High-Performance Blockchain tackles the concept of scalability from a completely different angle. Rather than just looking at the software side of things, the project also tackles the hardware aspect. To realize the optimal performance of blockchain applications, things will need to change in the near future. As such, this team is building an architecture which uses thousands of CPU and FPGA resources to create a more versatile and scalable ecosystem. There are a few aspects of the High-Performance Blockchain project to take into account. First of all, there is the chip-level acceleration engine which provides accelerated hardware chips to power this entire ecosystem. Secondly, the software side of the High-Performance Blockchain is integrated with the new dedicated hardware accelerated engine and focuses on depth and scaling customization. Third, the project claims it can produce a throughput in the millions of transactions without any major problems. While all of this sounds amazing, it is difficult to come by any real information regarding the technical aspects of either the hardware or the software side of High-Performance Blockchain. While the team mainly focuses on blockchain integration for real-world business cases, it remains to be seen how their chips will operate and how their algorithms are created. It seems the High-Performance Blockchain project is closely connected to the NEO infrastructure, which could introduce some interesting developments down the line. Building the High-Performance Blockchain infrastructure will take a lot of time and money. As such, the roadmap is filled with milestones which the team aims to achieve in the coming years. A testnet version of this project will be launched at some point in 2018, which will undergo further improvements for several months. The actual manner will launch in Q2 of 2018 if things go according to plan. However, the official version will not go live until mid-2019 at the earliest.
ProximaX is an advanced extension of the Blockchain and Distributed Ledger Technology (DLT) with utility-rich services and protocols. Businesses, enterprises, and innovators can avoid costly and failure prone centralized architecture by utilizing an all-in-one sustainable platform which provides augmented secured services, content delivery, storage, and media streaming. The ProximaX protocol aims to offer DApp developers cost-efficient fault tolerant, multilayer, P2P cloud services including, but not limited to, blockchain-powered P2P storage and bandwidth. A fault-tolerant system is designed to ensure a system remains fully functional even when part of it is ‘down’ or unavailable. ProximaX will build a P2P cloud storage architecture with fault tolerance and a distributed database by removing the central entity and connecting all the servers (or nodes) in a mesh configuration. Failure of any single component of the mesh will have minimal effect upon the overall performance of the system. ProximaX protocol will ensure confidentiality and integrity of the data passing through a myriad of nodes. The use of distributed databases (DHT) ensures consistency and integrity throughout the network. ProximaX distributed file management system (DFMS) interfaces with NEM blockchain and works in four scenarios: 1. ProximaX Public DFMS with NEM Public chain 2. ProximaX Private DFMS with NEM Public Chain 3. ProximaX Public DFMS with NEM Private Chain 4. ProximaX Private DFMS with NEM Private Chain ProximaX will provide DApp developers with an easy-to-use SDK that abstracts the ProximaX protocol layer into a dynamic second layer on top of the NEM blockchain layer that can carry different unique DApp protocols. This will ensure that the DApp developers can build great P2P applications with the best possible security protocols without relying on points of central authority. It will empower developers to build apps and monetise in the ways they want without any unnecessary compliance pressure. This solution makes use of the NEM blockchain for value and hash transaction and the NEM cryptography framework to gain access to the ProximaX DFMS and work in a tightly integrated environment based on the above four scenarios.