Most online transactions, in fiat and crypto alike, go through their own process in the background between sending and approval. In traditional banking systems, a transaction is considered final once it’s fully processed by all involved financial institutions —and yet, it still can be reversed for any reason. This doesn’t happen with most cryptocurrencies, where transactions aim to be immutable. Transaction finality in crypto refers to the point at which a transaction is considered permanent and irreversible on the network. Once a transaction reaches finality, it cannot be undone or changed, ensuring that the funds are with the intended recipient or the data involved is undoubtedly on chain. This assures users that they can safely spend the received funds. Of course, not all cryptos are built the same, and they all have different mechanisms to reach their own level of transaction finality. Deterministic vs. Probabilistic You’ll likely find several types of transaction finality in crypto, but they could be reduced to deterministic or probabilistic. Deterministic finality ensures that once a transaction is confirmed or stable, it is final and irreversible. Platforms like Obyte or some Proof-of-Stake (PoS) networks offer this type of finality, where their internal mechanisms make it impossible for a confirmed transaction to be undone, providing a higher level of security and certainty for users. In contrast, probabilistic finality occurs when a transaction becomes more secure over time but could theoretically be reversed, especially shortly after it was broadcast to the network. For instance, in Bitcoin, a transaction with just one confirmation is less secure than one with six confirmations. This is because, early on, there’s a small chance that a miner could create an alternative chain with enough mining power, effectively reversing the transaction. A practical example of this is a 51% attack, where an entity controlling the majority of the network’s hashing power could rewrite recent blocks, potentially reversing or invalidating previous transactions. This scenario is unlikely, though, because the costs often exceed the potential reward. However, in theory, it’s still possible to reverse transactions on probabilistic blockchains, especially if they’re small. Finality Matters In the digital world, almost everything can be copied and pasted, and that was a problem in creating electronic money for many years. Cryptocurrencies brought their own cryptographic and decentralized system to prevent exactly that. Without finality, someone could spend their crypto twice (double-spending), undermining the entire system’s integrity. By guaranteeing that once a transaction is confirmed, it’s recorded permanently on the chain, finality eliminates this risk, creating a reliable framework for the exchange of digital assets. This is why transaction finality matters, in the first place. In the field of smart contracts, finality also plays a critical role. Smart contracts are automated agreements that execute based on predefined conditions, and their outcomes rely on the immutability of their network —without middlemen. Finality ensures that once a smart contract executes, its results are permanent, meaning the terms of the agreement are fulfilled without the possibility of reversal. This is essential for maintaining trust in smart contract-based applications, where the stakes are high, and participants need certainty that agreements will be honored. For decentralized applications (Dapps), transaction finality is key to maintaining the security and reliability of their operations. When users interact with Dapps, they need to know that their actions and transactions are irreversible once confirmed. Finality guarantees this, ensuring that the outcomes of Dapp interactions are trustworthy. Stable Transactions in Obyte Obyte is a decentralized network that uses a Directed Acyclic Graph (DAG) structure instead of a blockchain, allowing for more decentralization. Unlike blockchains, where a small group of block producers can dominate and even censor transactions, Obyte eliminates these central power structures. Its DAG model ensures that no single entity can control the network, creating a system where there aren’t middlemen between transaction sending and transaction approval. In terms of transaction finality, Obyte reaches deterministic finality once a transaction is deemed stable, meaning it cannot be reversed —ever. This is achieved by gradually building a Main Chain (MC) through transactions posted by Order Providers (OPs—nodes with guiding transactions). As new transactions are added to the network, each user tracks their own current MC based on the latest transactions they have received. While the recent part of the MC might change as new transactions are received, its old part, beyond some point, is stable, meaning that it will never change no matter what new transactions are received. This point is called the stability point. A transaction becomes final and irreversible once the stability point moves ahead of the transaction. This happens when enough “weight” from OPs is placed on the older part of the MC and any competing branches lose their chances of redirecting that part of the MC. Therefore, after reaching the stability point, a transaction is considered fully confirmed and cannot be reversed, ensuring deterministic finality, as opposed to the probabilistic one on some well-known blockchains, including Bitcoin. As a result, users can enjoy the benefits of a whole crypto ecosystem including smart contracts, Decentralized Finance (DeFi) apps, Autonomous Agents (AA), customized tokens, and more features, all with integrated deterministic finality. Ready to explore it? Featured Vector Image by vectorjuice / Freepik Most online transactions, in fiat and crypto alike, go through their own process in the background between sending and approval. In traditional banking systems, a transaction is considered final once it’s fully processed by all involved financial institutions —and yet, it still can be reversed for any reason. This doesn’t happen with most cryptocurrencies, where transactions aim to be immutable. Transaction finality in crypto refers to the point at which a transaction is considered permanent and irreversible on the network. Once a transaction reaches finality, it cannot be undone or changed, ensuring that the funds are with the intended recipient or the data involved is undoubtedly on chain. This assures users that they can safely spend the received funds. Transaction finality in crypto refers to the point at which a transaction is considered permanent and irreversible on the network. Of course, not all cryptos are built the same, and they all have different mechanisms to reach their own level of transaction finality. Deterministic vs. Probabilistic You’ll likely find several types of transaction finality in crypto, but they could be reduced to deterministic or probabilistic. Deterministic finality ensures that once a transaction is confirmed or stable, it is final and irreversible. Platforms like Obyte or some Proof-of-Stake (PoS) networks offer this type of finality, where their internal mechanisms make it impossible for a confirmed transaction to be undone, providing a higher level of security and certainty for users. types of transaction finality types of transaction finality Obyte Obyte In contrast, probabilistic finality occurs when a transaction becomes more secure over time but could theoretically be reversed , especially shortly after it was broadcast to the network. For instance, in Bitcoin, a transaction with just one confirmation is less secure than one with six confirmations. This is because, early on, there’s a small chance that a miner could create an alternative chain with enough mining power, effectively reversing the transaction. In contrast, probabilistic finality occurs when a transaction becomes more secure over time but could theoretically be reversed A practical example of this is a 51% attack, where an entity controlling the majority of the network’s hashing power could rewrite recent blocks, potentially reversing or invalidating previous transactions. This scenario is unlikely, though, because the costs often exceed the potential reward. However, in theory, it’s still possible to reverse transactions on probabilistic blockchains, especially if they’re small. the costs the costs Finality Matters In the digital world, almost everything can be copied and pasted, and that was a problem in creating electronic money for many years. Cryptocurrencies brought their own cryptographic and decentralized system to prevent exactly that. Without finality, someone could spend their crypto twice (double-spending), undermining the entire system’s integrity. By guaranteeing that once a transaction is confirmed, it’s recorded permanently on the chain, finality eliminates this risk, creating a reliable framework for the exchange of digital assets. This is why transaction finality matters, in the first place. By guaranteeing that once a transaction is confirmed, it’s recorded permanently on the chain, finality eliminates this risk, creating a reliable framework for the exchange of digital assets. In the field of smart contracts , finality also plays a critical role. Smart contracts are automated agreements that execute based on predefined conditions, and their outcomes rely on the immutability of their network —without middlemen. Finality ensures that once a smart contract executes, its results are permanent, meaning the terms of the agreement are fulfilled without the possibility of reversal. This is essential for maintaining trust in smart contract-based applications , where the stakes are high, and participants need certainty that agreements will be honored. smart contracts smart contracts smart contract-based applications smart contract-based applications For decentralized applications (Dapps), transaction finality is key to maintaining the security and reliability of their operations. When users interact with Dapps, they need to know that their actions and transactions are irreversible once confirmed. Finality guarantees this, ensuring that the outcomes of Dapp interactions are trustworthy. Stable Transactions in Obyte Obyte is a decentralized network that uses a Directed Acyclic Graph (DAG) structure instead of a blockchain, allowing for more decentralization. Unlike blockchains, where a small group of block producers can dominate and even censor transactions, Obyte eliminates these central power structures. Its DAG model ensures that no single entity can control the network, creating a system where there aren’t middlemen between transaction sending and transaction approval. Obyte Obyte In terms of transaction finality, Obyte reaches deterministic finality once a transaction is deemed stable, meaning it cannot be reversed —ever. This is achieved by gradually building a Main Chain (MC) through transactions posted by Order Providers (OPs—nodes with guiding transactions). As new transactions are added to the network, each user tracks their own current MC based on the latest transactions they have received. In terms of transaction finality , Obyte reaches deterministic finality once a transaction is deemed stable, meaning it cannot be reversed —ever. transaction finality transaction finality While the recent part of the MC might change as new transactions are received, its old part, beyond some point, is stable, meaning that it will never change no matter what new transactions are received. This point is called the stability point. A transaction becomes final and irreversible once the stability point moves ahead of the transaction. This happens when enough “weight” from OPs is placed on the older part of the MC and any competing branches lose their chances of redirecting that part of the MC. Therefore, after reaching the stability point, a transaction is considered fully confirmed and cannot be reversed, ensuring deterministic finality, as opposed to the probabilistic one on some well-known blockchains, including Bitcoin. As a result, users can enjoy the benefits of a whole crypto ecosystem including smart contracts, Decentralized Finance (DeFi) apps, Autonomous Agents (AA), customized tokens, and more features, all with integrated deterministic finality. Ready to explore it? Ready to explore it? Ready to explore it? Featured Vector Image by vectorjuice / Freepik Featured Vector Image by vectorjuice / Freepik Freepik Freepik
