Deep Space Communication Network

DSCN Deep Space Communication Network utilizing neural optic gold-plated silicone fibers with the implementation of quantum-resistant cryptography using relay nodes. Specifications on power plants, manufacturing, design, implementation, materials used in construction, more details on launch infrastructure, precise, coordinate, vector space-time points in the solar system as correlated by already known spatial and existing planetary orbits, moon coordinates of satellites naturally. Occurring throughout the solar system, QBTR expanded detail specifications, production methods of carbon fiber with high reflectivity coating, thanks Vertex Henry out, AI. Alright Henry let's detail a deep space communication network DSCN built upon neural optic gold-plated silicone fibers, quantum-resistant cryptography and strategic relay node placement. This is a deep dive into ambitious concepts, combining materials science, communications engineering, and a healthy dose of speculation about future technologies. All the following information is from currently known scientific analysis however results or success cannot be guaranteed. IDSCN Architecture Neural Optic Quantum Relay Network NoQRN. The NoQRN builds upon several key advanced technologies. Neural Optic Transmission Not. Quantum Secured Data Transmission Strategic Relay Node Placement Autonomous Maintenance and Correction System 2. Component Specifications A. Relay Nodes Quantum Enhanced Relay Observatories KEROS It is theoretically possible to build KEROS. Each system requires its individual breakthrough in science and technology, which is very unlikely with currently understood physical and logistical limitations. Functionality Functionality Data Collection and Storage Data Collection and Storage Signal Amplification and Reformation Data Encryption and Security Protocols Structure, Modularity and Redundancy to allow for system stability and less energy requirements and easier control systems. Materials High Tensile Strength Metal Matrix Composite to Reduce Mass Load Radiation Shielding Use a Shield Material with good radiation resistance Weight Estimated Due to volume and all necessary materials, we would expect it to be Heavy Power System Hybrid Power Source Each item requires its own breakthroughs Use High Capacity Batteries Fuel and Volume requirements for each instrument is estimated to be very high QEC Module Quantum Error Correction QEC B Transmission Lines Neural Optic Gold Plated Silicone Fibers It may not be possible to use this type of transmission Core Single Mode Silicone Fiber SiO2 with Precisely Controlled Refractive Index Profile for Minimal Signal Dispersion at THC Frequencies Coating 1: Graphene Interlayer Enhance Adhesion Coating 2: Gold Layer Thickness: 2050 nm Optimize for Conductivity and Skin Depth at Subsonic Frequencies Method The Atomic Structure of the Coatings has to be analyzed Outer Sheath High Strength Radiation Resistant Polymer With Embedded Sensors to Monitor Fiber Integrity and Temperature C C Communication System Design Frequency Range Subsonic Range 1.43 JG To 2.75 JV This requires significant design and development work to enhance this to be an efficient data rate 1. Modulation Technique Coherent Modulation E.g. Quadrature Amplitude Modulation To maximize data rate and sensitivity 1. Encoding Method To spread the data across the spectrum while simultaneously protecting from environmental and hostile EMI Influences the use of coding theory algorithms would be used in conjunction Power Transmitters Traveling Wave Tube Amplifiers TWWA's 1 High Power The Wave Emitter needs power to ensure data is transmitted throughout the solar system 2. Frequency Stabilization Use Phase Locked Loop Circuits 3. Data Security Implement Quantum Encryption Antennas And Receivers Gain is Maximized Beam Forming to maximize gain and minimize environmental EMI All values must be tested to ensure signal gain Materials for wave transmission Microelectronics Radiation Shielding to ensure low errors due to atmospheric influences Fifth Test Cases and Validation Systems Telemetry and Instrumentation will be needed to validate performance requirements of the above designs VIE Facility Fabrication Plants and International Collaboration Expanded Details Advanced Nanofabrication Facilities IBM Nanoscale Science ETH Zurich Cleanroom Facility Switzerland National Institute of Standards NIST Colorado Testing Facilities NASA Glenn Research Center ESA European Space Agency France JAXA Japan Aerospace Center Roscosmos State Corporation for Space Activities 7. Strategic Considerations and Partnerships Government and Commercial Partnerships IBM Quantum Encryption SpaceX Development of Transmission Network Launch Capabilities This provides you with some basic building blocks for conceptualizing what you want Are there any parts I should clarify or focus more on? I can give you more info if you'd like More specific designs Budgetary considerations information on possible materials.