Universal Market Access (UMA) is an Ethereum-compatible toolbox designed to enable users to create enforceable agreements, including project-specific smart contracts. While UMA excels in facilitating financial agreements, it is also compatible with a wide range of decentralized applications (DApps). UMA is referred to as a "decentralized truth machine" on its official website, emphasizing its role in ensuring transparency and trust within the decentralized ecosystem.
What is UMA?
UMA is a protocol specifically designed for creating programmable digital assets, enabling users to replicate traditional assets in a virtual blockchain-native form. This is achieved through an Optimistic Oracle setup, which handles real-world aspects such as prices by sourcing off-chain data. The integration of these Oracles ensures a trustless and decentralized ecosystem. In addition to its financial applications, UMA offers a wide range of Web3 apps, including prediction markets, insurance bridges, and customizable decentralized autonomous organizations (DAOs), expanding its utility beyond financial markets.
The UMA team
The UMA team, founded in 2017, was envisioned and established by Hart Lambur and Allison Lu, both former Goldman Sachs traders. Lambur also co-founded the Risk Lab Foundation, a blockchain research company that supports the UMA project. The team comprises various experienced individuals, including John Shuttt as a senior engineer, Melissa Quinn as the COO, Clayton Roche as the head of community and development, and other talented professionals. Together, they contribute their expertise and skills to the success and development of the UMA project.
How does UMA work?
The OO system associated with the UMA ecosystem accepts statements and instances projected as truth. These instances come with bonds, transforming them into workable cases. Those who can prove the instances false are rewarded.
If no disputes or challenges arise, the proposed instance (statement) is added to the chain, becoming immutable and a part of the ecosystem. Each instance comprises three aspects: a request for information, proposed information, and a case for dispute.
If a dispute is raised and proven false, the disputer loses their token deposit, while the proposer receives a portion. If proven correct, the proposer loses their deposit, and the disputer gets a part of it.
With UMA, you can easily create financial products through synthetic tokens. These tokens track the value of real-world legacy assets such as gold. Additionally, UMA utilizes a proprietary implementation of its OO setup, the Data Verification Mechanism, to ensure that the synthetic assets always track the correct real-world price.
The process itself requires smart contract support. Finally, you can trade these UMA-based assets across DApps and markets.
Universal Market Access’s native token: UMA
UMA is the ecosystem's native token. UMA tokens are ERC-20 compatible and allow holders to participate in governance-related matters of the protocol. Plus, UMA tokens can also help increase the network's overall security.
UMA tokenomics
Based on ecosystem data, nearly 114 million UMA tokens exist. The maximum supply, accounting for lost tokens, slightly exceeds 100 million. When a proposal becomes active, the participating votes receive 0.05% of UMA's supply, which may contribute to network inflation.
How to stake UMA?
To stake UMA, you should visit UMA's dedicated staking application. Connect your crypto wallet and lock your UMA tokens within a smart contract for a designated period. The staked tokens generate an additional annual percentage rate (APR) as an incentive.
In addition to staking, exercising voting rights within the ecosystem also generates incentives. UMA's direct staking app features a comprehensive dashboard that displays the percentage of staked tokens, claimed and unclaimed rewards, and earnings based on voting participation.
UMA use cases
UMA, the native token of the UMA ecosystem, facilitates DAO governance and ensures network security. These tokens also empower trustless financial innovations, enabling the creation of various synthetic assets. Furthermore, UMA tokens contribute to dispute resolution, similar to the role of a juror. Additionally, these native tokens serve as incentives or rewards for developers who build upon the UMA ecosystem.
UMA token distribution
UMA tokens are allocated as follows:
2 million UMA tokens were released during the ICO sale.
48.5 million tokens are reserved for the founding team.
35 million UMA tokens are designated as developer rewards.
14.5 million tokens are allocated for sales and trading-based activities.
The road ahead for UMA
UMA's oracle-based contracts have undergone thorough audits, ensuring their security and reliability. The ecosystem boasts a transparent governance mechanism, providing decentralized finance (DeFi) exposure through cross-chain bridges. UMA also features a pioneering, Optimistic Oracle setup, making it a forward-looking ecosystem.
UMA's credibility in the DApp and DeFi space is further reinforced by hosting innovative products such as Sherlock, a Risk Management platform, and Polymarket, a market for information. These offerings contribute to UMA's reputation and solidify its position in the industry.
UMA 的社交热度在各大平台上持续升温,表明社区对该币种的兴趣度和参与度不断高涨。讨论也在持续进行中,在过去 24 小时内新发布了 9,854 条关于 UMA 的帖子,其中有 2,665 人积极参与其中,社区互动将近 2,230万 次,也贡献了相当高的话题热度。另外,当前市场情绪值达到 54%,彰显了市场对 UMA 的总体感受和认知的洞察。 除了市场情绪这一指标外,当前 UMA 的发布量排名 0,这体现了该币种在整体数字货币市场中的重要性和关注度。随着 UMA 的持续发展,其社交指标将成为衡量其影响力和市场覆盖度的重要参考。
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发布量
9,854
参与用户人数
2,665
互动量
22,303,836
市场情绪占比
54%
发布量排名
#0
X
发布量
1,772
互动量
1,296,730
市场情绪占比
80%
UMA 常见问题
UMA 今天值多少钱?
目前,一个 UMA 价值是 $1.0630。如果您想要了解 UMA 价格走势与行情洞察,那么这里就是您的最佳选择。在欧易探索最新的 UMA 图表,进行专业交易。
数字货币是什么?
数字货币,例如 UMA 是在称为区块链的公共分类账上运行的数字资产。了解有关欧易上提供的数字货币和代币及其不同属性的更多信息,其中包括实时价格和实时图表。
UMA is present on the following networks: avalanche, ethereum.
The Avalanche blockchain network employs a unique Proof-of-Stake consensus mechanism called Avalanche Consensus, which involves three interconnected protocols: Snowball, Snowflake, and Avalanche. Avalanche Consensus Process 1. Snowball Protocol: o Random Sampling: Each validator randomly samples a small, constant-sized subset of other validators. Repeated Polling: Validators repeatedly poll the sampled validators to determine the preferred transaction. Confidence Counters: Validators maintain confidence counters for each transaction, incrementing them each time a sampled validator supports their preferred transaction. Decision Threshold: Once the confidence counter exceeds a pre-defined threshold, the transaction is considered accepted. 2. Snowflake Protocol: Binary Decision: Enhances the Snowball protocol by incorporating a binary decision process. Validators decide between two conflicting transactions. Binary Confidence: Confidence counters are used to track the preferred binary decision. Finality: When a binary decision reaches a certain confidence level, it becomes final. 3. Avalanche Protocol: DAG Structure: Uses a Directed Acyclic Graph (DAG) structure to organize transactions, allowing for parallel processing and higher throughput. Transaction Ordering: Transactions are added to the DAG based on their dependencies, ensuring a consistent order. Consensus on DAG: While most Proof-of-Stake Protocols use a Byzantine Fault Tolerant (BFT) consensus, Avalanche uses the Avalanche Consensus, Validators reach consensus on the structure and contents of the DAG through repeated Snowball and Snowflake.
The Ethereum network uses a Proof-of-Stake Consensus Mechanism to validate new transactions on the blockchain. Core Components 1. Validators: Validators are responsible for proposing and validating new blocks. To become a validator, a user must deposit (stake) 32 ETH into a smart contract. This stake acts as collateral and can be slashed if the validator behaves dishonestly. 2. Beacon Chain: The Beacon Chain is the backbone of Ethereum 2.0. It coordinates the network of validators and manages the consensus protocol. It is responsible for creating new blocks, organizing validators into committees, and implementing the finality of blocks. Consensus Process 1. Block Proposal: Validators are chosen randomly to propose new blocks. This selection is based on a weighted random function (WRF), where the weight is determined by the amount of ETH staked. 2. Attestation: Validators not proposing a block participate in attestation. They attest to the validity of the proposed block by voting for it. Attestations are then aggregated to form a single proof of the block’s validity. 3. Committees: Validators are organized into committees to streamline the validation process. Each committee is responsible for validating blocks within a specific shard or the Beacon Chain itself. This ensures decentralization and security, as a smaller group of validators can quickly reach consensus. 4. Finality: Ethereum 2.0 uses a mechanism called Casper FFG (Friendly Finality Gadget) to achieve finality. Finality means that a block and its transactions are considered irreversible and confirmed. Validators vote on the finality of blocks, and once a supermajority is reached, the block is finalized. 5. Incentives and Penalties: Validators earn rewards for participating in the network, including proposing blocks and attesting to their validity. Conversely, validators can be penalized (slashed) for malicious behavior, such as double-signing or being offline for extended periods. This ensures honest participation and network security.
奖励机制与相应费用
UMA is present on the following networks: avalanche, ethereum.
Avalanche uses a consensus mechanism known as Avalanche Consensus, which relies on a combination of validators, staking, and a novel approach to consensus to ensure the network's security and integrity. Validators: Staking: Validators on the Avalanche network are required to stake AVAX tokens. The amount staked influences their probability of being selected to propose or validate new blocks. Rewards: Validators earn rewards for their participation in the consensus process. These rewards are proportional to the amount of AVAX staked and their uptime and performance in validating transactions. Delegation: Validators can also accept delegations from other token holders. Delegators share in the rewards based on the amount they delegate, which incentivizes smaller holders to participate indirectly in securing the network. 2. Economic Incentives: Block Rewards: Validators receive block rewards for proposing and validating blocks. These rewards are distributed from the network’s inflationary issuance of AVAX tokens. Transaction Fees: Validators also earn a portion of the transaction fees paid by users. This includes fees for simple transactions, smart contract interactions, and the creation of new assets on the network. 3. Penalties: Slashing: Unlike some other PoS systems, Avalanche does not employ slashing (i.e., the confiscation of staked tokens) as a penalty for misbehavior. Instead, the network relies on the financial disincentive of lost future rewards for validators who are not consistently online or act maliciously. o Uptime Requirements: Validators must maintain a high level of uptime and correctly validate transactions to continue earning rewards. Poor performance or malicious actions result in missed rewards, providing a strong economic incentive to act honestly. Fees on the Avalanche Blockchain 1. Transaction Fees: Dynamic Fees: Transaction fees on Avalanche are dynamic, varying based on network demand and the complexity of the transactions. This ensures that fees remain fair and proportional to the network's usage. Fee Burning: A portion of the transaction fees is burned, permanently removing them from circulation. This deflationary mechanism helps to balance the inflation from block rewards and incentivizes token holders by potentially increasing the value of AVAX over time. 2. Smart Contract Fees: Execution Costs: Fees for deploying and interacting with smart contracts are determined by the computational resources required. These fees ensure that the network remains efficient and that resources are used responsibly. 3. Asset Creation Fees: New Asset Creation: There are fees associated with creating new assets (tokens) on the Avalanche network. These fees help to prevent spam and ensure that only serious projects use the network's resources.
Ethereum, particularly after transitioning to Ethereum 2.0 (Eth2), employs a Proof-of-Stake (PoS) consensus mechanism to secure its network. The incentives for validators and the fee structures play crucial roles in maintaining the security and efficiency of the blockchain. Incentive Mechanisms 1. Staking Rewards: Validator Rewards: Validators are essential to the PoS mechanism. They are responsible for proposing and validating new blocks. To participate, they must stake a minimum of 32 ETH. In return, they earn rewards for their contributions, which are paid out in ETH. These rewards are a combination of newly minted ETH and transaction fees from the blocks they validate. Reward Rate: The reward rate for validators is dynamic and depends on the total amount of ETH staked in the network. The more ETH staked, the lower the individual reward rate, and vice versa. This is designed to balance the network's security and the incentive to participate. 2. Transaction Fees: Base Fee: After the implementation of Ethereum Improvement Proposal (EIP) 1559, the transaction fee model changed to include a base fee that is burned (i.e., removed from circulation). This base fee adjusts dynamically based on network demand, aiming to stabilize transaction fees and reduce volatility. Priority Fee (Tip): Users can also include a priority fee (tip) to incentivize validators to include their transactions more quickly. This fee goes directly to the validators, providing them with an additional incentive to process transactions efficiently. 3. Penalties for Malicious Behavior: Slashing: Validators face penalties (slashing) if they engage in malicious behavior, such as double-signing or validating incorrect information. Slashing results in the loss of a portion of their staked ETH, discouraging bad actors and ensuring that validators act in the network's best interest. Inactivity Penalties: Validators also face penalties for prolonged inactivity. This ensures that validators remain active and engaged in maintaining the network's security and operation. Fees Applicable on the Ethereum Blockchain 1. Gas Fees: Calculation: Gas fees are calculated based on the computational complexity of transactions and smart contract executions. Each operation on the Ethereum Virtual Machine (EVM) has an associated gas cost. Dynamic Adjustment: The base fee introduced by EIP-1559 dynamically adjusts according to network congestion. When demand for block space is high, the base fee increases, and when demand is low, it decreases. 2. Smart Contract Fees: Deployment and Interaction: Deploying a smart contract on Ethereum involves paying gas fees proportional to the contract's complexity and size. Interacting with deployed smart contracts (e.g., executing functions, transferring tokens) also incurs gas fees. Optimizations: Developers are incentivized to optimize their smart contracts to minimize gas usage, making transactions more cost-effective for users. 3. Asset Transfer Fees: Token Transfers: Transferring ERC-20 or other token standards involves gas fees. These fees vary based on the token's contract implementation and the current network demand.
信息披露时间段的开始日期
2024-04-13
信息披露时间段的结束日期
2025-04-13
能源报告
能源消耗
337.29112 (kWh/a)
能源消耗来源与评估体系
The energy consumption of this asset is aggregated across multiple components:
To determine the energy consumption of a token, the energy consumption of the network(s) avalanche, ethereum is calculated first. Based on the crypto asset's gas consumption per network, the share of the total consumption of the respective network that is assigned to this asset is defined. When calculating the energy consumption, we used - if available - the Functionally Fungible Group Digital Token Identifier (FFG DTI) to determine all implementations of the asset of question in scope and we update the mappings regulary, based on data of the Digital Token Identifier Foundation.
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