Optim Finance
  • INTRODUCTION
    • Introduction
    • Roadmap
  • OADA
    • Overview
    • OADA 🟣 and sOADA 🟒
    • Flow of Funds
    • User Guides
      • Passive yield with sOADA
      • Epoch Stake Auction
    • AMOs
      • Splash DEX AMO
      • Stake Auction AMO
      • Staking AMO
    • UNHCR Donation Module
      • Automated Yield Donation Protocol
      • NFT Impact Certificate
      • Integration with the OADA Ecosystem
      • Humanitarian Partnership
      • Future Extensions
    • Governance
    • Resources
  • OTOKEN Framework
    • Introduction
      • Key Benefits
      • Who is it for?
      • Inspirations & Applications
    • Framework
      • Key Concepts
      • Use Cases
      • OTOKENs
    • Core Concepts
      • OTOKEN and sOTOKEN
      • Algorithmic Market Operations (AMOs)
      • Balancing Stability, Yield, and Adaptability
    • System Architecture
      • OTOKEN Policy
      • Staking AMO
      • Collateral Management AMO
    • Extensions & Other Modules
      • DEX AMO (Liquidity & Peg Stability)
      • Stake Auction AMO
      • Borrowing & Lending AMOs
      • Other AMOs & Opportunities
    • Multiple OTOKEN Deployments
      • Ecosystem Synergy
      • Not Just Synthetic Assets
    • Vision
      • Key Pillars of the OToken Framework
      • Future Directions & Opportunities
      • An Invitation to Innovate
    • Bug Bounty Program
  • LIQUIDITY BONDS
    • Overview
    • Bond App FAQ
    • Use Cases
      • ISPO Bonds
      • SPO Bonds
    • Bond Architecture
      • Validators
      • High Level Workflow
      • Scripts Technical
      • Transaction Flow
      • Pooled Loans
    • Guides for SPOs
      • Bond Creation
      • Bond Sales
      • SPO Bond Issue Summary
      • Bond Verification
    • Liquidity Bonds Audit
  • OUSD
    • OUSD Reserves
      • Reserve Criteria
        • Stability and Reputation
        • Compliance
        • Smart Contract Security
    • Ongoing Reserves Management
      • Reserve Asset Valuation Calculation
      • Dynamic Reserve Asset Adjustment Metrics
        • Dynamic Reserves Adjustment
    • Yield, Staking, and Flow of Funds
      • Yield Modules
        • OUSD DEX AMO
        • Future Modules (v2)
      • Staking AMO
      • sOUSD Redemption Mechanism
    • Peg Protection
      • Market Depth and Liquidity
    • Governance and Risk Framework
      • Risk Capital Requirements
      • First-Loss Capital Structure
      • Asset Allocation Framework
        • Static Governance Parameters
        • Dynamic Allocation System
    • Financial Engineering Audit
  • Leviathan
    • System Architecture
      • Background
      • Concurrency Limitations
      • Complexity in Transaction and Contract Management
    • Core Concepts
      • Deterministic Transaction
        • Guaranteed Transaction
      • Instant Finality
        • Liveness and Safety
        • Probabilistic Finality vs Instant Finality
      • Account Abstraction
        • Concept of Account Abstraction
        • Technical Implementation
        • Security and Operational Implications
      • Intent Based Transactions
        • The Infrastructure and Process of IBTs
        • Declarative Constraints in IBTs
      • Layer 2
        • Types of Layer 2 Solutions
      • Sequencers
        • Core Functions of Sequencers
        • Role in Layer 2 Rollups
        • Challenges
    • System Components
      • Understanding the System Components
      • Optim-Account (Intents to enable tx chain)
        • User Interaction and Intent Submission
        • Intent Structuring and Authentication
        • Smart Contract Functionalities and Operational Parameters
        • The Necessity of an Account-Based Framework
        • Account Abstraction and Its Role in Leviathan
      • Leviathan Sequencer System (tx chain building)
        • The Role of the Leviathan Sequencer System in Conjunction with The Optim Account
        • Sequencing and Ordering of Transactions
        • The Role of Time in the System
        • The Pragmatic Leviathan: Dealing with Potential Changes
      • The Role of OADA in the Leviathan System
        • Operational Simplification of Staking Mechanisms via OADA Integration
        • Facilitating Time Dilation and Composability
    • Processes
      • Entering Leviathan
      • Transaction Execution
      • Leaving Leviathan
    • High Level Overview
      • System Design
        • Account Abstraction Functionality
        • Guaranteed Transactions
        • Instant Finality
        • Unbreakable Transaction Chaining
        • Layer 2 Execution Environment
        • Future Sequencer Network
      • System Context
        • Limitations of current transactions chaining paradigm
        • Limitations of current inter dApp composability issues
        • Explanation of basic design and non-custodial asset inputs
        • Intent Based Transactions
        • Account Base vs eUTxO model app architecture
      • Theoretical Applications
  • GOVERNANCE
    • Governance Overview
      • Proposal Temp Check
      • Governance Proposal
        • On/Off Chain Mechanics
      • ODAO
    • Tokenomics
      • Categories
      • Vesting
    • Optim DAO Wallets
    • Protocol Profits
  • GUIDES
    • Transaction Chaining
      • Background
      • Overview
      • Pool Transaction Chaining
    • OPTIMiz Conversion
  • ODAO Stack
    • Introduction
    • Design Principles
    • Why Optim DAO Stack?
      • Current Limitations
      • ODAO Solutions
    • Key Features
      • Snapshot Voting
      • Treasury Management
      • Proposal Execution
    • System Architecture
      • Modular Framework
      • On-Chain Logic
      • Off-Chain Operations
      • User Interfaces
    • Core Modules
      • Snapshot Voting Module
      • Treasury Management Module
      • Proposal Execution Module
    • Future Roadmap
      • Potential Future Enhancements
      • Long Term Vision
  • OADA UI
    • Setup
      • Installation
      • Development Workflow
      • Troubleshooting
      • Development Tips
      • Open Source Contributions
      • FAQ
    • Key Functionalities
      • Wallet Integration
      • Dashboard
      • Transaction Management
        • UTxO Management
        • Transaction Creation and Conversion
        • Transaction Monitoring
      • Real-time Updates
        • Portfolio Value Tracking
        • Transaction Status Monitoring
    • OADA Smart Contract API
      • Minting OADA
      • Staking OADA
      • Unstaking sOADA
      • Epoch Stake Auction
        • Bid Calculation Functions
        • Auction Actions
        • Bid Form Component
        • Auction Dashboard
    • Tutorials
      • Environment Setup and Installation
      • Understanding the Project Structure
      • Basic Configuration and Customization
      • Working with Components
      • State Management and Data Flow
      • Wallet Integration and State Management
      • Smart Contract Integration
      • Advanced UI Customization
      • Testing and Quality Assurance
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On this page
  • What are ISPO Bonds?
  • How do ISPO Bonds work?
  1. LIQUIDITY BONDS
  2. Use Cases

ISPO Bonds

PreviousUse CasesNextSPO Bonds

Last updated 1 year ago

What are ISPO Bonds?

ISPO (Initial Stake Pool Offering) Bonds are a tool that enables anyone to increase their participation in an ISPO by borrowing ADA delegation power to do so. Just like all Liquidity Bonds, they allow anyone to borrow or β€˜rent’ ADA staking rights and associated staking rewards for a fixed period of time. The staking rights to ADA are staked to an ISPO pool with the borrower receiving associated governance tokens from a project for their participation.

How do ISPO Bonds work?

Borrowers: Those who wish to borrow ADA staking rights Borrowers issue 'bonds' by offering specific terms to lenders who are willing to lock their ADA in a smart contract and allow borrowers to attach their own stake key to the locked ADA. Borrowers set the terms - such as interest rate, duration, and amount of ADA - then deposit the required prepaid interest for the amount they're requesting to borrow. Each bond issued by a borrower is for 100 ADA and is essentially a preset loan agreement. Borrowers typically choose amounts from 50K-250K ADA, equaling 5000-25000 Bonds. Lenders can buy bonds by depositing ADA into a smart contract in 100 ADA increments. There is also a minimum interest buffer, which is the minimum amount of interest that must be kept in the bond at all times. If the interest buffer is not maintained, the ADA in the smart contract is no longer locked and the lender can redeem it, at which point the borrower loses the ability to attach their stake key.

Lenders: Those who wish to lend ADA staking rights by locking their ADA into a smart contract. Lenders buy bonds, which are 100 ADA each, and lock their ADA into a smart contract under the terms defined by the borrower who issues the bonds. Each bond is redeemable for 100 ADA plus interest at the end of the bonds maximum duration or when the bond closes due to a borrower failing to pay the required interest. In both cases the lender's ADA is unlocked and can be redeemed for the 100 ADA underlying plus interest. Resources Some great articles and videos by partners and members of the community for further explanation πŸ‘‡ - -

https://medium.com/@FluidTokens/a-step-by-step-guide-to-borrowing-while-increasing-your-position-on-fldt-ispo-through-optim-finance-9efbc57b05d4
https://medium.com/@meteraprotocol/join-meteras-ispo-leveraging-optim-bonds-2300cceb4cd1