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=Emergent enterprises in Decentralized Finance=
=Emergent Collaborations In Decentralized Finance=


Decentralized finance utilizes blockchain technology to provide financial services such as borrowing, lending, and trading without the need for traditional financial intermediaries like banks.
Decentralized finance (DeFi) leverages blockchain technology to offer financial services, such as borrowing, lending, and trading, without the need for traditional financial intermediaries like banks. However, entering the world of cryptocurrency still requires a point of contact with the traditional banking system, as you need to purchase Bitcoin or Ethereum using fiat currency.
Still, entering the world of cryptocurrency requires a point of contact with the traditional banking system, as you have to buy Bitcoin or Ethereum with fiat.


But technologies like Ethereum make it possible for many other applications to benefit from the blockchain technology, some of the most successful DeFi projects include MakerDAO which runs on the Ethereum blockchain. It allows users to generate DAI, a stablecoin pegged to the US dollar, by locking up other cryptocurrencies as collateral.
Platforms like Ethereum enable numerous applications to benefit from blockchain technology. Some of the most successful DeFi projects include MakerDAO, which operates on the Ethereum blockchain. It allows users to generate DAI, a stablecoin tied to the US dollar, by securing other cryptocurrencies as collateral.


Or Uniswap, A decentralized exchange (DEX) that allows for the automated trading of DeFi tokens without an order book. There are also various lending platforms like Aave and Compound where users can lend and borrow different cryptocurrencies.
Another example is Uniswap, a decentralized exchange (DEX) that facilitates the automated trading of DeFi tokens without requiring an order book. Additionally, there are various lending platforms, such as Aave and Compound, where users can lend and borrow different cryptocurrencies.


Many DeFi projects employ blockchain technology as an automated escrow system. Here, decentralization refers to the fact that the network nodes supporting the blockchain are independent and equal in relation to the network protocol, meaning no single node holds more importance than the others.


Many DeFi projects use blockchain technology as an automated escrow system. Decentralization here refers to the fact that the nodes of the network supporting the blockchain are independent, and equal in relation to the network protocol, in the sense that no particular node is more important than others.


This is the original meaning of decentralization when we read about it in Bitcoin's white paper. However, Ethereum's Decentralized Virtual Machine, and other blockchains of the same category open new possibilities that expand the meaning of Decentralization besides the validation of transactions.


Complex interactions emerge among independent and unrelated actors that need no central organization to function.
This concept of decentralization, as originally outlined in Bitcoin's white paper, is foundational. However, Ethereum's Decentralized Virtual Machine and similar blockchains introduce new possibilities that broaden the scope of decentralization beyond merely validating transactions. These platforms facilitate complex interactions among independent and unrelated actors who do not require a central organization to function.


To illustrate this point, let us consider Seasonal Tokens, a set of four tokens implementing the same economic principles embedded in Bitcoin's design, but running on the Ethereum network.


The four ERC20 Tokens are created and operated by four independent smart contracts.They do not talk to each other, and they are identical except for the name of the tokens: Spring, Summer, Autumn and Winter.
And for the dates in which the mining supply will be cut in half.


The smart contracts started operating on September 2021, nine months later the Spring mining supply was cut in half. Nine months later Summer's mining supply was halved. Nine months after that Autumns mining supply was halved, and nine months after that the Winter token mining supply was cut in half.


The halving of mining supply for each token will occur every 3 years. But their halving are staggered so that every 9 months one of the tokens mining supply will be halved.This is the only relation between these four smart contracts. They are totally independent.
To illustrate this point, consider Seasonal Tokens, a project that implements the economic principles found in Bitcoin’s design but operates on the Ethereum network. This project comprises four ERC20 tokens—Spring, Summer, Autumn, and Winter—each managed by its own independent smart contract. These contracts do not interact; their primary distinction lies in the names of the tokens and the timing of their mining supply halvings.


In spite of their name, a smart contract is more like a jukebox, it sits there doing nothing unless somebody puts a coin in the sloth an asks for a song.
The operation of these smart contracts began in September 2021. Nine months into the operation, the mining supply of the Spring token was halved. This process was sequentially repeated every nine months with the other tokens: Summer, Autumn, and Winter. Following this pattern, the mining supply for each token is scheduled to halve every three years. However, these halvings are staggered so that every nine months, one of the token's supplies is reduced. This staggered schedule is the sole connection between these four smart contracts; otherwise, they function independently.


The smart contract supports the functionality of the token and actively manages and executes all operations associated with it, which includes the token's issuance, transfer mechanics, and balance tracking.
Interestingly, when the price movements of the four tokens are observed on the same graph, a pattern of oscillation around each other emerges. This pattern is not explicitly programmed into the smart contracts. How, then, does this synchronized behavior occur?
But all these functions are executed only if a person (or another smart contract) asks for it and pays the gas fees associated with operating the function.


[[File:HistoricalRelPrice.png|800px |left]]


Despite their name, a smart contract is more akin to a jukebox—it remains inactive until someone inserts a coin and selects a song. The smart contract underpins the token's functionality, managing and executing all operations related to it, including issuance, transfer mechanics, and balance tracking. However, these functions are only executed when a person (or another smart contract) requests them and pays the associated gas fees.


An analogy might help illustrate how this complex behavior emerges from simple instructions encoded in smart contracts.






Consider the relationship between flowers and bees. Bees facilitate pollination by transferring pollen from one flower to another, but their primary motivation is not pollination; they are simply gathering food for the hive. This relationship demonstrates how different parties, acting in their own interests, can collectively fulfill a broader purpose.


Consi
Similarly, the four smart contracts attract various actors, none of whom are specifically aiming to create price oscillations. It is likely that most are primarily interested in making money. These actors might engage in different activities such as mining tokens, trading them, providing liquidity to decentralized markets, or capitalizing on price fluctuations and arbitrage opportunities. The random and uncoordinated actions of all these participants ultimately result in the observed price oscillations of the tokens.






Bitcoin's technological break trough was to successfully implement the blockchain as an automated escrow system where people can exchange digital assets without the need to trust a third party.  
This closed ecosystem of four cryptocurrencies offers additional advantages over single-token systems. In other proof of work cryptocurrencies, when the mining supply is halved, mining often becomes unprofitable overnight, forcing many miners to cease operations.


In the Seasonal Tokens system, miners can redirect their efforts to the other three tokens, which typically leads to an increased supply of these tokens. Traders, anticipating this shift, might invest in the token whose supply was just reduced. The resulting scarcity of that token tends to drive its price up relative to the others.


The problem with electronic transactions is that if two persons want to exchange digital assets they have to trust each other.
By adapting in this way, traders inadvertently support the mining economy, effectively subsidizing the production of the momentarily unprofitable token. This collaboration occurs spontaneously, with each participant acting in their own interest, yet collectively benefiting the system.
For example if Alice and Bob want to exchange documents, Alice may send the document to Bob,but Bob may decide not to send his document.
 
The only way to solve this problem is the use of an escrow system,
 
where both Alice and Bob trust a third party to keep the documents until both parties fulfill their obligation.
 
The escrow receives Alice's and Bob's documents, and delivers the documents only if the two documents were handed in.
This scenario illustrates how, beyond the decentralization seen in transaction verification on networks, other subtle forms of decentralization can emerge purely from economic principles, without any need for formal governance or central planning. Thus, the Seasonal Tokens model exemplifies a powerful synergy between technology and economic strategy, fostering a self-sustaining and adaptive financial ecosystem.

Latest revision as of 17:35, 26 September 2024

Emergent Collaborations In Decentralized Finance

Decentralized finance (DeFi) leverages blockchain technology to offer financial services, such as borrowing, lending, and trading, without the need for traditional financial intermediaries like banks. However, entering the world of cryptocurrency still requires a point of contact with the traditional banking system, as you need to purchase Bitcoin or Ethereum using fiat currency.

Platforms like Ethereum enable numerous applications to benefit from blockchain technology. Some of the most successful DeFi projects include MakerDAO, which operates on the Ethereum blockchain. It allows users to generate DAI, a stablecoin tied to the US dollar, by securing other cryptocurrencies as collateral.

Another example is Uniswap, a decentralized exchange (DEX) that facilitates the automated trading of DeFi tokens without requiring an order book. Additionally, there are various lending platforms, such as Aave and Compound, where users can lend and borrow different cryptocurrencies.

Many DeFi projects employ blockchain technology as an automated escrow system. Here, decentralization refers to the fact that the network nodes supporting the blockchain are independent and equal in relation to the network protocol, meaning no single node holds more importance than the others.


This concept of decentralization, as originally outlined in Bitcoin's white paper, is foundational. However, Ethereum's Decentralized Virtual Machine and similar blockchains introduce new possibilities that broaden the scope of decentralization beyond merely validating transactions. These platforms facilitate complex interactions among independent and unrelated actors who do not require a central organization to function.



To illustrate this point, consider Seasonal Tokens, a project that implements the economic principles found in Bitcoin’s design but operates on the Ethereum network. This project comprises four ERC20 tokens—Spring, Summer, Autumn, and Winter—each managed by its own independent smart contract. These contracts do not interact; their primary distinction lies in the names of the tokens and the timing of their mining supply halvings.

The operation of these smart contracts began in September 2021. Nine months into the operation, the mining supply of the Spring token was halved. This process was sequentially repeated every nine months with the other tokens: Summer, Autumn, and Winter. Following this pattern, the mining supply for each token is scheduled to halve every three years. However, these halvings are staggered so that every nine months, one of the token's supplies is reduced. This staggered schedule is the sole connection between these four smart contracts; otherwise, they function independently.

Interestingly, when the price movements of the four tokens are observed on the same graph, a pattern of oscillation around each other emerges. This pattern is not explicitly programmed into the smart contracts. How, then, does this synchronized behavior occur?

HistoricalRelPrice.png

Despite their name, a smart contract is more akin to a jukebox—it remains inactive until someone inserts a coin and selects a song. The smart contract underpins the token's functionality, managing and executing all operations related to it, including issuance, transfer mechanics, and balance tracking. However, these functions are only executed when a person (or another smart contract) requests them and pays the associated gas fees.

An analogy might help illustrate how this complex behavior emerges from simple instructions encoded in smart contracts.


Consider the relationship between flowers and bees. Bees facilitate pollination by transferring pollen from one flower to another, but their primary motivation is not pollination; they are simply gathering food for the hive. This relationship demonstrates how different parties, acting in their own interests, can collectively fulfill a broader purpose.

Similarly, the four smart contracts attract various actors, none of whom are specifically aiming to create price oscillations. It is likely that most are primarily interested in making money. These actors might engage in different activities such as mining tokens, trading them, providing liquidity to decentralized markets, or capitalizing on price fluctuations and arbitrage opportunities. The random and uncoordinated actions of all these participants ultimately result in the observed price oscillations of the tokens.


This closed ecosystem of four cryptocurrencies offers additional advantages over single-token systems. In other proof of work cryptocurrencies, when the mining supply is halved, mining often becomes unprofitable overnight, forcing many miners to cease operations.

In the Seasonal Tokens system, miners can redirect their efforts to the other three tokens, which typically leads to an increased supply of these tokens. Traders, anticipating this shift, might invest in the token whose supply was just reduced. The resulting scarcity of that token tends to drive its price up relative to the others.

By adapting in this way, traders inadvertently support the mining economy, effectively subsidizing the production of the momentarily unprofitable token. This collaboration occurs spontaneously, with each participant acting in their own interest, yet collectively benefiting the system.


This scenario illustrates how, beyond the decentralization seen in transaction verification on networks, other subtle forms of decentralization can emerge purely from economic principles, without any need for formal governance or central planning. Thus, the Seasonal Tokens model exemplifies a powerful synergy between technology and economic strategy, fostering a self-sustaining and adaptive financial ecosystem.