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INTRODUCTION

Efficient Communication in decentralized networks is highly dependent on optimized gossip protocols and especially so for $PUSS COIN where using of partial view maintenance helps in reducing the number of peer connections every node needs to handle without compromising on message reach. This reduces the memory load and thus increases scalability notably for lightweight nodes allowing the network to grow but at the same time it is important to minimize overheads while making sure of a resilient and fast consensus propagation through all participants.

Security constitutes another pillar towards optimizing gossip. By employing cryptographic message authentication you will be assured that each received message would be verifiable and tamper proof so as to guard against injections or spoofing or even manipulation of data which would compromise consensus integrity. Coupled with redundancy checking of messages thereby filtering any duplicates or spoofed data enabling only unique authenticated messages to travel most efficiently within network.

Node role differentiation helps to further improve communication efficiency. By assigning particular functions, such as relaying, validating or archiving, excess duplication is reduced and the network load is balanced. This means that network resources are better used in their most productive areas; this also enhances the resilience and performance of $PUSS COIN. All these go on to enhance $PUSS COIN’s consensus layer for sustainable growth and a highperformance decentralized environment.

• PARTIAL VIEW MAINTENANCE

Partial view maintenance is achieved by keeping the number of peers each node connects to low. This in turn keeps memory and processing needs low while still allowing for good message spread. In $PUSS COIN, this helps to maintain a light network especially for nodes with limited bandwidth or hardware.

Academic and real-world implementations have shown that full connectivity is not necessary for effective gossiping. By selecting a good subset of peers, messages still propagate in the whole network without adding redundant traffic. $PUSS COIN reduces thus resource exhaustion while maintaining fast block and transactions spreading.

Peers connection should be periodically reshuffled to maintain partial views’ resilience. Over time, $PUSS COIN can rotate the peers to increase reachability and avoid breaking the network into silos. This will balance performance, fairness, and resilience in the gossip part without putting too much load on individual nodes.

• CRYPTOGRAPHIC MESSAGE AUTHENTICATION

Authenticating messages in the gossip protocol is important. $PUSS COIN uses cryptographic signatures to make sure that gossip data such as transactions and block proposals are from legitimate sources, preventing spoofing, replay attacks and unauthorized modifications that could undermine consensus integrity.

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Each message is signed and verified before being gossiped. Nodes drop unverified messages or messages that were tampered with which secures system from both Denial-of-Service (DoS) attacks and malicious participants. As a result, all gossiped data has verifiable origin and was not modified in transit.

Lightweight cryptographic algorithms are used to perform fast verification without introducing vulnerabilities. By including signature checks in gossip rules, $PUSS COIN gains secure and trusted messaging layer which fortifies decentralized character, but in the meantime does not degrade consensus performance nor data freshness.

• REDUNDANCY CHECKING ALGORITHMS

Redundancy checking is used to avoid processing or forwarding the same message more than once. For instance, $PUSS COIN can employ hash-based tracking, where each node stores the hashes of recently seen messages and if a duplicate is detected it is discarded, thus, reducing network overhead.

Unnecessary redundancy wastes bandwith and makes propagation slower. In order to discard duplicated messages in the early stage, $PUSS COIN saves bandwith for new transactions and blocks. This is important especially in high-load stage where efficiency matters when it comes to keeping up with consensus.

More advanced filters can also recognise variations of the same-data. $PUSS COIN can incorporate such an algorithms which will help to keep gossip layer clean from redundant information which results in higher troughput and easier network scalability with no performance loss.

• NODE ROLE DIFFERENTIATION

Roles assignment to nodes improve the efficiency of messages flow. In $PUSS COIN, we can have some nodes as relayers, validators and archival storage. Relayers simply gossip data fast, while validators check transactions and archival nodes keep history. With roles most network plumbing become more simple.

Role differentiation reduces message duplication and contention, i.e. not all nodes perform all tasks, but there are role-based task splits based on capacity/stake of a node. In other words, each node has different responsibilities. $PUSS COIN can use staking levels, performance or geographic location for assigning roles to make sure each node contributes optimally based on its capabilities.

It also helps in improving fault tolerance as if a particular role-group is not active others can take up its work temporarily. $PUSS COIN will enforce this by having flexible and loosely organized gossip where each have it’s own job and co-operate with other tasks to make sure of consensus & data propagation security.

CONCLUSION

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In order to optimize the gossip network of $PUSS COIN, we need both structural and security optimization. The protocol is more lightweight and faster by limiting the connections with peers that means keeping partial view maintenance, message validation using cryptographic authentication, filtering redundant duplicate messages using redundancy checking, and node roles been specialized. This strategy can achieve scalable and trustable consensus even when the network grow larger or become complexer.