Algorand vs opBNB Scalability
Real-time TPS
Algorand TPS is 83.91% lower than opBNB TPS
Max TPS (100 blocks)
Algorand max TPS is 10X higher than opBNB max TPS
Max Theoretical TPS
Algorand max theoretical TPS is 1.97X higher than opBNB max theoretical TPS
Transaction Volume
Algorand transaction volume is 83.91% lower than opBNB transaction volume
Block Time
Algorand block time is 5.63X longer than opBNB block time
Finality
Algorand finality is 100% shorter than opBNB finality
Type
Algorand is a layer 1 blockchain, while opBNB is a layer 2 blockchain
Launch Date
Algorand was launched 4 years before opBNB
Algorand vs opBNB Decentralization New
Nakamoto Coefficient
Algorand Nakamoto Coefficient is 12X higher than opBNB Nakamoto Coefficient
Validators
Algorand has 1,903X more validators than opBNB
Stake
Algorand stake is $481.1M, while opBNB has no data
Consensus Mechanism
Algorand is Pure Proof of Stake, while opBNB is Rollup (Optimistic)
Governance
Algorand on-chain governance is better than opBNB off-chain governance
Algorand vs opBNB Real-Time TPS Chart
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Other Comparisons
Algorand Comparisons
opBNB Comparisons
About Blockchains
About Algorand
Algorand emerges as a blockchain platform committed to fostering transparency and enabling the growth of decentralized projects and applications. Operating as a public, decentralized blockchain, it leverages a Pure Proof-of-Stake (PPoS) consensus mechanism to uphold network security, efficiency, and decentralization. Powered by the Algorand Consensus Algorithm, the network employs a combination of cryptographic techniques and random selection to attain consensus, effectively addressing the constraints of traditional consensus mechanisms.
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.