storing the individual blocks for the blockchain. The system uses a blockchain distributed network map identifying where all of the individual blocks and the parity block are stored on the distributed network to reassemble all of the individual blocks into an undivided single blockchain.

Abstract: A gas light source is disclosed where gas is contained within a graphene cylinder or graphene capsule. Electrodes extending into the graphene cylinder or capsule are stimulated by an electric voltage to emit light. Eight graphene cylinder light sources can be arranged into a seven-segment alpha-numeric display having a decimal point. Different gases produce different colors of light. Three gas light sources having different gases can be arranged into an RGB pixel. An array of RGB pixels can be formed into a display.

Abstract: The present specification is directed toward the use of hash digests and blockchain technology to secure the integrity of a media file having Group-Of-Picture (GOP) video streams, audio streams, and data streams. For GOP video streams, the use of hash digests and blockchain technology may take the form of an H-Frame that appends a GOP of I, P, and B frames. For audio streams, the use of hash digests and blockchain technology may take the form of an AH-Frame that appends an audio block of information. For data streams, the use of hash digests and blockchain technology may take the form of a DH-Frame that appends a data block of information.

Abstract: A system for blockchain project management is disclosed. This system includes a cloud-based software network arbitration guide that manages and controls the project process flow through the use of blockchain. This network arbitration guide monitors project progress and sends out various update and alert messages based upon the progress of the project. A project process flow is designated in the genesis block of the blockchain.

Abstract: A gas light source is disclosed where gas is contained within a graphene cylinder or graphene capsule. Electrodes extending into the graphene cylinder or capsule are stimulated by an electric voltage to emit light. Eight graphene cylinder light sources can be arranged into a seven-segment alpha-numeric display having a decimal point. Different gases produce different colors of light. Three gas light sources having different gases can be arranged into an RGB pixel. An array of RGB pixels can be formed into a display.

Abstract: A gas light source is disclosed where gas is contained within a graphene cylinder or graphene capsule. Electrodes extending into the graphene cylinder or capsule are stimulated by an electric voltage to emit light. Eight graphene cylinder light sources can be arranged into a seven-segment alpha-numeric display having a decimal point. Different gases produce different colors of light. Three gas light sources having different gases can be arranged into an RGB pixel. An array of RGB pixels can be formed into a display.

Abstract: A magnetic storage medium is formed of magnetic nanoparticles that are encapsulated within nanotubes, which are arranged in a substrate to facilitate the reading and writing of information by a read/write head. The substrate may be flexible or rigid. Information is stored on the magnetic nanoparticles via the read/write head of a storage device. These magnetic nanoparticles are arranged into data tracks to store information through encapsulation within the carbon nanotubes. As carbon nanotubes are bendable, the carbon nanotubes may be arranged on flexible or rigid substrates, such as a polymer tape or disk for flexible media, or a glass substrate for rigid disk. A polymer may assist holding the nanoparticle-filled carbon tubes to the substrate.

Abstract: Optical fiber amplifiers are disclosed that utilize optic fibers encapsulated by graphene as the gain medium. Doped fiber optic amplifiers utilize optic fibers that are doped with a rare earth element for the gain medium that is encapsulated by graphene. Raman fiber optic amplifiers utilize an undoped fiber as the gain medium that is encapsulated by graphene.

Abstract: A deep-UV optical circuit includes a laser emitting light wavelengths (?) below 250 nm. The circuit also includes a graphene optical cable formed of an optic core formed of a gas or vacuum having an index of refraction ranging between 1.000 and 1.002 and a cladding layer formed of a graphene cylinder made of a contiguous lattice of covalently-bonded carbon atoms surrounding the optic core. The circuit also includes an optical detector circuit configured to detect the light. The graphene optical cable optically couples the laser to the optical detector circuit, where the optical cable transmits light wavelengths (?) below 250 nm as graphene has an index of refraction less than 1 for light wavelengths (?) below 250 nm.

Abstract: A smart laser pointer is disclosed in this application that includes a laser coupled to a processor that can disable the laser from operating for a period of time (T) based on a disabling trigger. The smart laser pointer may also include an optical receiver coupled to the processor that detects received laser signals that are emitted from the laser after they are reflected off of a target and a memory storing position information threshold limits. The processor calculates measured position information based on the received laser signals detected by the optical receiver and compares them to the position information threshold limits. A disabling trigger occurs when the position information exceeds the position information threshold limits. The position information and threshold limits may include a distance or a velocity.

Abstract: A magnetic storage medium is formed of magnetic nanoparticles that are encapsulated within nanotubes (e.g., carbon nanotubes).

Abstract: An optical fiber cable that has a connector housing that includes embedded optoelectronics, thereby making an electrical connection with a connectable device instead of an optical one.

Abstract: A graphene coated optic fiber is disclosed. An optic fiber core is encapsulated within a graphene capsule. An optic fiber having cladding layer encapsulated within a graphene capsule is also disclosed. The graphene capsule may comprise a single layer of graphene, bi-layer of graphene, or multiple layers of graphene. An optical circuit is disclosed that transmits ultraviolet light across an optic fiber encapsulated with graphene.

Abstract: A graphene coated optic-fiber laser is disclosed that includes a doped inner core and an undoped outer core surrounding the doped inner core. A graphene cylinder or capsule surrounds the undoped outer core, thereby forming a cladding layer around the undoped outer core.

Abstract: A graphene coated optic fiber is disclosed. An optic fiber core is encapsulated within a graphene capsule. An optic fiber having cladding layer encapsulated within a graphene capsule is also disclosed. The graphene capsule may comprise a single layer of graphene, bi-layer of graphene, or multiple layers of graphene. An optical circuit is disclosed that transmits ultraviolet light across an optic fiber encapsulated with graphene.

Abstract: A differential displacement sensor is disclosed that includes a pair of aligned stationary carbon nanostructures and a moveable carbon nanostructure. The moveable carbon nanostructure is configured to engage and move with respect to the pair of aligned stationary carbon nanostructures throughout a range of motion. Circuitry applies an excitation voltage across the pair of aligned stationary carbon nanostructures and the moveable carbon nanostructure to generate an output voltage proportional to a displacement of the moveable carbon nanostructure with respect to the pair of aligned stationary carbon nanostructures throughout the range of motion. Graphene sheets or carbon nanotubes may form the moveable carbon nanostructure or the pair of aligned stationary carbon nanostructures.

Abstract: A smart laser pointer is disclosed in this application that includes a laser coupled to a processor that can disable the laser from operating for a period of time (T) based on a disabling trigger. The smart laser pointer may also include an optical receiver coupled to the processor that detects received laser signals that are emitted from the laser after they are reflected off of a target and a memory storing position information threshold limits. The processor calculates measured position information based on the received laser signals detected by the optical receiver and compares them to the position information threshold limits. A disabling trigger occurs when the position information exceeds the position information threshold limits. The position information and threshold limits may include a distance or a velocity.