opBNB vs IoTeX Scalability
Real-time TPS
opBNB TPS is 23X higher than IoTeX TPS
Max TPS (100 blocks)
opBNB max TPS is 33.93% lower than IoTeX max TPS
Max Theoretical TPS
opBNB max theoretical TPS is 2.38X higher than IoTeX max theoretical TPS
Transaction Volume
opBNB transaction volume is 23X higher than IoTeX transaction volume
Block Time
opBNB block time is 80% shorter than IoTeX block time
Finality
opBNB finality is 100% longer than IoTeX finality
Type
opBNB is a layer 2 blockchain, while IoTeX is a layer 1 blockchain
Launch Date
opBNB was launched 4 years after IoTeX
opBNB vs IoTeX Decentralization New
Nakamoto Coefficient
opBNB Nakamoto Coefficient is 88.88% lower than IoTeX Nakamoto Coefficient
Validators
opBNB has 98.61% fewer validators than IoTeX
Stake
opBNB has no data, while IoTeX stake is $123.8M
Consensus Mechanism
opBNB is Rollup (Optimistic), while IoTeX is PoS
Governance
opBNB off-chain governance is worse than IoTeX on-chain governance
opBNB vs IoTeX Real-Time TPS Chart
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Other Comparisons
opBNB Comparisons
About Blockchains
About opBNB
opBNB is an optimistic rollup network designed to enhance the scalability of the Binance Smart Chain (BSC). It aims to take the workload away from the mainnet and improve network performance. The opBNB network employs a unique approach to ensure transaction integrity and security. It leverages the main network (BSC) for final transaction validation on its execution layer, facilitated by a verifier mechanism, striving to achieve high throughput while maintaining security.
About IoTeX
IoTeX is a blockchain platform designed specifically for the Internet of Things (IoT) industry. It aims to address the scalability, privacy, and security challenges associated with connecting billions of devices to the internet. IoTeX utilizes a unique architecture that combines blockchain, decentralized identity, and secure hardware to create a trusted and privacy-centric infrastructure for IoT applications. It offers lightweight and efficient consensus mechanisms, support for trusted computing environments, and privacy-preserving techniques such as zero-knowledge proofs.