Delegated Proof of Stake (DPOS)¶
Delegated Proof of Stake (DPOS) is a new method of securing a crypto-currency’s network. DPOS attempts to solve the problems of both Bitcoin’s traditional Proof of Work system, and the Proof of Stake system of Peercoin and NXT. DPOS implements a layer of technological democracy to offset the negative effects of centralization.
Table of Contents
- Rationale Behind DPOS
- Role of Delegates
- Voting Algorithm
- Disincentives for Attacks
- How many witnesses are securing the network
- DPOS Infographic
- Sources and Discussions
Delegated proof of stake mitigates the potential negative impacts of centralization through the use of witnesses (formally called delegates). A total of N witnesses sign the blocks and are voted on by those using the network with every transaction that gets made. By using a decentralized voting process, DPOS is by design more democratic than comparable systems. Rather than eliminating the need for trust all together, DPOS has safeguards in place the ensure that those trusted with signing blocks on behalf of the network are doing so correctly and without bias. Additionally, each block signed must have a verification that the block before it was signed by a trusted node. DPOS eliminates the need to wait until a certain number of untrusted nodes have verified a transaction before it can be confirmed.
This reduced need for confirmation produces an increase in speed of transaction times. By intentionally placing trust with the most trustworthy of potential block signers, as decided by the network, no artificial encumbrance need be imposed to slow down the block signing process. DPOS allows for many more transactions to be included in a block than either proof of work or proof of stake systems. DPOS technology allows cryptocurrency technology to transact at a level where it can compete with the centralized clearinghouses like Visa and Mastercard. Such clearinghouses administer the most popular forms of electronic payment systems in the world.
In a delegated proof of stake system centralization still occurs, but it is controlled. Unlike other methods of securing cryptocurrency networks, every client in a DPOS system has the ability to decide who is trusted rather than trust concentrating in the hands of those with the most resources. DPOS allows the network to reap some of the major advantages of centralization, while still maintaining some calculated measure of decentralization. This system is enforced by a fair election process where anyone could potentially become a delegated representative of the majority of users.
- Give shareholders a way to delegate their vote to a key (one that doesn’t control coins ‘so they can mine’)
- Maximize the dividends shareholders earn
- Minimize the amount paid to secure the network
- Maximize the performance of the network
- Minimize the cost of running the network (bandwidth, CPU, etc)
So how is this different than Bitcoin? With Bitcoin, users must pick a mining pool and each pool generally has 10% or more of the hash power. The operator of these pools is like a representative of the clients pointed at the pool. Bitcoin expects the users to switch pools to keep power from becoming too centralized, but collectively five major pools control the network and manual user intervention is expected if one of the pools is compromised. If a pool goes down then the block production rate slows proportionally until it comes back up. Which pool one mines with becomes a matter of politics.
- High probability they are not online.
- Attackers would gain control proportional to their stake, without any peer review.
- Without any mining at all, the generation of a random number in a decentralized manner is impossible and thus an attacker could control the random number generation.
Assuming a fixed validation cost per transaction and a fixed fee per transaction, there is a limit to the amount of decentralization that can take place. Assuming the validation cost exactly equals the fee, a network is completely centralized and can only afford one validator. Assuming the fee is 100x the cost of validation, the network can support 100 validators.
Systems like Nxt and Peercoin will have excessive fees if they intend to allow everyone to be a validator and earn fees at scale. What this means for Nxt and Peercoin is that anyone with less than 1% stake cannot validate profitably unless their fees are higher than our DPOS chain. If these chains assume 100 delegates is too centralized and start promoting they have 1000 validators, then their fees must be 10x those of DPOS. If such a chain grew to be the size of Bitcoin ($10 B) then only those with $1M worth of coin could validate profitably and most would consider that an elite club. If they reduce the minimum stake to be a validator to $1000, then their fees would be 10,000 times higher than DPOS.
Developers of DPOS assume that everyone with less than the amount required to validate won’t participate. Also assumed is a “reasonable” distribution of wealth. It’s clear that unless alternate chains have unusually high fees, there will only be a handful of people with enough stake to validate profitably.
In conclusion, the only way for POS to work efficiently is to delegate. In the case of Nxt, they can pool their stake by some means and ultimately this will end up like DPOS prior to approval voting with a variable number of delegates. Delegates wouldn’t actually receive any income as with mining pools because the validation expenses will consume the vast majority of the transaction fees.
The end result is that decentralization has a cost proportional to the number of validators and that costs do not disappear. At scale, these costs will centralize any system that does not support delegation. This kind of centralization should be designed as part of the system from the beginning so that it can be properly managed and controlled by the users, instead of evolving in some ad hoc manner as an unintended consequence.
- A witness is an authority that is allowed to produce and broadcast blocks.
- Producing a block consists of collecting transactions of the P2P network and signing it with the witness’ signing private key.
- A witness’ spot in the round is assigned randomly at the end of the previous block
- Persuade others to give upvotes to your witness
- When another user gives an upvote to your (and possibly other) delegates
- A user can give an upvote for more than one witness. As a result all upvoted witnesses get a vote
- Convince proxies (that vote on behalf of their followers) to vote for you
- Giving only upvotes, and allowing multiple votes per share, is called Approval Voting, and comes with several advantages over the old delegation voting.
- No downvotes are needed, which not only simplifies usability but also reduces code and complexity.
Once every maintenance interval, all votes are recounted and the corresponding result takes effect.
- By choosing not to produce a block, a witness risks getting fired and they lose guaranteed profits in the future.
- A dishonest delegate would only fail to produce a block if they were sure to win something from it
- If a lottery only payed out 50% to a jackpot (giving the other 50% to charity) then the most this dishonest delegate could do is break even.
- Witnesses can’t sign invalid blocks as the block needs confirmation by the other witnesses as well
This is totally in the hands of the shareholders. If the majority votes for 50 witnesses, then 50 witnesses will be used. If the shareholders only vote for 20, so be it. The minimum possible witness count is 11.