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Portable Ethereum Proof-of-Work Blockchain Network on Raspberry Pi Nodes


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A prototype of a blockchain-in-a-box system that allows users to easily bootstrap and orchestrate an Ethereum Proof-of-Work (PoW) network running on multiple Raspberry Pi nodes.
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The paper presents a prototype of a blockchain-in-a-box system that enables users to easily set up and manage an Ethereum Proof-of-Work (PoW) network running on multiple Raspberry Pi nodes. The system consists of a local server running on each Raspberry Pi that listens for commands from a master server, which provides a web-based interface for orchestrating the blockchain network.

The key features of the prototype include:

  1. Hardware setup: The system uses Raspberry Pi computers as the blockchain nodes, along with a Wi-Fi router, network switch, and power supplies to create a self-contained, portable blockchain network.

  2. Software setup: Each Raspberry Pi runs a local server that can initialize and manage an Ethereum PoW node using the Go Ethereum (geth) client. The master server controls the Raspberry Pi nodes and allows users to adjust parameters like mining difficulty and peer-to-peer (P2P) network topology.

  3. Visualization: Each Raspberry Pi has a screen attached that displays the current state of its local blockchain, making it easy to observe whether the network is in consensus.

The authors conduct experiments to measure the consensus quality of the blockchain network under different P2P topologies (ring, star, and grid). They analyze metrics such as mainchain rate, branching ratio, contribution ratio, and initial consensus to evaluate the impact of the network topology on the overall consensus.

The results show that the ring topology outperforms the grid and star topologies in terms of mainchain rate and branching ratio, despite the star topology having the shortest average distance between nodes. This is likely due to the overhead of managing multiple peer connections in the star topology, which can act as a bottleneck for consensus.

The prototype demonstrates the feasibility of running a fully functional blockchain network on modest hardware, and its portability and visualization capabilities make it a valuable tool for educational and experimental purposes.

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Statistieken
The mining difficulty parameter was set to 215,000 to achieve a block generation rate of around 0.75 to 1 second. The experiments were conducted with 9 Raspberry Pi nodes. The mainchain rate (higher is better) was significantly higher in the ring topology compared to the grid and star topologies. The branching ratio (lower is better) was highest in the star topology, indicating issues with consensus. The contribution ratio of each node was expected to be 1/9 = 0.11, but there was some variation with outliers, especially in the star topology. The initial consensus (number of blocks required for a node to join the mainchain) was usually less than 25 blocks, but some nodes struggled to achieve initial consensus, taking over 100 blocks.
Citaten
"In our experiments we used geth client, which is one of the most popular execution clients for Ethereum, however other clients could exhibit different behavior." "Experiments described in the last section demonstrate that our blockchain-in-a-box prototype is capable enough to conduct consensus quality measurements in a completely isolated environment, not even using an Internet connection, yet running a fully functional version of the Ethereum PoW blockchain network." "Running a blockchain network through a hardware setup, as opposed to a software simulation, results in a much more realistic behaviour. For example, measurements in all of the experiments above are significantly influenced by the communication overhead between nodes - a fact that node has finite computational capabilities and that, on top of consensus maintenance and mining, it has to relay messages between nodes."

Diepere vragen

How could the prototype be extended to support other blockchain protocols beyond Ethereum PoW, such as Proof-of-Stake or alternative consensus mechanisms?

To extend the prototype to support other blockchain protocols like Proof-of-Stake (PoS) or alternative consensus mechanisms, several modifications and additions would be necessary. Firstly, the software setup of the prototype would need to be reconfigured to accommodate the specific requirements of the new protocol. For PoS, the nodes would need to be adjusted to participate in the staking process rather than traditional mining. This would involve changes in how blocks are validated and added to the blockchain. Additionally, the master server's web-based control panel would need to be updated to include options and parameters relevant to the new consensus mechanism. For example, in a PoS system, users might need to specify their staking preferences or delegate their stake to other nodes. The visualization component on the Raspberry Pi screens would also need to be adapted to display information specific to the new protocol, such as staking rewards or validator status. Furthermore, the hardware setup might require enhancements to support the resource requirements of different consensus mechanisms. For instance, PoS protocols typically require less computational power than PoW, so the Raspberry Pi nodes could potentially be optimized for energy efficiency rather than raw processing power.

What are the potential limitations or challenges of using Raspberry Pi nodes for a blockchain network, and how could these be addressed to improve the system's scalability and performance?

Using Raspberry Pi nodes for a blockchain network may pose several limitations and challenges, primarily related to hardware constraints and network capabilities. One major limitation is the limited computational power and memory of Raspberry Pi devices compared to traditional mining rigs or server setups. This could impact the speed and efficiency of block validation and propagation, potentially leading to slower transaction processing times. To address these limitations and improve scalability and performance, several strategies could be implemented. One approach is to optimize the software running on the Raspberry Pi nodes to be more resource-efficient. This could involve streamlining the blockchain client software, reducing unnecessary processes, and optimizing code for the ARM architecture of the Raspberry Pi. Additionally, clustering multiple Raspberry Pi nodes together to form a more powerful network could enhance scalability. By distributing the workload among several nodes and coordinating their efforts, the overall performance of the blockchain network could be improved. Implementing load balancing techniques and parallel processing strategies could further enhance the system's scalability. Improving network connectivity and bandwidth could also address performance challenges. Upgrading to faster and more reliable networking hardware, optimizing network configurations, and implementing protocols for efficient data transmission could help overcome network-related limitations.

Given the insights gained from the experiments on network topology, how could the prototype be used to explore the impact of other factors, such as node heterogeneity or dynamic network conditions, on blockchain consensus and performance?

Building on the insights gained from the experiments on network topology, the prototype could be leveraged to explore the impact of other factors such as node heterogeneity and dynamic network conditions on blockchain consensus and performance. To investigate the effects of node heterogeneity, the prototype could be configured with Raspberry Pi nodes of varying computational power or network capabilities. By introducing nodes with different processing speeds, memory capacities, or network speeds, researchers could observe how these differences affect block validation times, consensus formation, and overall network performance. This could provide valuable insights into the role of node diversity in blockchain networks. In terms of dynamic network conditions, the prototype could be subjected to scenarios where network latency, packet loss, or bandwidth fluctuations are simulated. By introducing controlled disruptions or variations in network conditions, researchers could study how the blockchain network adapts to these challenges. This could involve measuring the impact of network instability on block propagation, fork occurrence, and consensus quality. Furthermore, the prototype could be used to explore the resilience of the blockchain network to adversarial attacks or malicious nodes. By introducing nodes programmed to behave in a non-cooperative manner or to propagate incorrect information, researchers could assess the system's ability to withstand such threats and maintain consensus integrity. Overall, by expanding the scope of experiments to include factors like node diversity, network dynamics, and adversarial conditions, the prototype could provide valuable insights into the robustness and performance of blockchain networks under various real-world scenarios.
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