In mythology, Ouroboros (also, uroboros) is usually depicted as a snake (or sometimes a dragon) eating its own tail in a closed circle. The word Ouroboros itself derives from Ancient Greek, its literal meaning being 'tail eating' or 'tail devourer.'
As a symbol, Ouroboros represents the infinity of time flowing back unto itself, in a never-ending cycle, as if caught in an eternal loop. Ouroboros first appeared in Egypt, in 13th century BC. Later, alchemists adopted Ouroboros into their mystical symbolism.
Throughout the ages, Ouroboros has been interpreted and used in a variety of ways by a plethora of cultures. One of the most common interpretations is that the symbol represents the interconnectedness and infinity of the Universe.
In 2017, Charles Hoskinson adopted Ouroboros to name the proof-of-stake consensus protocol that underlies Cardano. In this context, Ouroboros represents the possibility of infinite and ethical growth and scalability of the blockchain. Ouroboros' central message is the delivery of greater opportunities for the world, and its preservation through much-reduced energy consumption.
What is Ouroboros
Ouroboros is the consensus protocol for Cardano, the first provably secure proof-of-stake protocol, and the first blockchain protocol based on peer-reviewed research.
Combining unique technology and mathematically verified mechanisms (including behavioral psychology and economic philosophy principles), Ouroboros guarantees and supports the security and sustainability of any blockchain implementing it. The result is a protocol with proven security guarantees, and able to facilitate the propagation of global, permissionless networks with minimal energy requirements. Cardano is the first such network.
Ouroboros selects participants - stake pools, in this case - to create new blocks based on the stake they control in the network, and facilitates the creation of distributed, permissionless networks capable of sustainably supporting new markets.
Ouroboros comes in different versions:
The first implementation of Ouroboros achieved three major milestones:
- The foundation for an energy-efficient protocol to rival proof of work
- The introduction of the mathematical framework to analyze proof of stake
- The implementation of a novel incentive mechanism to reward participants in a proof-of-stake setting
But what really set Ouroboros apart from other blockchain protocols (specifically, proof-of-stake protocols), was its ability to generate unbiased randomness in the protocol’s leader selection algorithm, and the subsequent security assurances that provided. Randomness prevents the formation of patterns, which is critical for maintaining the protocol’s security. Ouroboros was the first blockchain protocol to be developed with this type of rigorous security analysis.
Ouroboros Byzantine Fault Tolerance (BFT) was the protocol's second implementation, used during the Byron update (transition from the old Cardano codebase to the new). The second instance of the protocol prepared Cardano for the decentralization that came with the Shelley release.
Ouroboros BFT enabled synchronous communication between a network of federated servers – the blockchain –, providing ledger consensus in a simpler and more deterministic manner.
Ouroboros Praos introduced substantial security and scalability improvements to the Ouroboros Classic implementation. Praos processes transaction blocks by dividing chains into slots, which are aggregated into epochs. But unlike Ouroboros Classic, Praos is analyzed in a semi-synchronous setting and is secure against adaptive attackers, using private-leader selection and forward-secure, key-evolving signatures to ensure that a strong adversary cannot predict the next slot leader and launch a focused attack (such as a DDoS attack).
Once implemented, the fourth iteration of Ouroboros -Genesis- will further improve upon Ouroboros Praos by adding a novel chain selection rule that enables parties to bootstrap from a genesis block without the need for trusted checkpoints or assumptions about past availability. The Genesis paper also provides proof of the protocol’s Universal Composability, which demonstrates that the protocol can be composed with other protocols in arbitrary configurations in a real-world setting, without losing its security properties.
Ouroboros Crypsinous equips Genesis with privacy-preserving properties. It is the first formally analyzed privacy-preserving proof-of-stake blockchain protocol, which achieves security against adaptive attacks while maintaining strong privacy guarantees by introducing a new coin evolution technique relying on SNARKs and key-private forward-secure encryption. Crypsinous isn’t currently planned to be implemented on Cardano, but it can be used by other chains for increased privacy-preserving settings.
Chronos achieves two goals: first, it shows how blockchain protocols can synchronize clocks securely via a novel time synchronization mechanism and thereby become independent of external time services. Second, it provides a cryptographically secure source of time to other protocols. In short, Chronos makes the ledger more resistant to attacks that target time information.
From an application point of view, Chronos can dramatically boost the resilience of critical telecommunications, transport, and other IT infrastructures that require the synchronization of local time to a unified network clock that has no single point of failure.