The Architecture Of TRANSFORMERS CHAIN Network
We all know that a public blockchain's performance (security, stability, scalability, and development ease) and the use cases for which it is eventually most appropriate are greatly influenced by the network architecture design. The network architecture is the road network inside the blockchain's city, if protocol algorithms are the "sports cars" that travel through the "traffic system" of a public blockchain. Muddy, impassable dirt roads are too slow for even a Ferrari to travel at high speeds. Over a longer period of time, network architecture has an impact on a public blockchain's overall performance. Furthermore, network issues might be harder to identify than protocol issues and more challenging to fix once they are.
Most community members frequently ignore this important factor, and there aren't many technical papers that discuss network structure. This is truly regrettable. The ability to create network architecture is akin to smart contracts in that it puts important technical team members' development management and big-picture thinking to the test when handling intricate, large-scale systems issues. A ability like this is as uncommon as unicorn horns and phoenix feathers.
Upon closely examining the technical instructions, I saw that TFSC has thoughtfully and meticulously designed the network architecture. I was eager to write this post and tell everyone what I had discovered.
To put it simply, TFSC has adopted a distributed, fully connected, decentralized P2P network architecture. By using a P2P-based network connection, TFSC achieves a high degree of decentralization by enabling all blockchain network nodes to function as both clients and servers.
Establishing a tolerance interval for malicious nodes and ensuring the security and randomness of node and outgoing block verifications are the main goals of this. Rewards for participating in the process of confirming a block's validity are given to any node.
Complete Link and Maximum Amount
TFSC has a high processing capacity, great dependability, and minimal latency due to its fully integrated design.
The optimum speed and security are maintained in TFSC networks when the maximum number of nodes is between 500 and 1000. This finding is supported by several laboratory experiments and advancements.
The TFSC team has created a single network node with a takeover capability based on this unique mechanism. Network nodes that are not able to participate in transactions will become momentarily inaccessible when node performance reaches a limit.
The long-term stability of the TFSC network layer's development and availability can be attributed to the fluidity of the nodes' participation process.
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