Optimize resources between nodes in a cluster:

System Overview:

System Goal: Optimize the allocation and use of resources, goods and services between nodes in a cluster. Nodes can be software programs, individuals, machines, organizations, and any other entities that can exchange resources.

Platform Function: Not only promotes the exchange and sharing of resources, but also significantly reduces the legal costs and time of short-term or long-term cooperation.

Technical Features:

Blockchain Technology: Use blockchain ledgers to store smart contracts and transaction records to enhance the transparency and security of transactions.

Distributed Operating System: Deploy the Space Operating System (SOS) network to manage the resources and services of nodes, including processing, storage, energy, and communication.

Smart Contract Management: The system supports and manages smart contracts between nodes to promote automated transactions and resource allocation.

Resource Management and Optimization:

Resource Manager (ROME): Used to optimally allocate resources, goods and services between nodes, and maximize resource utilization through optimization standards and rules.

Resource Allocation Table: Dynamically update the resource allocation table to ensure efficient resource allocation and transparent transactions.

Internal certificates (CCs): Issue internal certificates to nodes as proof of contribution to shared resources, which can be used to exchange resources such as processing power, energy, communication and storage.

Nodes and communication:

Node diversity: Nodes in the cluster include software programs, individuals, machines, computing devices, organizations, etc., which are interconnected through the SOS network.

Efficient communication: Supports multiple communication protocols and technologies, including CCSDS, GNU Radio, quantum communication, etc., to ensure efficient data transmission.

Application scenarios:

Space industry: Especially suitable for space data communication and services, solving the problems of high cost and low efficiency of existing systems.

Distributed base stations and satellite constellations: Significantly enhance resource sharing and service exchange between distributed base stations and satellite constellation systems.

Multi-industry applications: Can be extended to other industries to achieve efficient sharing of resources and services.

Economic incentives and cooperation:

Contribution incentive mechanism: Incentivize nodes to share resources by issuing internal certificates (CCs) to promote the self-organization and sustainable development of the network.

Transparent market: Establish a nearly perfect market with full transparency of information between buyers and sellers to avoid monopoly and market manipulation.

Collaborative economy: Based on the theory of collaborative sharing economy, promote resource sharing and cooperation between nodes.

System Implementation and Architecture:

Distributed Storage and Grid Computing: The SOS network provides distributed storage, processing grids, and virtual networks.

Hardware and Software Components: The hardware components and software architecture of the physical nodes are described in detail, including processors, memory, sensors, communication devices, etc.

API Layer and Open Protocols: The API layer of SOS provides access to communication space protocols and other open source functions, supporting interoperability between nodes.

Performance and Growth:

Dynamic Optimization: The system is able to dynamically optimize resource allocation to ensure efficient resource utilization and transparency of transactions.

Network Growth: With the addition of new nodes, the total amount of network resources and services will grow exponentially, promoting the self-organization and expansion of the system.

By introducing blockchain technology, distributed operating systems, and smart contract management, an efficient, transparent, and automated resource allocation and sharing platform is provided for nodes in the cluster, which is particularly suitable for the field of space data communication and services, and can be extended to other industry applications.

The following is a summary of the short answer questions for the file US10742313.pdf:

What is the main goal of the system?

A: The main goal of the system is to optimize the allocation and use of resources, goods and services between nodes in the cluster. Nodes can be software programs, individuals, machines, organizations, and any other entities that can exchange resources.

What key technologies does the system use?

A: The system uses blockchain technology, distributed space operating system (SOS), and smart contract management. Blockchain technology is used to store smart contracts and transaction records to enhance transaction transparency; the SOS network is used to manage node resources and services; smart contracts promote automated transactions and resource allocation.

What is the main role of the resource manager (ROME)?

A: The resource manager (ROME) is used to optimally allocate resources, goods and services between nodes. It maximizes the use of resources by optimizing standards and rules, and dynamically updates the resource allocation table to ensure efficient resource allocation and transparent transactions.

What role do internal certificates (CCs) play in the system?

A: Internal certificates (CCs) serve as proof of contribution to shared resources in the system. Nodes obtain CCs by sharing resources, and these certificates can be used to exchange other resources such as processing power, energy, communication, and storage, thereby incentivizing resource sharing between nodes.

How does the system support efficient communication?

A: The system supports a variety of communication protocols and technologies, including CCSDS, GNU Radio, quantum communication, etc., to ensure efficient data transmission. These technologies enable nodes in the cluster to communicate and collaborate effectively.

What is the economic incentive mechanism of the system?

A: The economic incentive mechanism of the system is to incentivize nodes to share resources by issuing internal certificates (CCs). Nodes obtain CCs by contributing resources, and these certificates can be circulated and exchanged in the system, thereby promoting the self-organization and sustainable development of the network.

How is the system applied to the space industry?

A: The system is particularly suitable for the field of space data communication and services. It solves the problems of high cost and low efficiency of existing systems, and enhances the interoperability and service capabilities between distributed base stations and satellite constellation systems through efficient resource sharing and collaboration.

How is the scalability of the system?

A: The system has good scalability. It is not only applicable to the space industry, but can also be extended to other industries to achieve efficient sharing of resources and services. With the addition of new nodes, the total amount of network resources and services will grow exponentially, promoting the self-organization and expansion of the system.