As the developers are constantly using different network protocols of blockchain such as Hyperledger, multichain, Ethereum, Corda, and others. Community will appreciate if the developers & blockchain enthusiasts can pour in some key differences between various types of blockchains as mentioned above.

Thanks !

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    One of the main differences lies with the consensus algorithm the blockchain is using they are all solving the consensus problem but in different ways – Mat0 Jan 24 '17 at 22:02

This is a good question, though not one easily addressed with a simple answer.

As @Mat0 commented above, one difference is the approaches that the various platforms are using to achieve consensus. Some use proof of work (PoW), others use variants of byzantine fault tolerant strategies (PBFT, SBFT, etc). Some use PAXOS derivative strategies. Hyperledger Sawtooth Lake has developed an innovative strategy named Proof of Elapsed Time (PoET). Some, such as Hyperledger Fabric allow pluggable consensus implementations to allow for experimentation and additional diversity.

Other platforms differ in the means by which they implement confidentiality of data and transaction execution.

Some such as Hyperledger Fabric, Hyperledger Sawtooth Lake, Corda, Ethereum and many others permit more comprehensive smart contract capabilities, while other platforms are very restrictive of the types of contract operations - such as the various platforms that only support the limited set of operations in the unspent transaction output (UTXO) protocol.

Some are more targeted to a specific use case, while others are more intended to be more general purpose. All are seeking to find ways to improve the various aspects of performance and scale.

Finally, some are intended to support permission-less public blockchain networks, while others are more oriented towards support for private, permissioned networks (consortia networks) where participation and membership is tightly controlled.

Hyperledger is focused on developing blockchain technologies suitable for use in the enterprise. The organization has been established to bring together related and even competing technologies in the expectation that the proximity and common governance will lead to interoperability and gradual consolidation.

Choosing a platform will demand significant research and a clear understanding of your use case and requirements and a good deal of experimentation. At the end of the day, there will be no easy answers.

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    Thanks for the detailed response. Appreciate if you can share your opinion/experience on scalability, Flexibility, Easy of implementation, cloud compatibility, cost of implementing pilots and the likes – Saurabh Feb 3 '17 at 11:09
  • A note to Hyperledger Fabric they are also using the new SIEVE approach to solve consensus – Mat0 Feb 18 '17 at 21:01

To add to Chris's comment, with which I mostly agree, I'd expand on his comment about the "UTXO" model.

In our view (I'm the CTO of R3), one key design decision which distinguishes blockchain platforms is whether they use what I call the "replicated virtual machine" metaphor or whether they are based on the idea of transaction outputs (the "UTXO" model).

Mike Hearn wrote about this in the context of Corda's design: https://www.corda.net/2016/12/09/rationale-tradeoffs-adopting-utxo-style-model/

The key point I wanted to make, however, was that the UTXO model - at least as implemented in Corda - enables full-function code to be run... the set of supported operations is not in any way limited.

The differences become manifest mostly in the context of the non-functional characteristics of the platforms.

As Chris says, platform selection should be driven by use-case: I believe that the UTXO model we've used in Corda makes it particularly well-suited for a wide variety of financial services scenarios (that's why we made the choice to adopt that architecture!). But there is no one size that fits all.

  • +1 for "But there is no one size that fits all.". That's exactly the observation that I am making right now. I am experimenting with different views (corda, fabric, quorum, ethereum) on our problems at hand and as always it's all about tradeoffs. – ivicaa Apr 13 at 20:12

Bitcoin technology stack — especially when enhanced with sidechains and payment channels (such as from Blockstream and Lightning Network).

Ethereum platform — currently the second most proven platform, behind the Bitcoin stack.

Hyperledger Fabric — a result of significant strategic investment from IBM and many others that is reaching into an installed base of large corporate customers.

R3 Corda — vertical-oriented blockchain technology (the company prefers "blockchain inspired" because it emphasizes significant differences between this private/permissioned ledger offering compared to the public/permissionless ledgers such as Bitcoin blockchain).

Digital Asset — another vertically focused blockchain technology that has high visibility in the financial services sector

While it is very difficult to predict the eventual winner given that it may not even be on the market, but it is possible to state what that winner will look like. Here are the 9 characteristics of a winning blockchain platform

Open source — this is necessary to cultivate a rich and diverse ecosystem and accelerate adoption through network effect.

Modular architecture with layers of programmability and customizability — as above, this cultivates an ecosystem and enables market adoption.

Global scale — scalability, performance and efficiency are essential if blockchain is to become the foundation for the "Internet of Money."

Multiple implementations of the core protocol — multiple, independently developed implementations ensure that the protocol is understood, well-defined and adds resistance to possible attacks (as occurred with the Ethereum platform in September 2016). This requires there to be an accurate and precise specification of the core protocol, as opposed to relying on one codebase that is not documented.

Hardened through public blockchain deployment — this is the only way to ensure that the system is secure and "bulletproof," by exposing it to the worst threats on the open internet, as has occurred with both the Bitcoin stack and the Ethereum platform.

Configurable for private blockchain deployment and support for confidentiality of transactions — because most businesses do not want their transactions to be visible by their competitors or by the rest of the world.

Functioning governance — there needs to be a cohesive decision-making structure that can respond in an agile and coherent manner to threats to the system.

Advanced smart contract capability — because the current generation of smart-contract technology relies on traditional languages (similar to Java or C#), which are inadequate for the rigorous requirements of large-value contracts (and are best supported by metadata-driven or mathematically verifiable programming systems).

Adequate tooling for developing, debugging, deploying, monitoring and managing smart-contract-based systems (the importance of which was underscored by the recent denial-of-service attacks on the Ethereum network).

Since 2008, when the term bitcoin was coined by Satoshi Nakamoto as a novel electronic and completely peer-to-peer cash system free of trusted third party, the interest in the bitcoin and blockchain technology has increased. Recognizing it as a revolutionizing technology across the industries, especially in banking and finance, in terms of transactions and their privacy and security, researchers are not leaving any stone unturned to come up with exotic protocols with each passing day and each is the newer, advancer and better protocol than the previous. In continuation to the blockchain series on TheBlockchainAcademy.com, I have included 6 major blockchain protocols, so as to embrace the technology and increase awareness among investors and end users of blockchain.

Hyperledger

Hyperledger is the open source blockchain platform, began in 2015 by the Linux Foundation, in an effort to support the blockchain-based distributed ledgers. The protocol focuses ledgers developed to support international business transactions, catering leading financial, technological and supply chain businesses, with the objective of improving a lot of performance and reliability aspects. The project emphasizes on making collaborative efforts for making open standards and protocols, by offering a modular framework that backs various components for diverse uses, including a range of blockchains having their own storage and consensus models, and the services for access control, contracts and identity.

Bitcoin

The starting of the bitcoin dates back to November 2008, when a thesis had been posted by Nakamoto on a US mailing list where the cryptographers share or exchange information. The thesis titled “Bitcoin: A peer-to-peer electronic cash system”, presented the following characteristics of this protocol:

  1. Enables transaction directly with no need of any trusted third party
  2. Enables the non-reversible transactions
  3. Decreases credit cost in minor casual transactions
  4. Decreases transaction fees
  5. Prevents double-spending

Bitcoins are virtual currency, also called cryptocurrency. These are distributed while exploring the value in the data managed by software. The start of 2016 witnessed the issuance of around 15.26 million BTC, equivalent to around 7 billion US Dollars. Major technologies that make Bitcoin include hash, digital signature, public-key cryptography, P2P and Proof of Work. This blend has developed a mechanism that prevents duplication of payments and data falsification, additioinally a mechanism that prevents malicious users, which are critical for the operating system like the one for the electronic money, having no central authority.

Ethereum

Ethereum is a public, open-source and block chain oriented distributed computing protocol that features smart contracts (scripting) functionality. The protocol has provided a decentralized virtual machine called the Ethereum Virtual Machine (EVM), which carried out Turning-complete scripts by using a global network of public nodes and the token called ether, also referred to as gas. Gas is used for preventing the spam on networks and allocating the resources in proportion to the incentive provided by the request. Bloomberg explains Ethereum as shared software that is used by all; however, is tamperproof. Ethereum is also used as a protocol for decentralized applications, smart contracts and decentralized autonomous organizations, with a number of functioning applications developed on it by March 2016, New York Times says.

Ripple Consensus Network

The Ripple Transaction Protocol (RTXP), issued in 2012, has been developed upon an open-source distributed consensus ledger, Internet protocol, and native currency termed as XRP (ripples). Ripple enables instant, safe and almost free global financial transactions of any scale without any chargeback. The protocol is embraced being able to support tokens presenting cryptocurrency, fiat currency, commodity and any other value unit like mobile minutes, frequent flier miles etc. By the end of 2017, Ripple is expected to be the third-biggest cryptocurrency in terms of market capitalization, after the bitcoin and ethereum.

R3’s Corda

Corda by the Company R3 is the distributed ledger protocol that has been developed from the ground up for recording, supervising and synchronizing the financial agreements among regulated financial institutions. It is, by great deal, stimulated by, and captures the advantages of blockchain systems, with no design choices that turn blockchains unsuitable for a lot of banking scenarios. Corda’s design came up as a result of heavy analysis and prototyping with team members. It is now an open sourced protocol since the code matured further.

Symbiont Distributed ledger

This protocol was announced in October 2016 as a software development kit for the Assembly, which is the permitted distributed ledger part of Symbiont’s smart contracts system. Assembly is considered as the first distributed ledger suitable for institutional finance. It is a greatly secure, high performing Byzantine fault-tolerant distributed ledger, which can process a sustained 80,000 transactions every second in a local multi-node network. As stated by Co-founder of Symbiont, decentralized systems should no longer be slow and with Assembly, it has been fulfilled.

You can learn more about Blockchain and implementing your own Blockchain @ IBM Blockchain 101: A quick-start developer guide

This is the subject of a number of recent academic papers, as the field expands rapidly.

These for example are based on Consensus in the Age of Blockchains:

  • Committee Formation - How the members of the committee are chosen, for example via proof-of-work, proof-of- stake, trusted hardware etc
  • Consistency - The likelihood that the system will reach consensus on a proposed value; it can be either strong or weak
  • Incentive Model
  • Safety ( Transaction, Censorship Resistance, DoS Resistance)
  • Adversary models considered
  • Performance (Throughput, Scalability, Latency)
  • Exp. Setup
  • Code availability

See also Blockchain Consensus Protocols in the Wild.

The main thing that differentiate each different blockchain is the consensus algorithm. Some algorithms are meant for public chain (eg: bitcoin blockchain) whereas some algorithms are meant for permissioned network (eg: Ripple, Hashgraph).

I just wanted to add that DAG is a game changer for blockchain (as far as I know). Take a look at NANO (raiblocks) which is even more interesting than pure DAG, it is DAG + Blockchain. Instead of one blockchain like BTC and ETH. There is a blockchain for each account and connected by DAG which is very creative and scalable!

Block lattice:

Nano has one blockchain for each account which is controlled by the account's private key, and each blockchain is replicated to all peers in the network. We call this arrangement a block lattice.

Balances are transferred between blockchains through send and receive blocks. Send blocks reduce the balance of an account and marks the delta as receivable by an account number. At a later time, the receiving account creates a receive block, which increases the balance of their account by the delta.

Distributed agreements like Proof-of-Work or Proof-of-Stake are unnecessary, since the account owner has authoritative control over transactions.

https://github.com/nanocurrency/raiblocks/wiki/Block-lattice

I will be bold and say that Confidence Coin is perhaps the fastest blockchain technology in terms of broadcasting events.

  • Better encoding. Every time a new address is used in a transaction it is saved to the blockchain database, so next time it is spotted it replaced with a numeric value. Bitcoin can encode about 2K transactions in one megabyte of a block while Coco can have up to 100K transactions in same space.
  • The principal problem in blockchain P2P networks is their size, with each new node added to the system it takes more time to broadcast new blocks to everyone. There are 11,000 nodes in Bitcoin as of 2018. The source of Coco speed is in its Royal Network. It's called royal as in order to join the network you must mine a block. It allows only the best Pools to be part of the Royal Network. It's funny as in Bitcoin over 95% of the blocks mined by less than 20 Pools, but instead of direct communication between them, their messages traverse the entire 11,000 nodes.

Disclaimer: I am the developer of Coco.

There will be several difference between those blockchain projects:

  1. Application: The specific application or domain they are focusing on. Some blockchain projects are public basic blockchains, like Ethereum, you can develop your own applications on it with the support of smart contract. While others may focus on certain domain, such as entertainment, storage, finance etc.

  2. Consensus Protocol: as mentioned by others as well, different blockchain projects may use different consensus protocols, such as: PoW, PoS, DPoS, BFT, DBFT etc. So many consensus protocols were proposed. Although, honestly speaking, for now, only PoW works well for a long time.

  3. TPS: it's actually related with the 2nd point, consensus protocol can certainly affect the performance/TPS, however, block design, and technologies like sharding, lightning network can significantly affect the TPS as well. Specific technologies used to improve scalability can also differentiate those projects.

  4. Smart Contract: programming languages used to develop smart contract, whether the contract is secure, whether the development environment is user friendly, those are also the factors that should be considered to differentiate the blockchain projects.

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