News
Blockchain Monthly Report For May 2024: All You To Need To Know To Stay Ahead
This Blockchain Monthly Report for May 2024 provides a comprehensive analysis of the top layer 1 and layer 2 blockchains and offers you a clear understanding of the entire blockchain market. We perform a general analysis and an in-depth analysis, in which we analyse the selected blockchains’ economic activity, user interest, development, scalability, latency, cost, and market performance. We ensure accurate data and insightful analysis using trusted sources and advanced methodologies.
1. Blockchain General Analysis
In the blockchain general analysis section, we evaluate blockchains using Total Value Locked (TVL) and Dominance indexes to identify the top five blockchains this month. To make the analysis clearer, we examine layer 1 and layer 2 chains separately. Additionally, we use the 30-day Change index to understand how the top five chains in both the layer 1 and layer 2 categories have changed over the last 30 days.
1.1. Top Five Layer 1 Chains by TVL and Dominance
Ethereum, BNB Smart Chain, Solana, Bitcoin, and Avalanche are the top five blockchains in the layer 1 blockchain segment on the basis of dominance and TVL.
Layer 1 Blockchains | Dominance | TVL |
Ethereum | 81.13% | $67,117,291,559 |
BNB Smart Chain | 6.81% | $5,636,030,854 |
Solana | 5.83% | $4,820,977,767 |
Bitcoin | 1.42% | $1,175,529,567 |
Avalanche | 1.22% | $1,007,843,019 |
Among the top five layer 1 chains, Ethereum dominates with 81.13% dominance. BNB Smart Chain and Solana follow with 6.81% and 5.83%. Bitcoin shows 1.42% dominance, and Avalanche displays 1.22% dominance.
1.1.1. Top Layer 1 Chains: 30-Day Change
Layer 1 Blockchains | 30-day Change |
Ethereum | +23.3% |
BNB Smart Chain | +5.2% |
Solana | +28.1% |
Bitcoin | -2.6% |
Avalanche | +7.8% |
Among these blockchain, only Bitcoin shows a negative 30-day change; it displays a change of -2.6%. Solana marks the highest 30-day change of +28.1%. Ethereum closely follows with +23.3% change. Avalanche and BNB Smart Chain showcases minimal positive changes of +7.8% and +5.2%, respectively.
1.2. Top Five Layer 2 Chains by TVL and Dominance
Arbitrum One, Blast, Base, Polygon POS and Optimism are the top five blockchains in the layer 2 segment, based on TVL and Dominance.
Layer 2 Blockchains | Dominance | TVL |
Arbitrum One | 29.50% | $3,148,514,895 |
Blast | 18.52% | $1,976,079,698 |
Base | 16.66% | $1,778,022,834 |
Polygon POS | 9.28% | $990,739,279 |
Optimism | 8.42% | $898,103,584 |
Among the top five layer 2 chains, Arbitrum One leads with 29.50% dominance. Blast and Base closely follow with 18.52% and 16.66%, respectively. Polygon POS and Optimism exhibit 9.28% and 8.42%, respectively.
1.2.1. Top Layer 2 Chains: 30-Day Change
Layer 2 Blockchains | 30-days Change |
Arbitrum One | +18.9% |
Blast | +37.5% |
Base | +12.4% |
Polygon POS | +8.4% |
Optimism | +2.0% |
All the chains in the top five layer 2 chains list show positive 30-day changes. Blast registers the highest positive 30-day change of +37.5%. Arbitrum One and Base follow with +18.9% and +12.4%. Polygon POS depicts a change of +8.4%. Optimism presents a minimal change of +2.0%.
2. Best Blockchains This Month By 30-Day Change
In this section, we focus only on the 30-day change indicator, without considering the TVL and Dominance indicators. Importantly, we do not separate layer 1 and layer 2 chains; instead, we consider all chains together. Our goal is to identify the best Performing blockchains based solely on their 30-day change.
Blockchains | 30-day Change | TVL |
Core | +285.4% | $23,999,916 |
Linea | +125.6% | $579,474,178 |
Scroll | +63.9% | $120,705,581 |
StarkNet | +46.0% | $309,199,498 |
Blast | +37.5% | $1,973,664,714 |
Polygon zkEVM | +28.1% | $13,137,952 |
Solana | +28.1% | $4,807,347,354 |
Sui | +26.3% | $738,154,425 |
Ethereum | +23.3% | $66,927,529,978 |
Arbitrum One | +18.9% | $3,144,667,067 |
Core registers the highest 30-day change of +285.4%. Linea follows with +125.6%. Scroll, StarkNet, and Blast record +63.9%, +46.0% and +37.5% change, respectively. Polygon zkEVM, Solana, and Sui also register +28.1%, +28.1% and +26.3% change, respectively.
Notably, Ethereum, the top layer 1 chain by dominance and TVL, is in the ninth position, with +23.3% change, and Arbitrum One, the top layer 2 chain by dominance and TVL, is in the tenth position, with +18.9% change.
Among the top five layer 1 chains, only Ethereum and Solana find places in this list, and among the top five layer 2 chains, Arbitrum One and Blast have positions in the list.
3. Blockchains In-Depth Analysis
In this section, we conduct an in-depth analysis of the top five blockchains. We examine various aspects, including economic activity, user interest, development and innovation, scalability, latency, cost, and market performance. To provide more clarity, we analyse the top five-layer 1 and layer 2 chains separately.
3.1. Blockchain Economic Activity Analysis
To perform the economic activity analysis, we mainly use four indices: revenue, fees, volume, and TVL. The revenue indicator shows the total blockchain earnings. The fee indicator reflects the cost users pay for transactions. The volume indicator, the second important indicator to analyse blockchain economic activity, represents the total amount of transactions. The TVL indicator, which is the primary indicator for analysing economic activity in blockchains, measures the total capital staked or locked in the blockchain.
3.1.1. Top Layer 1 Chain Economic Activity Analysis
Layer 1 Blockchains | Revenue | Fees | Volume | TVL |
Ethereum | $6.27M | $8.06M | $2.215B | $66.798B |
BNB Smart Chain | $39.67K | $398.21K | $545.23M | $5.589B |
Solana | $935.09K | $1.87M | $1.129B | $4.756B |
Bitcoin | N/A | $1.56M | $237.88K | $1.167B |
Avalanche | $24.36K | $24.36K | $45.99M | $995.59M |
Among the top five-layer 1 chains by TVL, Ethereum, which has the highest TVL of $66.798B, records the highest revenue of $6.27M. Solana, showing the third highest TVL of $4.756B after BNB Smart Chain’s $5.589B, follows with $935.09K. BNB Smart Chain only marks a revenue of $39.67K. Avalanche, the one with the fifth highest TVL among the top five, registers just $24.36K in revenue.
In terms of volume also, Ethereum dominates with $2.215B. Solana closely follows with $1.129B. BNB Smart Chain and Avalanche exhibit $545.23M and $45.99M volume, respectively. Bitcoin, with just $237.88K volume, is in the fifth position.
Let’s consider the fees index. Ethereum, with $8.06M, dominates in this parameter as well. Solana and Bitcoin follow with $1.87M and $1.56M fees, respectively. BNB Smart Chain has a fees of $398.21K, and Avalanche has $24.36K.
3.1.2. Top Layer 2 Chains Economic Activity Analysis
Layer 2 Blockchains | Revenue | Fees | Volume | TVL |
Arbitrum One | $142.69K | $146.64K | $710.1M | $3.136B |
Blast | N/A | N/A | $27.71M | $1.965B |
Base | $208.4K | $209.34K | $373.23M | $1.768B |
Polygon POS | $3.71K | $27.19K | $62.16M | $984.56M |
Optimism | $67.94K | $68.91K | $124.61M | $891.48M |
Among the top five layer 2 chains by TVL, in terms of revenue, Base, with the third highest TVL of $1.768B TVL, dominates with $208.4K. Arbitrum One, with the highest TVL of $3.136B, follows with $142.69K. Optimism marks a revenue of $67.94K, and Polygon POS records a minimal revenue of $3.71K.
While considering volume, Arbitrum One has an impressive volume of $710.1M. Base also registers a high volume of $373.23M. Optimism reports $124.61M volume, and Polygon POS and Blast register $62.16M and $27.71M, respectively.
When it comes to fees, Base has the highest fees of $209.34K, and Arbitrum One has a high fee of $146.64K. Optimism and Polygon POS follow with $68.91K and 27.19K fees, respectively.
3.2. Blockchain User Interest Analysis
To analyse the user interest of the blockchains, we primarily use the net inflow index, which indicates the amount of new capital entering the blockchain.
A blockchain with the top net inflow index shows high user interest, indicating many people are investing and bringing new capital into it. Positive values indicate increasing user interest and capital inflow, while negative values suggest decreasing interest and capital outflow.
3.2.1. Top Layer 1 Chains User Interest Analysis
Layer 1 Blockchains | Net Inflow |
Ethereum | +$2.09M |
BNB Smart Chain | -$1.13M |
Solana | N/A |
Bitcoin | N/A |
Avalanche | +$7.71M |
Avalanche has the highest positive net inflow of +$7.71M. Ethereum follows with +$2.09M. Conversely, BNB Smart Chain has a negative net inflow of -$1.13M.
3.2.2. Top Layer 2 Chains User Interest Analysis
Layer 2 Blockchains | Net Inflow |
Arbitrum One | -$1.553B |
Blast | -$0.42M |
Base | -$3.39M |
Polygon POS | +$3.94M |
Optimism | -$7.94M |
Among the top five layer 2 chains by TVL, only Polygon POS shows a positive net inflow; it records a net inflow of +3.94M. Arbitrum One registers the highest negative net inflow of -$1.553B. Optimism, Base and Blast follow with -$7.94M, -$3.39M, and -$0.42M net inflow, respectively.
3.3. Blockchain Development and Innovation Analysis
To do the blockchain development and innovation analysis, we mainly use two indices: commits and core developers. The commits indicator reflects the frequency and extent of code updates, improvements and innovations being made to the blockchains. The core developers indicator speaks about a blockchain’s capacity for sustained development. A higher number of core developers indicates a strong, active and diverse development team.
3.3.1. Top Layer 1 Chains Development and Innovation Analysis
Layer 1 Blockchains | Commits | Core Developers |
Ethereum | 12.92K | 381 |
BNB Smart Chain | 382 | 32 |
Solana | 254 | 19 |
Bitcoin | N/A | N/A |
Avalanche | 2.21K | 40 |
Among the top layer 1 chains, Ethereum shows the highest number of commits of 12.92K and the highest number of core developers of 381. Avalanche follows with 2.21K commits and 40 core developers. BNB Smart Chain records 382 commits and 32 core developers, and Solana reports 254 commits and 19 core developers.
3.3.2. Top Layer 2 Chains Development and Innovation Analysis
Layer 2 Blockchains | Commits | Core Developers |
Arbitrum One | 1.57K | 43 |
Blast | N/A | N/A |
Base | 313 | 22 |
Polygon POS | 168 | 17 |
Optimism | 2.97K | 55 |
Among the top layer 2 chains, Optimism dominates with 2.97K commits and 55 core developers. Arbitrum One follows with 1.57K commits and 43 core developers. Base shows 313 commits and 22 core developers, and Polygon POS displays 168 commits and 17 core developers.
3.4. Blockchain Scalability Analysis
To perform the blockchain scalability analysis, we utilise three indices: Real-Time TPS, Max Recorded TPS and Max Theoretical TPS. Real-Time TPS shows how many transactions per second a blockchain is processing. This metric is calculated by taking different time intervals; here we consider the one month timeframe. Max Recorded TPS records the highest number of transactions per second achieved by a blockchain in its history. Max Theoretical TPS represents how many transactions the blockchain is theoretically capable of handling per second.
3.4.1. Top Layer 1 Chains Scalability Analysis
Layer 1 Blockchains | Real-Time TPS | Max Recorded TPS | Max Theoretical TPS |
Ethereum | 13.45 tx/s | 62.34 tx/s | 119 tx/s |
BNB Smart Chain | 39.94 tx/s | 1,731 tx/s | 2,222 tx/s |
Solana | 860 tx/s | 1,624 tx/s | 65,000 tx/s |
Bitcoin | 6.56 tx/s | 12.36 tx/s | 7 tx/s |
Avalanche | 2.09 tx/s | 92.74 tx/s | 357 tx/s |
Among the top layer 1 chains, Solana has the highest Real-Time TPS of 860 tx/s. BNB Smart Chain follows with 39.94 tx/s. Ethereum, Bitcoin, and Avalanche register just 13.45 tx/s, 6.56 tx/s and 2.09 tx/s, respectively.
Meanwhile, BNB Smart Chain has the highest Max Recorded TPS of 1,731 tx/s. Solana follows with 1,624 tx/s. Avalanche and Ethereum mark impressive values of 92.74 tx/s and 62.34 tx/s, respectively.
Interestingly, Solana has the highest Max Theoretical TPS of 65,000 tx/s. BNB Smart Chain has the second-highest value of 2,222 tx/s. Avalanche and Ethereum mark satisfactory values of 357 tx/s and 119 tx/s. Bitcoin shows a minimal value of 7 tx/s.
3.4.2. Top Layer 2 Chains Scalability Analysis
Layer 2 Blockchains | Real-Time TPS | Max Recorded TPS | Max Theoretical TPS |
Arbitrum One | 22.99 tx/s | 532 tx/s | 40,000 tx/s |
Blast | N/A | N/A | N/A |
Base | 24.95 tx/s | 293 tx/s | 1,429 tx/s |
Polygon POS | 46.39 tx/s | 282 tx/s | 649 tx/s |
Optimism | 6.77 tx/s | 33.47 tx/s | 714 tx/s |
Among the top five-layer 2 chains, Polygon POS has the highest Real-Time TPS of 46.39 tx/s. Base and Arbitrum One closely follow with 24.95 tx/s and 22.99 tx/s, respectively. Optimism records 6.77 tx/s Real-Time TPS.
At the same time, Arbitrum One has the highest Max Recorded TPS of 532 tx/s. Base and Polygon POS follow with 293 tx/s and 282 tx/s, respectively. Optimism displays a minimum value of 33.47 tx/s.
Notably, Arbitrum One has the highest maximum theoretical TPS of 40,000 tx/s. Base, Optimism and Polygon POS follow with 1,429 tx/s, 714 tx/s, and 649 tx/s, respectively.
3.5. Blockchain Latency Analysis
To perform the blockchain latency analysis, we majorly consider two indices: TTF and Block Time. TTF, or Time To Finality, is the duration of time it takes for a transaction to be considered completed in a blockchain network. Block Time is the average amount of time it takes for a new block to be added to a blockchain.
3.5.1. Top Layer 1 Chains Latency Analysis
Layer 1 Blockchains | TTF | Block Time |
Ethereum | 16 minutes | 12.08 seconds |
BNB Smart Chain | 7.5s | 3.01s |
Solana | 12.8s | 0.46s |
Bitcoin | 1h | 10m 6s |
Avalanche | 0s | 2.1s |
Among the top layer 1 chains, Avalanche has the shortest TTF. BNB Smart Chain and Solana follow with 7.5 seconds and 12.8 seconds TTF, respectively. Bitcoin has the longest TTF of 1 hour, and Etheruem the second longest of 16 minutes.
Meanwhile, Solana has the shortest Block Time of 0.46 seconds. Avalanche, BNB Smart Chain and Ethereum follow with 2.1s, 3.01s and 12.08s, respectively. Bitcoin has the longest Block Time of 10 minutes and six seconds.
3.5.2. Top Layer 2 Chains Latency Analysis
Layer 2 Blockchains | TTF | Block Time |
Arbitrum One | 16m | 0.25s |
Blast | N/A | N/A |
Base | 16m | 2s |
Polygon POS | 4m 16s | 2.28s |
Optimism | 16m | 2s |
Among the top five layer 2 blockchains, Polygon POS has the shortest TTF of 4 minutes and 16 seconds. Arbitrum One, Base, and Optimism show the same TTF of sixteen minutes.
At the same time, Arbitrum One has the shortest Block Time of 0.25 seconds. Base and Optimism follow with the same Block Time of two seconds. Polygon POS records the highest Block Time of 2.28 seconds.
3.6. Blockchain Cost Analysis
To do the blockchain cost analysis, we can utilise the Gas Price index. Gas price is the amount of money that users are willing to pay per unit of “Gas.” Gas is a measure of computational effort required to perform a task or transaction on the blockchain.
3.6.1. Top Layer 1 Chains Cost Analysis
Layer 1 Blockchains | Gas Price (in Gwei) | Gas Price (in USD) |
Ethereum | 18.0 Gwei | $1.44 |
BNB Smart Chain | 1.1 Gwei | $0.014 |
Solana | 22 Gwei | $0.000066 |
Bitcoin | N/A | N/A |
Avalanche | 25.0 Gwei | $0.019 |
Among the top layer 1 chains, Solana has the lowest gas price of $0.000066. BNB Smart Chain and Avalanche follow with $0.014 and $0.019, respectively. Ethereum marks the highest gas price of $1.44.
3.6.2. Top Layer 2 Chains Cost Analysis
Layer 2 Blockchains | Gas Price (in Gwei) | Gas Price (in USD) |
Arbitrum One | 0.0 Gwei | $0.00096 |
Blast | 0.0 Gwei | $0.0012 |
Base | 0.0 Gwei | $0.00095 |
Polygon POS | 49.0 Gwei | $0.00076 |
Optimism | 0.1 Gwei | $0.0050 |
Among the top five layer 2 chains, Polygon POS has the lowest gas price of $0.00076. Base and Arbitrum One follow with $0.00095 and $0.00096, respectively. Blast shows a comparatively high gas price of $0.0012. Optimism records the highest gas price of $0.0050.
3.7. Blockchain Market Performance Analysis
To perform the market performance analysis, we generally consider three indices: 30-day change, volume and revenue. The 30-day change index shows the recent performance trend of the blockchain. The volume index indicates the level of trading activity and liquidity. The revenue index reflects the financial health and profitability of the blockchain.
A blockchain with top 30-day change, volume and revenue indicates strong recent performance, high trading activity, and robust financial health.
3.7.1. Top Layer 1 Chains Market Performance Analysis
Layer 1 Blockchains | 30-day Change | Volume | Revenue |
Ethereum | +23.3% | $2.215B | $6.27M |
BNB Smart Chain | +5.2% | $545.23M | $39.67K |
Solana | +28.1% | $1.129B | $935.09K |
Bitcoin | -2.6% | $237.88K | N/A |
Avalanche | +7.8% | $45.99M | $24.36K |
Among the top five layer 1 blockchains, only one chain shows a negative 30-day change; Bitcoin marks a negative 30-day change of -2.6%. Solana and Ethereum register high changes of +28.1% and +23.3%, respectively. Avalanche and BNB Smart Chain display moderate change of +7.8% and +5.2%, respectively.
Meanwhile, Ethereum has the highest volume of $2.215B. Solana follows with $1.129B. BNB Smart Chain and Avalanche showcase moderate values of $545.23M and $45.99M, respectively. Bitcoin records a moderate volume of $237.88K.
Notably, Ethereum reports the highest revenue of $6.27M. Solana follows with $935.09K revenue. BNB Smart Chain and Avalanche display minimal values of $39.67K and $24.36K, respectively.
3.7.2. Top Layer 2 Chains Market Performance Analysis
Layer 2 Blockchains | 30-days Change | Volume | Revenue |
Arbitrum One | +18.9% | $710.1M | $142.69K |
Blast | +37.5% | $27.71M | N/A |
Base | +12.4% | $373.23M | $208.4K |
Polygon POS | +8.4% | $62.16M | $3.71K |
Optimism | +2.0% | $124.61M | $67.94K |
Among the top five layer 2 chains, all of them show a positive 30-day change. Blast marks the highest 30-day change of +37.5%. Arbitrum One and Base follow with +18.9% and +12.4%, respectively. Polygon POS exhibits +8.4% change. Optimism showcases the smallest 30-day change of +2.0%.
At the same time, Arbitrum One exhibits the highest volume of $710.1M. Base and Optimism follow with 373.23M and 124.61M, respectively. Polygon POS and Blast display $62.16M and $27.71M, respectively.
Interestingly, Base has the highest revenue of $208.4K. Arbitrum One and Optimism follow with $142.69K and 67.94K, respectively. Polygon POS exhibits the lowest revenue of $3.71K.
Endnote
Thank you for reading our Blockchain Monthly Report for May 2024. We aim to offer a clear and thorough understanding of the blockchain landscape. By leveraging reliable sources and cutting-edge methodologies, we provide detailed insights. We hope this report aids your decision-making and deepens your knowledge of the blockchain sector.
News
An enhanced consensus algorithm for blockchain
The introduction of the link and reputation evaluation concepts aims to improve the stability and security of the consensus mechanism, decrease the likelihood of malicious nodes joining the consensus, and increase the reliability of the selected consensus nodes.
The link model structure based on joint action
Through the LINK between nodes, all the LINK nodes engage in consistent activities during the operation of the consensus mechanism. The reputation evaluation mechanism evaluates the trustworthiness of nodes based on their historical activity status throughout the entire blockchain. The essence of LINK is to drive inactive nodes to participate in system activities through active nodes. During the stage of selecting leader nodes, nodes are selected through self-recommendation, and the reputation evaluation of candidate nodes and their LINK nodes must be qualified. The top 5 nodes of the total nodes are elected as leader nodes through voting, and the nodes in their LINK status are candidate nodes. In the event that the leader node goes down, the responsibility of the leader node is transferred to the nodes in its LINK through the view-change. The LINK connection algorithm used in this study is shown in Table 2, where LINKm is the linked group and LINKP is the percentage of linked nodes.
Table 2 LINK connection algorithm.
Node type
This paper presents a classification of nodes in a blockchain system based on their functionalities. The nodes are divided into three categories: leader nodes (LNs), follower nodes (FNs), and general nodes (Ns). The leader nodes (LNs) are responsible for producing blocks and are elected through voting by general nodes. The follower nodes (FNs) are nodes that are linked to leader nodes (LNs) through the LINK mechanism and are responsible for validating blocks. General nodes (N) have the ability to broadcast and disseminate information, participate in elections, and vote. The primary purpose of the LINK mechanism is to act in combination. When nodes are in the LINK, there is a distinction between the master and slave nodes, and there is a limit to the number of nodes in the LINK group (NP = {n1, nf1, nf2 ……,nfn}). As the largest proportion of nodes in the system, general nodes (N) have the right to vote and be elected. In contrast, leader nodes (LNs) and follower nodes (FNs) do not possess this right. This rule reduces the likelihood of a single node dominating the block. When the system needs to change its fundamental settings due to an increase in the number of nodes or transaction volume, a specific number of current leader nodes and candidate nodes need to vote for a reset. Subsequently, general nodes need to vote to confirm this. When both confirmations are successful, the new basic settings are used in the next cycle of the system process. This dual confirmation setting ensures the fairness of the blockchain to a considerable extent. It also ensures that the majority holds the ultimate decision-making power, thereby avoiding the phenomenon of a small number of nodes completely controlling the system.
After the completion of a governance cycle, the blockchain network will conduct a fresh election for the leader and follower nodes. As only general nodes possess the privilege to participate in the election process, the previous consortium of leader and follower nodes will lose their authorization. In the current cycle, they will solely retain broadcasting and receiving permissions for block information, while their corresponding incentives will also decrease. A diagram illustrating the node status can be found in Fig. 1.
Election method
The election method adopts the node self-nomination mode. If a node wants to participate in an election, it must form a node group with one master and three slaves. One master node group and three slave node groups are inferred based on experience in this paper; these groups can balance efficiency and security and are suitable for other project collaborations. The successfully elected node joins the leader node set, and its slave nodes enter the follower node set. Considering the network situation, the maximum threshold for producing a block is set to 1 s. If the block fails to be successfully generated within the specified time, it is regarded as a disconnected state, and its reputation score is deducted. The node is skipped, and in severe cases, a view transformation is performed, switching from the master node to the slave node and inheriting its leader’s rights in the next round of block generation. Although the nodes that become leaders are high-reputation nodes, they still have the possibility of misconduct. If a node engages in misconduct, its activity will be immediately stopped, its comprehensive reputation score will be lowered, it will be disqualified from participating in the next election, and its equity will be reduced by 30%. The election process is shown in Fig. 2.
Incentives and penalties
To balance the rewards between leader nodes and ordinary nodes and prevent a large income gap, two incentive/penalty methods will be employed. First, as the number of network nodes and transaction volume increase, more active nodes with significant stakes emerge. After a prolonged period of running the blockchain, there will inevitably be significant class distinctions, and ordinary nodes will not be able to win in the election without special circumstances. To address this issue, this paper proposes that rewards be reduced for nodes with stakes exceeding a certain threshold, with the reduction rate increasing linearly until it reaches zero. Second, in the event that a leader or follower node violates the consensus process, such as by producing a block out of order or being unresponsive for an extended period, penalties will be imposed. The violation handling process is illustrated in Fig. 3.
Violation handling process.
Comprehensive reputation evaluation and election mechanism based on historical transactions
This paper reveals that the core of the DPoS consensus mechanism is the election process. If a blockchain is to run stably for a long time, it is essential to consider a reasonable election method. This paper proposes a comprehensive reputation evaluation election mechanism based on historical records. The mechanism considers the performance indicators of nodes in three dimensions: production rate, tokens, and validity. Additionally, their historical records are considered, particularly whether or not the nodes have engaged in malicious behavior. For example, nodes that have ever been malicious will receive low scores during the election process unless their overall quality is exceptionally high and they have considerable support from other nodes. Only in this case can such a node be eligible for election or become a leader node. The comprehensive reputation score is the node’s self-evaluation score, and the committee size does not affect the computational complexity.
Moreover, the comprehensive reputation evaluation proposed in this paper not only is a threshold required for node election but also converts the evaluation into corresponding votes based on the number of voters. Therefore, the election is related not only to the benefits obtained by the node but also to its comprehensive evaluation and the number of voters. If two nodes receive the same vote, the node with a higher comprehensive reputation is given priority in the ranking. For example, in an election where node A and node B each receive 1000 votes, node A’s number of stake votes is 800, its comprehensive reputation score is 50, and only four nodes vote for it. Node B’s number of stake votes is 600, its comprehensive reputation score is 80, and it receives votes from five nodes. In this situation, if only one leader node position remains, B will be selected as the leader node. Displayed in descending order of priority as comprehensive credit rating, number of voters, and stake votes, this approach aims to solve the problem of node misconduct at its root by democratizing the process and subjecting leader nodes to constraints, thereby safeguarding the fundamental interests of the vast majority of nodes.
Comprehensive reputation evaluation
This paper argues that the election process of the DPoS consensus mechanism is too simplistic, as it considers only the number of election votes that a node receives. This approach fails to comprehensively reflect the node’s actual capabilities and does not consider the voters’ election preferences. As a result, nodes with a significant stake often win and become leader nodes. To address this issue, the comprehensive reputation evaluation score is normalized considering various attributes of the nodes. The scoring results are shown in Table 3.
Table 3 Comprehensive reputation evaluation.
Since some of the evaluation indicators in Table 3 are continuous while others are discrete, different normalization methods need to be employed to obtain corresponding scores for different indicators. The continuous indicators include the number of transactions/people, wealth balance, network latency, network jitter, and network bandwidth, while the discrete indicators include the number of violations, the number of successful elections, and the number of votes. The value range of the indicator “number of transactions/people” is (0,1), and the value range of the other indicators is (0, + ∞). The equation for calculating the “number of transactions/people” is set as shown in Eq. (1).
$$A_{1} = \left\{ {\begin{array}{*{20}l} {0,} \hfill & {{\text{G}} = 0} \hfill \\ {\frac{{\text{N}}}{{\text{G}}}*10,} \hfill & {{\text{G}} > 0} \hfill \\ \end{array} } \right.$$
(1)
where N represents the number of transactional nodes and G represents the number of transactions. It reflects the degree of connection between the node and other nodes. Generally, nodes that transact with many others are safer than those with a large number of transactions with only a few nodes. The limit value of each item, denoted by x, is determined based on the situation and falls within the specified range, as shown in Eq. (2). The wealth balance and network bandwidth indicators use the same function to set their respective values.
$${A}_{i}=20*\left(\frac{1}{1+{e}^{-{a}_{i}x}}-0.5\right)$$
(2)
where x indicates the value of this item and expresses the limit value.
In Eq. (3), x represents the limited value of this indicator. The lower the network latency and network jitter are, the higher the score will be.
The last indicators, which are the number of violations, the number of elections, and the number of votes, are discrete values and are assigned different scores according to their respective ranges. The scores corresponding to each count are shown in Table 4.
$$A_{3} = \left\{ {\begin{array}{*{20}l} {10*\cos \frac{\pi }{200}x,} \hfill & {0 \le x \le 100} \hfill \\ {0,} \hfill & {x > 100} \hfill \\ \end{array} } \right.$$
(3)
Table 4 Score conversion.
The reputation evaluation mechanism proposed in this paper comprehensively considers three aspects of nodes, wealth level, node performance, and stability, to calculate their scores. Moreover, the scores obtain the present data based on historical records. Each node is set as an M × N dimensional matrix, where M represents M times the reputation evaluation score and N represents N dimensions of reputation evaluation (M < = N), as shown in Eq. (4).
$${\text{N}} = \left( {\begin{array}{*{20}c} {a_{11} } & \cdots & {a_{1n} } \\ \vdots & \ddots & \vdots \\ {a_{m1} } & \cdots & {a_{mn} } \\ \end{array} } \right)$$
(4)
The comprehensive reputation rating is a combined concept related to three dimensions. The rating is set after rating each aspect of the node. The weight w and the matrix l are not fixed. They are also transformed into matrix states as the position of the node in the system changes. The result of the rating is set as the output using Eq. (5).
$$\text{T}=\text{lN}{w}^{T}=\left({l}_{1}\dots {\text{l}}_{\text{m}}\right)\left(\begin{array}{ccc}{a}_{11}& \cdots & {a}_{1n}\\ \vdots & \ddots & \vdots \\ {a}_{m1}& \cdots & {a}_{mn}\end{array}\right){\left({w}_{1}\dots {w}_{n}\right)}^{T}$$
(5)
Here, T represents the comprehensive reputation score, and l and w represent the correlation coefficient. Because l is a matrix of order 1*M, M is the number of times in historical records, and M < = N is set, the number of dimensions of l is uncertain. Set the term l above to add up to 1, which is l1 + l2 + …… + ln = 1; w is also a one-dimensional matrix whose dimension is N*1, and its purpose is to act as a weight; within a certain period of time, w is a fixed matrix, and w will not change until the system changes the basic settings.
Assume that a node conducts its first comprehensive reputation rating, with no previous transaction volume, violations, elections or vote. The initial wealth of the node is 10, the latency is 50 ms, the jitter is 100 ms, and the network bandwidth is 100 M. According to the equation, the node’s comprehensive reputation rating is 41.55. This score is relatively good at the beginning and gradually increases as the patient participates in system activities continuously.
Voting calculation method
To ensure the security and stability of the blockchain system, this paper combines the comprehensive reputation score with voting and randomly sorts the blocks, as shown in Eqs. (3–6).
$$Z=\sum_{i=1}^{n}{X}_{i}+nT$$
(6)
where Z represents the final election score, Xi represents the voting rights earned by the node, n is the number of nodes that vote for this node, and T is the comprehensive reputation score.
The voting process is divided into stake votes and reputation votes. The more reputation scores and voters there are, the more total votes that are obtained. In the early stages of blockchain operation, nodes have relatively few stakes, so the impact of reputation votes is greater than that of equity votes. This is aimed at selecting the most suitable node as the leader node in the early stage. As an operation progresses, the role of equity votes becomes increasingly important, and corresponding mechanisms need to be established to regulate it. The election vote algorithm used in this paper is shown in Table 5.
Table 5 Election vote counting algorithm.
This paper argues that the election process utilized by the original DPoS consensus mechanism is overly simplistic, as it relies solely on the vote count to select the node that will oversee the entire blockchain. This approach cannot ensure the security and stability of the voting process, and if a malicious node behaves improperly during an election, it can pose a significant threat to the stability and security of the system as well as the safety of other nodes’ assets. Therefore, this paper proposes a different approach to the election process of the DPoS consensus mechanism by increasing the complexity of the process. We set up a threshold and optimized the vote-counting process to enhance the security and stability of the election. The specific performance of the proposed method was verified through experiments.
The election cycle in this paper can be customized, but it requires the agreement of the blockchain committee and general nodes. The election cycle includes four steps: node self-recommendation, calculating the comprehensive reputation score, voting, and replacing the new leader. Election is conducted only among general nodes without affecting the production or verification processes of leader nodes or follower nodes. Nodes start voting for preferred nodes. If they have no preference, they can use the LINK mechanism to collaborate with other nodes and gain additional rewards.
View changes
During the consensus process, conducting a large number of updates is not in line with the system’s interests, as the leader node (LN) and follower node (FN) on each node have already been established. Therefore, it is crucial to handle problematic nodes accurately when issues arise with either the LN or FN. For instance, when a node fails to perform its duties for an extended period or frequently fails to produce or verify blocks within the specified time range due to latency, the system will precisely handle them. For leader nodes, if they engage in malicious behavior such as producing blocks out of order, the behavior is recorded, and their identity as a leader node is downgraded to a follower node. The follower node inherits the leader node’s position, and the nature of their work is transformed as they swap their responsibilities of producing and verifying blocks with their original work. This type of behavior will not significantly affect the operation of the blockchain system. Instead of waiting until the end of the current committee round to punish malicious nodes, dynamic punishment is imposed on the nodes that affect the operation of the blockchain system to maintain system security. The view change operation is illustrated in Fig. 4.
In traditional PBFT, view changes are performed according to the view change protocol by changing the view number V to the next view number V + 1. During this process, nodes only receive view change messages and no other messages from other nodes. In this paper, the leader node group (LN) and follower node group (FN) are selected through an election of the LINK group. The node with LINKi[0] is added to the LN leader node group, while the other three LINK groups’ follower nodes join the FN follower node group since it is a configuration pattern of one master and three slaves. The view change in this paper requires only rearranging the node order within the LINK group to easily remove malicious nodes. Afterward, the change is broadcast to other committee nodes, and during the view transition, the LINK group does not receive block production or verification commands from the committee for stability reasons until the transition is completed.
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The Hype Around Blockchain Mortgage Has Died Down, But This CEO Still Believes
LiquidFi Founder Ian Ferreira Sees Huge Potential in Blockchain Despite Hype around technology is dead.
“Blockchain technology has been a buzzword for a long time, and it shouldn’t be,” Ferriera said. “It should be a technology that lives in the background, but it makes everything much more efficient, much more transparent, and ultimately it saves costs for everyone. That’s the goal.”
Before founding his firm, Ferriera was a portfolio manager at a hedge fund, a job that ended up revealing “interesting intricacies” related to the mortgage industry.
Being a mortgage trader opened Ferriera’s eyes to a lot of the operational and infrastructure problems that needed to be solved in the mortgage-backed securities industry, he said. That later led to the birth of LiquidFi.
“The point of what we do is to get raw data attached to a resource [a loan] on a blockchain so that it’s provable. You reduce that trust problem because you have the data, you have the document associated with that data,” said the LiquidFi CEO.
Ferriera spoke with National Mortgage News about the value of blockchain technology, why blockchain hype has fizzled out, and why it shouldn’t.
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New bill pushes Department of Veterans Affairs to examine how blockchain can improve its work
The Department of Veterans Affairs would have to evaluate how blockchain technology could be used to improve benefits and services offered to veterans, according to a legislative proposal introduced Tuesday.
The bill, sponsored by Rep. Nancy Mace, R-S.C., would direct the VA to “conduct a comprehensive study of the feasibility, potential benefits, and risks associated with using distributed ledger technology in various programs and services.”
Distributed ledger technology, including blockchain, is used to protect and track information by storing data across multiple computers and keeping a record of its use.
According to the text of the legislation, which Mace’s office shared exclusively with Nextgov/FCW ahead of its publication, blockchain “could significantly improve benefits allocation, insurance program management, and recordkeeping within the Department of Veterans Affairs.”
“We need to bring the federal government into the 21st century,” Mace said in a statement. “This bill will open the door to research on improving outdated systems that fail our veterans because we owe it to them to use every tool at our disposal to improve their lives.”
Within one year of the law taking effect, the Department of Veterans Affairs will be required to submit a report to the House and Senate Veterans Affairs committees detailing its findings, as well as the benefits and risks identified in using the technology.
The mandatory review is expected to include information on how the department’s use of blockchain could improve the way benefits decisions are administered, improve the management and security of veterans’ personal data, streamline the insurance claims process, and “increase transparency and accountability in service delivery.”
The Department of Veterans Affairs has been studying the potential benefits of using distributed ledger technology, with the department emission a request for information in November 2021 seeking input from contractors on how blockchain could be leveraged, in part, to streamline its supply chains and “secure data sharing between institutions.”
The VA’s National Institute of Artificial Intelligence has also valued the use of blockchain, with three of the use cases tested during the 2021 AI tech sprint focused on examining its capabilities.
Mace previously introduced a May bill that would direct Customs and Border Protection to create a public blockchain platform to store and share data collected at U.S. borders.
Lawmakers also proposed additional measures that would push the Department of Veterans Affairs to consider adopting other modernized technologies to improve veteran services.
Rep. David Valadao, R-Calif., introduced legislation in June that would have directed the department to report to lawmakers on how it plans to expand the use of “certain automation tools” to process veterans’ claims. The House of Representatives Subcommittee on Disability Assistance and Memorial Affairs gave a favorable hearing on the congressman’s bill during a Markup of July 23.
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California DMV Uses Blockchain to Fight Auto Title Fraud
TDR’s Three Takeaways: California DMV Uses Blockchain to Fight Fraud
- California DMV uses blockchain technology to manage 42 million auto titles.
- The initiative aims to improve safety and reduce car title fraud.
- The immutable nature of blockchain ensures accurate and tamper-proof records.
The California Department of Motor Vehicles (DMV) is implementing blockchain technology to manage and secure 42 million auto titles. This innovative move aims to address and reduce the persistent problem of auto title fraud, a problem that costs consumers and the industry millions of dollars each year. By moving to a blockchain-based system, the DMV is taking advantage of the technology’s key feature: immutability.
Blockchain, a decentralized ledger technology, ensures that once a car title is registered, it cannot be altered or tampered with. This creates a highly secure and transparent system, significantly reducing the risk of fraudulent activity. Every transaction and update made to a car title is permanently recorded on the blockchain, providing a complete and immutable history of the vehicle’s ownership and status.
As first reported by Reuters, the DMV’s adoption of blockchain isn’t just about preventing fraud. It’s also aimed at streamlining the auto title process, making it more efficient and intuitive. Traditional auto title processing involves a lot of paperwork and manual verification, which can be time-consuming and prone to human error. Blockchain technology automates and digitizes this process, reducing the need for physical documents and minimizing the chances of errors.
Additionally, blockchain enables faster verification and transfer of car titles. For example, when a car is sold, the transfer of ownership can be done almost instantly on the blockchain, compared to days or even weeks in the conventional system. This speed and efficiency can benefit both the DMV and the vehicle owners.
The California DMV’s move is part of a broader trend of government agencies exploring blockchain technology to improve their services. By adopting this technology, the DMV is setting a precedent for other states and industries to follow, showcasing blockchain’s potential to improve safety and efficiency in public services.
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