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Paraverse White Paper
  • Paraverse: A Decentralized Operating and Trading Platform for 3D Digital Assets
  • Digital Parallel World
    • What is the "Digital Parallel World"?
    • Enabling Seamless Interaction with the Digital Parallel World
  • The Pain Points and Technical Challenges
    • The Pain Points and Technical Challenges
  • Paraverse Product Solutions
    • Paraverse Product Architecture Design
    • Operational System for the 3D Digital Parallel World — ParaLab
    • 3D Digital Parallel World Asset Utilization and Circulation System — ParaHere
    • Decentralized Distributed Rendering Network — Lark Network
    • Product Features
  • User Group Demand Analysis and Economic Ecosystem
    • User Group Demand Analysis
    • Paraverse Economic Ecosystem
      • User Payment System
      • Ecological Growth Strategy
      • Dynamic Analysis of PVS Token Market Capitalization Growth
  • Paraverse Core Technologies and Capabilities
    • Visual Computing GPU Resource Pooling
    • Cloud XR Network Transmission System
    • Distributed Validation Storage and Encrypted Operation of 3D Assets
    • Web3.0 combined anti-cheating mechanism for 3D applications
  • 3D Digital Asset Economic System Design
    • Token Design
      • Token Value Accumulation
      • Initial Token Distribution
      • Token circulation and stability
    • Incentive Mechanism
      • Rendering income
      • Validation Reward
      • Staking Rewards
    • Penalty Mechanism
  • Security and Privacy
    • Access Control and Authentication
    • Privacy Protection and Anonymity
    • Network Attack Prevention Measures
  • ParaDAO Community and Ecosystem
    • ParaDAO Community and Ecosystem
  • Ecosystem Development Roadmap
    • Ecosystem Development Roadmap
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  1. 3D Digital Asset Economic System Design
  2. Incentive Mechanism

Validation Reward

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Last updated 2 months ago

Only miners who join Paraverse to perform rendering tasks can participate in block validation and have the opportunity to earn validation rewards. Miners involved in block validation will perform two key tasks:

  • A randomly selected miner will validate a portion of the orders and generate a new block.

  • Other miners in the network will validate the newly submitted block.

Validation Process:

  1. Every 10 seconds, the network randomly selects a miner to validate a portion of the orders.

  2. The miner must prove that the rendering tasks for the selected orders were completed fully and efficiently. Upon validation, a new block is generated.

  3. The miner submits the rendering proof of the new block to the network. The network verifies the block using cryptographic proofs, accepting only correctly validated blocks.

  4. If more than 50% of the network's miners approve the block, the miner who created the block receives a validation reward in PAR tokens, with the reward amount randomly determined.

To encourage more miners to actively participate in rendering tasks, the weight of validation rewards will be adjusted, gradually decreasing as rendering task durations increase. Although a miner is randomly selected for validation every 10 seconds, validation rewards will be distributed at an hourly frequency to align the timing of validation and rendering rewards. This approach aims to establish a balanced incentive mechanism that encourages large-scale participation while maintaining network stability and efficiency.