The ICB Network is a reliable and secure network that uses POS consensus for efficient operation. Furthermore, the ecosystem of ICB will provide effective governance and democracy, ensuring that all stakeholders, including the project team, general delegators, and investors, can benefit from the success of the project.

ICB Network Advantages

• Faster transaction speeds: Proof of Stake & authority (PoS-A) removes the requirement for miners to solve intricate puzzles, resulting in quicker transaction speeds and increased capacity. Real-time transactions are important for applications that need to process transactions quickly.

• Lower energy consumption: PoS is a much more energy-efficient alternative to PoW, which makes it a better choice for projects that prioritize sustainability and the environment.

• Improved governance: PoS enables a system of direct democracy, where individuals who hold tokens can vote for delegates responsible for managing the network. This approach has the potential to facilitate quicker decision-making and encourage active participation from the community.

PoW Disadvantages:

• Slow transaction speeds: Proof of Work (PoW) can sometimes be slow, resulting in transaction times that can take several minutes or even hours. Real-time transactions can be significantly impacted by this, which can be a major disadvantage for certain applications.

• High energy consumption: Proof of Work (PoW) involves solving intricate mathematical puzzles, which consumes a substantial amount of energy. This has led to concerns about the potential environmental consequences.

• Hardware centralization: Large mining pools have a tendency to centralize mining operations, which can potentially affect the decentralization of the network.

We have implemented the theory of the Tokonomics circuit by examining seven parameters in our review:

• Amount of tokens or cash (q)

• Intensity of cash flow (i)

• Value potential difference (v)

• Token burning resistance (r)

• Source of real return (y)

• Token capacitance elements (c)

• Elements of staking token(s)

1. Presence of Cash and Tokens: In this project, cash and tokens act like an electric current in a circuit. The project is investor-friendly, with business partners including consortiums and collaborations, alongside public sales, from ICO to buying and selling exchanges.

2. Cash Flow Intensity: This parameter refers to the number of tokens that enter or exit the project within a certain time period. In other words, it measures the number of tokens involved in transactions. The cash flow intensity can be calculated using the following formula:

   i=q/t where ( i ) represents the liquidity flow intensity, ( q ) is the token amount, and ( t ) is time.

3. Difference in Valuation: ICB provides a precise definition of the value of project assets, similar to the voltage in electrical circuits, which drives cash flow. A lack of coordination in information can lead to misaligned valuations and redirect cash flows from high-value assets to low-value assets. People attracted to high-value assets due to FOMO illustrate this shift. The resulting bubble acts as an effective factor in displacing cash flow and is visible as selling pressure.

4. Resistance to Token Burn: Every transaction requires a gas fee for validators. Token burn resistance is used to personalize spending and devise ways to use the token, preventing it from being lost to manage inflation. Despite being designed for various purposes, this factor can be problematic because users can only know the amount of resistance in cash flow with the QR symbol. This symbol shows the number of tokens burned at a specific time, which is crucial for liquidity analysis. Resistance to token burning is a fundamental factor in inflation control mechanisms and generally benefits both the protocol and users.

   Cash flow intensity=value/resistance Therefore, a difference in value implies an inverse relationship between liquidity flow intensity and token burning resistance. When users seek real value from a protocol's product, higher demand arises. This increased resistance compared to costs and fees leads to a decrease in cash flow.

   Given that: cash flow intensity = amount / time

   So: token burn resistance = value x time / amount

5. Real Source of Income: The term "real source of profit" here refers to the utilization of various business models, including funding for delivery, to achieve a Minimum Viable Product (MVP) or Product-Market Fit (PMF). Digital assets also play a crucial role in generating significant returns or rewards. All types of Decentralized Autonomous Projects (DAPs) presented and the circulating funds derive from the project's staking platform. In the tokonomics system, this forms the battery or power supply circuit composed of a combination of resistance, capacitance elements, and token aggregation elements. This power supply is referred to as "financial impedance" denoted by the symbol "z". It is a linear structure analogous to Ohm's law in electrical circuits. Essentially, in a tokonomics system, this power supply functions similarly to a battery or power source, responsible for fulfilling financial needs within the circuit.

6. Capacitive Capacity Elements of Tokens: In the tokonomics circuit, capacitive capacity elements act akin to capacitors in electrical circuits. These include wallets and aggregators that hold tokens for a specific project across decentralized and centralized exchanges. The function of these capacitors in the tokonomics circuit is to indicate the level of user participation in the platform and aid in analyzing the dispersion of cash flow. During economic shocks, the amount of token deposits and withdrawals determines the likelihood of a death spiral or a flywheel effect. Moreover, by utilizing both deposit and withdrawal elements, market sentiment can be gauged.

   i=C*dv/dt

   Liquidity = Capacitive elements * value change rate

   Essentially, changes in token value prompt users to deposit or withdraw, resulting in immediate cash inflow or outflow.

7. Staking Elements: In the tokonomics circuit, token staking elements function similar to inductors in an electric circuit. Under normal conditions, they may not be essential, but their presence can strengthen the system during unstable cash flows. In essence, the existence of a reward mechanism based on real performance ensures balance in cash flow.

   v= S*di/dt

   Value = Staking elements * cash flow rate of change

   In the formula above, token value is determined by multiplying staking elements by the cash flow change rate. During fluctuations in cash flow due to user buying and selling decisions, the project team can manage asset value by controlling their monetary policies.

   In the tokonomics circuit, there are non-linear financial elements such as airdrops and prize pools. These elements contribute to maintaining the financial stability of the project token. Therefore, when designing the real return model, attention should be paid to factors such as the type of token model, the structure of monetary policy, and mechanisms for inflation and deflation.

Total supply : 100B Public Sale (Initial Distribution):

●35% (35B tokens) This portion can be distributed over several phases or rounds to ensure a fair and decentralized launch.

● Team : 10% (10B tokens)

●Advisors: 5% (5B tokens)

● Ecosystem Development Fund: 30% (30B tokens)

● Reserve Fund: 5% (5B tokens)

● Staking Rewards: 12% (12B tokens)

● Community Grants and Airdrops: 3% (3B tokens)

Initial Coin Offering of ICB Network

Our Initial Coin Offering (ICO), which will be conducted in four distinct phases. This phased approach is designed to provide clarity, ensure efficiency, and maximize participation opportunities for our investors.

Private Sale (4B ICB Tokens)

We are excited to present an exclusive private sale opportunity to our esteemed initial seed investors. This offering is tailored to acknowledge your early support and trust in our venture. Our goal is to provide you with the most advantageous packages, reflecting our appreciation for your foundational role in our journey.

• Package A : Pricing 1000$ give investor 0.0002$ per token with vesting period of 6 month lock & 6 months

• Package B : Pricing 5000$ give investor 0.00018$ per token with vesting period of 6 month lock & 3 months

• Package C : Pricing 10,000$ give investor 0.00015$ per token with vesting period of 3 month lock & 3 months

• Package D : Pricing 30,000$ give investor 0.0001$ per token with vesting period of 1 month lock & 3 months

Pre-Sale 1 (6B ICB Tokens)

1. Initial Starting Price

• Attractive Entry Point: The sale kicks off with an enticing starting price of $0.0002 per token, making it an ideal investment opportunity.

2. Daily Price Increment

• Dynamic Pricing: Each day, the token price will increase by $0.00001. This increment rewards early investors and maintains a fair and dynamic investment environment for all participants.

3. Token Lock-in and Vesting

• Lock-in Duration: To foster stability and long-term commitment, all purchased tokens will be locked for a 6-month period.

• Vesting Schedule: Following the lock-in phase, tokens will be released in a linear vesting process over 12 months. This ensures a gradual and controlled distribution into the market.

Pre-Sale 2 (10B ICB Tokens)

1. Initial Starting Price

• Attractive Entry Point: The sale kicks off with an enticing starting price of $0.0003 per token, making it an ideal investment opportunity.

2. Daily Price Increment

• Dynamic Pricing: Each day, the token price will increase by $0.00001. This increment rewards early investors and maintains a fair and dynamic investment environment for all participants.

3. Token Lock-in and Vesting

• Lock-in Duration: To foster stability and long-term commitment, all purchased tokens will be locked for a 6-month period.

• Vesting Schedule: Following the lock-in phase, tokens will be released in a linear vesting process over 12 months. This ensures a gradual and controlled distribution into the market.

Public Sale (15B ICB Token)

1. Dynamic Pricing

• Starting at $0.0005: The sale opens with an inviting price of $0.0005 per token. The sooner you invest, the more beneficial the pricing – ensuring early investors gain the most.

2. Reward Opportunities

• Active Participation Rewards: Your engagement and investment level directly influence the rewards you receive, offering you more for your involvement.

3. Referral Program

• Bonus for Referrals: Expand our community by inviting friends. For every new participant who joins through your referral, you receive additional bonuses, enhancing your investment benefits.

ICB Network is a cutting-edge blockchain that is both fast and safe, built on top of one of the most cutting-edge security features currently available.

It is provided for cooperation with other networks. These cooperations include financial and functional exchanges in the fields of smart contracts and development tools for developers. Within its ecosystem, there is a particular focus on the fields of gaming and the Metaverse:

1. Virtual Goods: The greatest value that ACB brings to the gaming community, from Dololoop information to NFTs and tradable assets, is the creation and management of virtual goods. Developers on any operating system can easily create a unique currency for their community, supported by the idea of blockchain cooperation as the main currency. This endows the coins with all the benefits of blockchain technology. Since each asset is registered in a registry smart contract, all ICBX smart wallets recognize them, allowing users to exchange virtual goods with ICBX at any time.

2. Payment Gateway: Additionally, the ICB SDK includes a decentralized payment gateway. This portal allows the creation of invoices, refunds, and more. It also provides a widget (liquidity) for accepting ICBX payments or custom coins on your website for current amounts. The payment gateway charges only a small fee for each transaction and does not impose any additional fees. Leveraging the capabilities of EVM smart wallets, users can make automatic payments to games and websites listed as trusted platforms. This feature enables the setting of coins with fiat money support, ensuring faster and more reliable payments for regular subscription services.

3. Smart Wallet: The smart wallet integrated into the ICB network is a crucial component that connects all elements. The wallet supports virtual goods across any of your trusted operating systems and synchronizes with your Ethereum address.

Introduction to ICB Network

A Pioneering Force in Blockchain Technology

As a fundamental and innovative project, the ICB network is at the forefront of blockchain developments. The network utilizes the Proof-of-Stake (PoS) consensus mechanism as its central core, which establishes EVM standards and introduces new standards in platform management for efficiency, security, and scalability across various industries.

PoS Consensus: The Backbone of Scalability and Efficiency

• The ICB network has transitioned from current proof-of-work (PoW) systems and standard-compliant PoS to a new generation within the PoS family. In this new system, token holders can choose representatives to verify transactions, which are then approved through the proof of validity method and the Byzantine Fault Tolerance algorithm. This approach brings several advantages:

• Increased Transaction Bandwidth: Using PoS, transaction verification is faster, and data flow is increased, making it ideal for high-volume applications.

• Ease of Transactions: This algorithm allows transactions to occur without multiple confirmations. If nodes agree on a block of transactions, the network transaction is confirmed immediately. This algorithm guarantees the finality of transactions without the need for confirmations such as proof of work or additional shares.

• Low Energy Consumption: Unlike consensus algorithms based on work and some older proof-of-stake systems, the ICBX algorithm does not require high computing power or energy consumption, making it environmentally friendly.

• Balanced Rewards: Decision-making in this algorithm is collective. Each node in ICB reduces and balances the rewards of validators according to their motivations.

• Enhancing network security: The agent-based model ensures that network operations are overseen by agents elected by token holders, which helps to enhance intelligent decision-making and increase overall network security.

The Impact of ICB Network's Innovation

A Future-Ready Blockchain Solution

The ICB Network is not just a technological advancement; it's a vision for the future of blockchain. By prioritizing speed, energy efficiency, and robust security measures, the network is uniquely positioned to transform multiple sectors. It’s an embodiment of our commitment to pushing the boundaries of what blockchain can achieve, making it more accessible, sustainable, and secure for everyone.

With POS consensus, a specialized Layer-1 design, and a focus on scalability, security, and speed, the ICB Network is ready to change how we communicate, do business, and handle data. The ICB Network will shape the future of Layer-1 blockchains as it continues to grow and change, promoting growth and innovation in many fields.

The ICB network, with its continued growth and evolution, has shaped the future of layer-1 blockchains and promotes innovation and development in many areas. The five main layers that this network uses are:

1. Hardware Layer: This foundational layer stores blockchain information in personal nodes or servers. The client-server structure is used to access information needed for web browsing or using blockchain applications. This layer employs peer-to-peer networks to share information, and data is stored in decentralized databases, creating a wide network of diverse devices.

2. Data Layer: The second layer contains the data and information available in the network. The blockchain data structure consists of a set of interconnected blocks, each containing time-ordered transactions. This structure uses pointers and a linked list to form a chain of blocks. Additionally, a Merkle tree is an important structure used for data security and integrity.

3. Network Layer: Also known as the P2P layer or publishing layer, this layer establishes communication between the various components of the blockchain. It manages the release of blocks, transactions, and communication. A peer-to-peer (P2P) network consists of distributed nodes that connect and share the network workload to achieve a common goal. This layer ensures that nodes can communicate, share, and synchronize information to maintain integrity across the blockchain network. Nodes are responsible for processing transactions in the blockchain.

4. Consensus Layer: This core layer is where the consensus algorithm is implemented and agreement between nodes is achieved. Consensus is reached in a decentralized manner, eliminating the need for centralization. This layer embodies the core of decentralization in a blockchain, with transactions processed by numerous nodes, all of which must agree on their validity. No single node can control transaction information, and if this layer fails, the entire blockchain system will collapse.

5. Application Layer: As the highest-level layer, this layer provides applications designed using blockchain. It functions similarly to the user interface and front-end part of an application. Developers can design their applications in this layer to be run by the blockchain. This layer includes scripts, APIs, frameworks, smart contracts, and decentralized applications.

Platform organization management

A decentralized autonomous organization (DAO) is an effective mechanism to eliminate intermediaries and interventions in blockchain-related technologies and applications. It even allows for restricting the interventions of the development group and founders of a blockchain project. Therefore, DAO-managed projects have high credibility among users and may substantially grow in a short time.

DAO attributes of ICB for all domestic products

DAOs provide superb advantages to users. However, a DAT not only is useful for users but also helps blockchain project developers and establishers enjoy remarkable advantages. It enables developers to manage their decentralized platforms without encountering many of challenges and offers an excellent experience to users. A number of DAO advantages are described below.

DAO security

As mentioned, DAOs are built in blockchain networks. Today, certain standards are used to build a DAO. Security in ICB is consistent with these standards and follows an acceptable structure. DAOs are smart contracts that are implemented by programming languages. As all the codes in smart contracts are open-source codes, all project users and stakeholders can evaluate the codes in detail before investing to ensure the security of the project. This provides DAOs with superb security and reliability.

Elimination of the hierarchical structure

DAOs are built using blockchain technology. They have enabled decentralized applications to conveniently eliminate the hierarchical structure for the first time. In a DAO, all users can vote and equally contribute to the changes in platforms. In other systems, some specific users and the development team can dictate their desired changes without the consensus of users.

A DAO enables all users to ensure that no member would enjoy particular advantages in the management of platforms. This, in turn, improves the confidence of users.

Cutting management costs

DAOs are the only organizations that can be managed at minimum expenses. ICB crypto services of decentralized platforms have dramatically decreased management expenses by implementing DAOs. A DAO provides all the users and stakeholders with the authority to manage platforms and applications. Therefore, DAO builders would not need to assign capital to project management, and the project would be automatically managed by users.

Collective wisdom

DAOs provide a better future for platforms in many cases. They enjoy collective wisdom. Therefore, many experts believe that the inclusion of numerous users in voting leads to better decision-making in different circumstances.

DAO ICBX structure

Founded and proposed by: Mike Verdish

Corechain

It is comprised of two layers: the base layer (theorists and advisors) and the technical and security layer (programmers and the project team).

The base layer is comprised of theorists and advisors and develops the general framework of the organization and project evaluation, whereas the technical and security layer has programmers and project teams that develop codes and fulfill technical and security tasks. The two layers cooperate to ensure project success and sustainability.

Layer 1: Base layer – theorization and advisory

Theorists

Analysis of technical theories: the theorists in the technical committee are responsible for analyzing the technical theories of the project. They evaluate the ideas and concepts that are provided in the project and make sure that these theories have technical relevance.

The theorists are required to evaluate the organization and propose solutions to the project execution team for system improvement. This helps enhance the technical principles and credibility of the project.

Advisors

Communication with the execution team: advisors act as a bridge to the execution team. They are responsible for providing technical advice concerning technology and project execution.

Handling technical challenges: Technical advisors handle technical challenges and share their experience in project improvement.

Interaction with other departments: This group of the technical committee is coordinated with other departments, such as marketing, legal, and financial. This is necessary to ensure unity and consistency between different components of the project.

Layer 2: Technical and security layer – programmers and project executors

Programmers

Development and implementation of codes: Programmers are responsible for developing and implementing project codes. They specialize in the required programming languages and technologies and try to generate a readable, sustainable, and secure code.

Testing and bug handling: Programmers should perform various tests and find and handle possible bugs or errors. This is necessary to ensure the quality and probity of projects.

Project execution

Resource and time management: the security layer is responsible for the management of resources and time for project development and execution. These executives coordinate the programming team and the optimal use of project resources.

Project security: This group is responsible for implementing security measures to protect the key data of the project. This includes data encryption and security standards.

Fichain

The first loop divides the earth into six parts in terms of population and circulating wealth to prevent a 51% attack and develop the system in a pervasive table based on the token economy. These six parts are co-founder companies, which are also known as creditors to masternodes based on the investment size and risk-taking.

Selection of creditors to build blocks: Creditors are selected to build a new block. They are often selected based on criteria such as the number of tokens staked in the network and using authentication technology.

Building a candidate block: Once creditors have been selected, the masternode selected to build a block collects validated transactions to generate a candidate block. This candidate block involves all transactions that have been set to the network at a certain time.

Incorporation of the transactions into the block: The creditor-generated candidate block (Fichain) involves transactions that have been received and successfully validated. These transactions are placed in a compressed format within the block. This is the characteristic of the first layer.

Super representatives

Super representatives (SRs) register information and serve as the Fullnode. Scaling and slashing are major responsibilities of SRs for the development of the second layer.

What is slashing?

The economic cycle of active blockchains in the proof-of-stake (PoS) system has two pathways. These blockchains mostly have an incentive mechanism for honest activity and a penalization mechanism for malicious activities.

As mentioned, the masternodes stake a certain amount of assets within the network. This resembles a bail-in. This staked amount is frozen in the network for a specific period. The penalty imposed on inactivity, dishonest validation, or other malicious behavior in PoS blockchains is known as the slashing penalty. It can be triggered in various ways, such as the loss of a constant portion of staked cryptocurrencies, a certain portion of the encrypted cryptocurrencies, closing the masternode’s account, and a temporary or permanent ban.

What is the goal of slashing?

Slashing is the penalization of a masternode’s misbehavior. This, in turn, enhances security, availability of validators, and honest participation in the network. The slashing penalty is imposed for two reasons:

1. To make possible attacks on the network economically unreasonable

2. To motivate validators to show responsible and proper behavior

The two major cases where validators are slashed include:

1. Downtime validators (offline/unavailable to sign transactions)

2. Double signing (validation of two or more blocks for the same chain)

What is downtime?

Downtime refers to the unavailability of masternodes to sign transactions. This often takes place in two cases:

1. When a validator loses connection to the chain for infrastructural reasons (such as internet issues)

2. When a validator cannot synchronize their validation with the network for technical reasons.

It should be noted that blockchains with slashing penalties do not impose the downtime slashing penalty immediately after a validator stops working. There is often a threshold to slash validators.

What is double signing?

Double signing occurs when a validator submits two signed messages for the same block. It mostly happens when a validator uses another masternode as a backup to avoid downtime. Double signing typically is a result of infrastructural issues and interference.

Many participants of this process utilize backup nodes to avoid such issues so that they can perform effective validation round-the-clock and avoid getting slashed. Double singing is a threat to the security of a network, and slashing is used to cope with this threat.

Masternodes

Masternodes use their systems to monitor the verification of transactions and reporting to SRs. They are practically the future SRs of the second layer. The second layer is generated for acceleration or scaling.

The network relies on its validators, where individuals holding a stake of 300 million ICBX tokens can become nodes. For each block creation in the ICB network, between 4 and 64 committees are selected, each consisting of 128 validator nodes chosen randomly from all network nodes. This random selection significantly reduces the possibility of network control.

ICB manages this sharded network by coordinating shard activities. The network also oversees node rewards and penalizes incorrect actions. When a user initiates a transaction on the network, it is assigned to a shard layer. ICB randomly or algorithmically selects a node within that shard to process the transaction and include it in the shard's block.

Sharding effectively mitigates the risk of a 51% attack. Other nodes within the same shard validate the block's authenticity. A minimum of 128 validator nodes, forming committees, must confirm each shard block's authenticity. These committees are responsible for producing a new block for their shard within a specific time slot. This time slot is termed an "epoch," comprising 32 slots. Only one valid block is introduced per slot. After each epoch, all committee members are replaced with new elections for the subsequent epoch. This rotation prevents any single entity from gaining control over all shards.

Overall, these mechanisms ensure the security and decentralization of the ICB network, safeguarding against centralized control and enhancing its resilience to potential attacks.

Supervisors

Supervisors are responsible for calculating profits and controlling nominators. They report vote verifications to the masternodes and perform the final verification.

Block distribution: Blocks are distributed to the other nodes upon the approval and signing of validators. These blocks contain new transactions and block generation information, and this is performed by supervisors.

Block verification: The other nodes of the network receive and validate the block. When the generated block is verified and validated by most of the nodes, it is added to the blockchain, and transactions become allowed within the block.

Block reward distribution: Validator nodes are rewarded ICB tokens for their major role in validating the block, and transaction costs are distributed by the users as rewards. These rewards are an incentive for validators to participate in the generation and validation of blocks and ensure the security and optimal functioning of the network.

Who are nominators?

The ICBX blockchain community is all nominators. Nominators can vote and their duty is to expand the system. In other words, they do referral marketing and ambassador marketing.

Nominators participate in decision-making in the organization. Nominators make the final decision from the second layer to the fork.


Voting in the ICBX Blockchain

To modify protocols and make pertinent choices, all voting criteria and requirements must be met in the ICBX blockchain. These measures are put in place to ensure that the decision-making process is fair, democratic, and open to all. The following are examples of ICBX blockchain voting criteria and conditions:

• Voting Criteria: An essential prerequisite for voting on the ICBX blockchain is the establishment of voting criteria. Precisely calculating the proportion of votes in support of a protocol amendment requires the consideration of a criteria. Obtaining 66% of the vote in favor might be one criterion for making a decision.

• Voting Conditions: Accurate determination of the prerequisites for voting is essential. These requirements could be conditional on the network members' levels of involvement or the quantity of tokens held by token holders. For instance, in order to vote, token holders could need 100 tokens or more. In addition, the circumstances surrounding each voting procedure are unique.

• Voting System: The ICBX blockchain uses a unique voting mechanism in which the majority of tokens cast determine the outcome. Each token is like a vote in this system. That is to say, the number of tokens that participate in the vote determines the outcome, and each token has one vote.

• Voting Duration: The length of time for voting is clearly defined. This time frame may be anything from a week to a month or more. During this time, everyone in the network has an equal opportunity to cast a vote and have their say on major decisions.

• Decision-Making Based on Polls: Polls provide the basis of the decision-making process. In this scenario, the tokens' majority vote determines the outcome. Changing the procedure will be the final decision if 66% of the votes are collected, to be correct.

ICB Token Staking: Understanding the Different Delegator Categories

Welcome to our comprehensive guide on ICB Token Staking. In this section, we'll explore the different types of delegators in our ecosystem: Non-KYC Delegator, KYC Delegator, and Slot Delegator. Each category has unique features and rewards structures, designed to cater to various user preferences and requirements.

Non-KYC Delegator

• Stake: Native ICB Tokens.

• Reward Token: Receives GICB Tokens (Governance Token).

• Rewards: No project-specific rewards.

• Limit: No cap on the number of delegators.

• Fees Share: 10% of the fees.

• Reward Calculation: For example, if Validator1 mines X blocks and collects fees, 10% of these fees are distributed among the connected delegators.

• Staking Reward Percentage: Adjusted via contract. E.g., 10% for 6 months, 25% for 1 year.

• Fee Burn Rate: 10% of block fees are burned.

KYC Delegator

• Stake: Native ICB Tokens.

• Reward Token: Receives GICB Tokens (Governance Token).

• Rewards: No project-specific rewards.

• Limit: Unlimited number of delegators.

• Fees Share: 40% of the fees.

• Reward Calculation: E.g., Validator1 mines X blocks, 40% of these fees go to the connected delegators.

• Staking Reward Percentage: Managed through contract. E.g., 15% for 6 months, 30% for 1 year.

• Fee Burn Rate: 10% of block fees are burned.

Slot Delegator

• Stake: Native ICB Tokens.

• Reward Token: Receives GICB Tokens (Governance Token).

• Rewards: Project-specific rewards available.

• Limit: A fixed number of slots for delegators.

• Fees Share: 40% of the fees.

• Additional Benefit: 75% of transaction fees used in project operations are allocated to the Slot Delegator's address (or registered project owner's address).

• Reward Calculation: For instance, if Validator1 mines X blocks, 40% of these fees are divided among the linked delegators.

• Staking Reward Percentage: Set via contract. E.g., 10% for 6 months, 25% for 1 year.

• Fee Burn Rate: 5% of block fees are burned.

Comparison chart between ICB NETWORK PoS-based blockchains and other blockchains using different consensus mechanisms

ICB Network Development Roadmap

Welcome to the ICB Network development roadmap! This comprehensive guide outlines our key milestones and launch phases, providing you with a clear view of our exciting journey ahead. Here's what you can look forward to:

Q1 2024: Start of ICO Platform and Private Sale

• ICO Platform Launch: Marking the beginning of our investment phase, the ICO platform will be initiated for our primary investors.

• Private Sale: We will conduct our inaugural private sale, providing our primary investors with an exclusive opportunity to be a part of the ICB journey.

Q1 2024: Presale Rounds

• First Presale: Launching our first presale, we'll offer attractive bonuses to early investors, making it an ideal time to get involved.

• Second Presale: Following the success of the first, our second presale will come with great bonuses, continuing the momentum.

Q1 2024: Public Sale

• Public Sale Launch: The public sale will be open to all, featuring exciting offers for our wider investor community. This marks a significant step in broadening our investor base.

Q1 2024: Launch of Testnet

• Overview: The ICB Testnet will be rolled out, offering developers and the public an early glimpse into our innovative platform. This phase is crucial for testing and refining our network's features and capabilities.

Q2 2024: Mainnet Launch and Exchange Listings

• Mainnet Launch: Our fully operational mainnet will go live, accessible to developers and the public, signifying a major milestone in our project.

• Exchange Listings: Our tokens will be listed on several exchanges, enabling public trading and increasing accessibility.

Q3 2024: Delegation Allotments and DAO Launch

• Delegation Allotments: We will assign delegation slots, an important element for governance and network stability.

• DAO and New Projects: Alongside the DAO launch, we'll introduce several exciting projects on the ICB network, expanding our ecosystem and utility.

1. Staking Agreement

• Commitment: By staking your tokens, you agree to lock them for a predetermined period, during which they cannot be traded or withdrawn.

• Risks: Be aware that staking involves risks, including market volatility and potential changes in the project's direction.

2. Rewards and Penalties

• Earning Rewards: Rewards are distributed in accordance with the amount and duration of your stake. The longer and larger your stake, the greater the potential rewards.

• Penalty Clauses: Early withdrawal or violation of staking terms may result in penalties, including forfeiture of rewards.

3. Validator Responsibilities

• Role: Validators are crucial for maintaining network integrity. If you choose to become a validator, you must ensure your node remains online and performs optimally.

• Penalties for Downtime: Validators facing frequent downtimes or malicious activities may be penalized, which could include a reduction in staking rewards or even ejection from the network.

4. Governance Participation

• Voting Rights: Stakers may receive voting rights, allowing them to participate in key decision-making processes regarding network updates and governance changes.

• Active Involvement: We encourage participants to actively engage in governance proposals to foster a democratic and transparent ecosystem.

5. Privacy and Security

• Data Protection: We are committed to protecting your personal data. However, participants are also responsible for their own digital security, including safeguarding private keys and wallet information.

• Transparency: While we uphold privacy, certain aspects of transaction history and staking records are public for network transparency.

6. Regulatory Compliance

• Legal Boundaries: Participants must comply with their local laws and regulations regarding cryptocurrency and staking.

• Changes in Regulation: Be aware that changes in regulatory landscapes could impact your participation in the project.

7. Amendments

• Updates to Terms: These terms and conditions are subject to change. Any amendments will be communicated clearly to all participants.

• Continued Participation: Your continued participation after such changes constitutes acceptance of the new terms.

ICB MAINNET

Chain ID : 73115

Symbol : ICBX

ICB Testnet

Chain ID : 73114

Symbol : ICBT

JSON-RPC : is a simple protocol that allows data to be encoded and transported using JSON (JavaScript Object Notation) between client apps and blockchain nodes. It's a common interface by which apps can communicate with blockchain nodes.

GRPC : is a cutting-edge, high-performance RPC framework that is becoming more and more popular in the blockchain space because of its cross-platform compatibility, efficiency, and scalability. JSON-RPC is still commonly used, although for some blockchain applications, gRPC has clear advantages.

TXPool : a temporary holding space on individual blockchain nodes where pending transactions wait to be included in a block; sometimes referred to as mempool in several blockchains. Transactions wait in line to be processed and permanently recorded on the blockchain, much as in a staging area.

LIBP2P : is a framework for modular, adaptable peer-to-peer networking that is essential to creating robust, decentralized blockchain networks. It offers a strong platform that enables direct data exchange and communication between blockchain nodes without the need for centralized servers.

In October 2020, ICB Labs was established, marking the first concrete step for the company (ICB Crypto Services) into the blockchain industry. The goal is to broaden the company's perspective, find new areas of problems to solve, and address recent challenges in the blockchain and cryptocurrency space using well-known modern technologies. Under the guise of Ideal Cooperation Blockchain (ICB), this division set out to design smart contracts and enable instantaneous, middleman-free transactions using widely used blockchain platforms. As a result of its rapid expansion, the ICB Network is now among the most notable and cutting-edge blockchain initiatives in existence. The fact that it is the initial project layer is one of its distinguishing features. By causing significant modifications to the blockchain's structure, this feature enables the ICB Network to emerge as a first-layer network by tackling issues and concerns with current blockchain services. Notable among ICB Network features is the ICBX. Thanks to its clever design and the inclusion of the project's schematic technical symbol, this feature enables the network to adapt the size of its blocks according to requirements, which can range from 700 bytes to 820 bytes. The network's capacity to store and retrieve data effectively and respond rapidly to user queries is guaranteed by this unequaled capability. On top of that, the ICB Network is all about smart contract development to fix the biggest issues with current blockchain services. These updates boost the effectiveness of the network and make using it more pleasant for everyone. By prioritizing efficiency, security, and innovation, ICB Crypto Services has risen to the position of industry leader in the blockchain space. In the absence of middlemen, this business is building a better, more adaptable future.

Problem Statement

The creation of services and programs based on blockchain technology, as well as the execution of transactions, are now hindered by significant hurdles. Here, the scalability of blockchain technology is a big issue. In the near future, blockchain network traffic may reach critical mass, similar to the increasing number of stationary automobiles on a highway. Long acknowledgment intervals and scalability problems in the blockchain might result from this issue, which arises from the inability to execute several transactions at once. This will lead to a congested network and a poor user experience. As a result, the overall efficiency of the blockchain will be affected. Gas cost increase in blockchain architecture is another issue. Actually, the gas charge is quite similar to the toll that users must pay in order to access blockchain services. These costs can be prohibitive for certain users on certain networks. Because of this, it will no longer be profitable to use the blockchain network. Consequently, the network will only support transactions with large fees. Another issue with transaction speeds arises in this context. Users may be dissatisfied with the sluggish transaction speeds due to the fact that blockchain networks may be slow to operate, particularly in high-volume request situations. Programs and services that rely on instantaneous financial transactions are particularly vulnerable to this issue. These issues can be resolved with the use of a remedy. As a cutting-edge blockchain platform, the ICB Network is renowned for its increased speed, decreased gas charge, and improved scalability. Decentralized applications (DApps) and blockchain-based services may be more easily developed with the help of this network. The ICB network can build a blockchain ecosystem with more features after integrating its specific capabilities into EVM compatibility. Improving the user experience and providing assistance to blockchain developers are the primary goals of developing a more robust, affordable, and extensively utilized blockchain platform.

ICBX Blockchain Platform with POS Consensus Algorithm

The ICB Blockchain, built on a Proof of Stake (PoS) consensus algorithm, stands as a leading blockchain platform pioneering unique and intricate theoretical concepts. These pioneering theories empower our developers to craft a framework underpinned by identity value, where network members directly contribute to blockchain validity. This validity, unlike traditional systems reliant on trust in central authorities, is rooted in the collective identity and active participation of its community.

Environmental Friendliness

The ICB Network, when combined with the PoS consensus process, has the notable benefit of being environmentally friendly. The ICB PoS systems help preserve the environment by utilizing optimal algorithms and reducing energy consumption, in contrast to the traditional financial transaction procedures that are marked by high rates of resource and energy consumption. By facilitating safe and transparent transactions in blockchain systems, these platforms contribute to the attainment of environmental objectives.

Blockchain Validity

A defining feature of the ICBNetwork PoS consensus mechanism is the focus on identity value and its direct impact on delegate selection. Instead of individual token holdings solely determining their influence, the network considers factors like community reputation, contributions, and past performance. This incentivizes members to actively engage in the ICB ecosystem and contribute meaningfully, shaping the direction of the blockchain through participatory governance structures.

Scalability Solution

Blockchain platform development faces the formidable obstacle of scalability. Scalability issues, mostly relating to network security, plagued early blockchain networks like Bitcoin and Ethereum. While this is certainly a plus, there were restrictions on the amount of transactions that could be processed in a given time frame. Because of the scalability issue, networks are less efficient and run more slowly. Because of this, networks are unable to handle extremely high transaction throughput (TPS). Here we will now talk about modern standards. By 2015, the Ethereum network has adopted the ERC-20 protocol. In accordance with this standard, programmers can build several interchangeable tokens on a blockchain network. Essential features of tokens, including as their names, total supply, symbols, and decimal places, and fundamental operations, such as token transfers and balance inquiries, are also highlighted in this standard. You won't find a more secure smart standard than this one. Think about the ICB Network's incredible speed in conjunction with the safety of this standard. You are aware that the ICB Network facilitates the management of many tokens in a digital wallet and that ERC-20 permits the simple transfer of tokens. As a result, this standard can process up to 1200 transactions per second while providing unmatched security. Thus, blockchain technology may be expanded and utilized by a larger audience. More users can be accommodated in a sandbox setting as the developer need grows. As a result, blockchain technology may reveal more of its potential.

Using ERC-721 for Complicated Transactions in the ICB Network

Solving scalability issues and managing complicated NFTs and transactions is vital with the ever-increasing developments in blockchain technology. To address these issues and offer a trustworthy, cutting-edge blockchain platform, the ICB Network implemented the ERC-721 standard. This standard offers distinct features and is a key tool for managing complex tokens on the ICB Network. Assigning a distinct identifier to every token is a key component of the ERC-721 standard. This identifier goes under several names, including serial number and token number. In this way, every token becomes distinct. So, tokens may be owned and hold important data. Put simply, every ERC-721 coin is uniquely identified from all others. Large, complicated transactions involving one-of-a-kind items may now be executed with the help of this functionality. Virtual marketplaces, online gaming, and digital asset management are just a few of the numerous uses for these interactions. Also, developers may make their own unique tokens that work with blockchain apps and services thanks to the ERC-721 standard. Due diligence on this secure standard has been exhaustive in light of the project objectives of the organization. To the best of our knowledge, ERC-721 can handle 400 complex transactions per second in its present implementation. Plus, developers may enhance this default speed as the number of requests increases.

Conducting High-Speed Transactions in the ICB Network

Fast and efficient transactions are fundamental to the architecture of every blockchain network. The ICB Network, as used in ICB Crypto Services's projects, has an incredible throughput of 1,200 TPS. Everyday transactions may be processed quickly on the ICB Network. This characteristic is of paramount importance. This lightning-fast speed makes the ICB Network a universally applicable platform for developers. Various decentralized applications and transactions may be handled using this platform. Some examples include digital financial markets, online gaming, and the Metaverse.

EVM-Compatible ICBX

Building smart contracts and applications on the ICB platform relies heavily on EVM compatibility. In order to guarantee that projects are executed correctly and successfully, it is important to adhere to standards, prioritize safety and security, optimize gas usage, conduct tests and validation, and maintain close supervision and monitoring. Following these guidelines will let developers to build robust, secure smart contracts and applications on the ICBX platform, just like on other networks that are compatible with the EVM and enable interaction and competition.

Compliance with Standards

An important tenet of the ICB Network's EVM compatibility is adherence to legitimate token and smart contract standards. For programming languages that are compatible with EVM, there are several benefits to using the tailored secure standards, such as ERC-20, ERC-721, and ERC-1155. Smart contracts and programs may be accurately defined by developers thanks to these standards, which also facilitate their interaction with other apps and services on the network.

Safety and Security of ICBX with EVM

The security of smart contracts and programs is of utmost importance in the EVM-compatible ICBX. To avoid hacking and other security breaches, programs should have solid security mechanisms. Reliable and legitimate operations, data and input confirmation, and security risk minimization are of the utmost importance.

Gas Optimization

One of the biggest problems with the ICB platform is handling the transaction fees. All monetary transactions on the ICB network are pegged to the local token unit. With the ICB network's cheap gas charge, decentralized apps and optimized smart contracts may cut down on gas use and transaction fees. The network's primary fuel should be the local ICB tokens.

Test and Validation

In order to ensure that smart contracts and programs are error-free, they are tested extensively using EVM utility apps before they are actually run on the ICB blockchain. To guarantee flawless performance, thorough testing and validation are necessary. Once put into place, smart contracts and programs need constant vigilance to avoid malfunctions and mistakes.

Governance in Blockchain

A blockchain platform's governance is obviously crucial. As a kind of decentralized organization, token holders on the ICBX blockchain decide how the network is to be run. Members of the blockchain community will be able to take part in important decision-making processes and make revisions thanks to this mainstream way to managing network relations and making decisions. The governance aspects of the ICB platform are as follows:

• Democracy : The ICB platform's governance is based on democracy. Basically, regardless of the amount of tokens possessed, every token holder has a voice in the network's decision-making. With this method, the total quantity of tokens held by each user can influence the network's ultimate decision-making power.

• Leveling and Balance : The ICBX platform's governance prioritizes equilibrium and fairness. That is to say, decision-making power will mostly rest with the token holders with the most tokens. Nevertheless, decision-making is open to all members of the network. The decision-making process is enhanced by this relatively equal allocation of authority.

• Modifications and Upgrades: Token holders and developers may make real-time changes and updates on the ICBX network. So, in response to new opportunities and fluctuating market conditions, the network adapts by incorporating the required improvements and adjustments and enhancing its performance.

• Transparency: Openness in network performance and decision-making is a result of ICBX blockchain governance. Everyone in the network can see every choice and activity. The status and choices of the network may be easily accessed by all members thanks to this function. The ICB blockchain relies heavily on governance, to sum up. Using it helps keep the network's administration and decision-making under check. With this open and democratic method, everyone in the network may play an active part in making the ICB network better all the time. In order to take part, voting is required.

Voting in the ICBX Blockchain

To modify protocols and make pertinent choices, all voting criteria and requirements must be met in the ICBX blockchain. These measures are put in place to ensure that the decision-making process is fair, democratic, and open to all. The following are examples of ICBX blockchain voting criteria and conditions:

• Voting Criteria: An essential prerequisite for voting on the ICBX blockchain is the establishment of voting criteria. Precisely calculating the proportion of votes in support of a protocol amendment requires the consideration of a criteria. Obtaining 66% of the vote in favor might be one criterion for making a decision.

• Voting Conditions: Accurate determination of the prerequisites for voting is essential. These requirements could be conditional on the network members' levels of involvement or the quantity of tokens held by token holders. For instance, in order to vote, token holders could need 100 tokens or more. In addition, the circumstances surrounding each voting procedure are unique.

• Voting System: The ICBX blockchain uses a unique voting mechanism in which the majority of tokens cast determine the outcome. Each token is like a vote in this system. That is to say, the number of tokens that participate in the vote determines the outcome, and each token has one vote.

• Voting Duration: The length of time for voting is clearly defined. This time frame may be anything from a week to a month or more. During this time, everyone in the network has an equal opportunity to cast a vote and have their say on major decisions.

• Decision-Making Based on Polls: Polls provide the basis of the decision-making process. In this scenario, the tokens' majority vote determines the outcome. Changing the procedure will be the final decision if 66% of the votes are collected, to be correct.

Process of Creating and Selecting Blocks

Bonding in the ICB Network

Bonding in the ICB Network refers to the tie that binds projects to their donors. As a security deposit for various apps and initiatives, contributors can lock their tokens. Tokens as bonds allow donors to show their interest in and dedication to the ICB Network's decentralized apps (DApps) and their performance and security.

Advantages of a Bonding Fund for the ICB Network

• Enhancing Trust: By bonding tokens to projects, contributors indicate that they believe in the

  validity and importance of them and are willing to help develop them.

• Improving Security: The tokens used as bonds can be used during transaction validation and block

  creation. This can improve the network security.

• Encouraging in Participation: The concept of bonding encourages contributors to put more efforts

  into developing and improving decentralized applications and projects, as they play key roles in

  improving performance as well as having financial commitments.

An essential and foundational idea in the ICB Network is the bonding fund. With this money, we can incentivize and reassure investors and developers to work on decentralized application (DApp) and blockchain initiatives. In addition to the monetary benefits of this fund, corporate backers and investors in projects held by corporations can ensure their monetary and economic benefits. Additional investments and financial backing for the creation of ground-breaking DApps may be made possible using this method, which also improves the security and transparency of blockchain apps.

Features of the First Layer in the ICB Network

Utilizing innovative routing, dynamic block size, smart contract optimization, and high-efficiency consensus methods, the ICB Network successfully tackled scaling issues. The speed of processing transactions and the general efficiency of the network were both greatly enhanced as a result of these measures.

• Efficient Smart Contract Optimization in a Range of Sizes: The ICB optimized smart contracts to maximize efficiency. The processing time might be extended due to the correlation between gas fees and the execution of smart contracts. Spend as little as possible and execute transactions more faster by using the latest optimization techniques. Consequently, the overall performance of the network will be enhanced.

• Advanced Network Routing in Validation Process to Initial Storage : In order to direct transactions to the correct nodes and branches of the network, the ICB Network employs sophisticated routing algorithms. Thanks to its performance, transaction processing times are significantly reduced, guaranteeing lightning-fast processing.

• High-Efficiency Consensus Algorithm: Block Sharding : To enhance the validation of transactions and the consensus process, the ICB Network makes use of efficient consensus algorithms. Enhanced iterations of the PoS approach or delegated PoS methods comprise these algorithms. These algorithms and sharding strategies can reduce computing strain, allowing for rapid validation and confirmation of transactions. With this enhancement, the throughput of processing transactions per second is much enhanced. While competing blockchain networks could only manage 100–200 TPS in the benchmark testing, the ICB Network reached a maximum of 1200 TPS.

• Dynamic Block Size: First-Layer ICB Network : The dynamic block size is advantageous to the ICB Network. To rephrase, block sizes are adjusted to match the needs of the network. Blocks are built bigger to accommodate additional transactions during moments of strong activity. To make the most efficient use of resources during periods of low activity, smaller blocks are utilized. The ICB Network's efficiency and scalability will be enhanced by this precise conformity with the network requirements.

Gas Fee Reduction in the ICB Network

ICB Network gas tariff reductions are a major benefit. This is due to the technological capabilities of the first-layer blockchain technology. The following efforts were made: optimizing network gas cost parameters, improving transaction processing, upgrading smart contract execution, and determining block sizes. New modifications lower transaction fees and establish the ICB Network as a cost-effective blockchain solution.

The significant characteristic has an economic and commercial impact on all financial connections using this network. ICB technology offers great efficiency and low fees for secure and cost-effective digital asset exchange, information storage, data sharing, and financial transactions.

Detailed Management of Gas Fees

Firstly, the detailed management of gas fees in the ICB Network was considered a major goal. This management process included the detailed configuration of initial files of development in which the relevant parameters of gas fees were set in detail. () () ()

Optimization of Gas Parameters

One of the main ways to lower gas expenses in the ICB Network is to optimize the gas characteristics. As part of the optimization process, smart contracts and transactions are used to establish gas values accurately. Therefore, applicants will pay less to complete their transactions, and transaction costs are decreased.

Improvement of Transaction Processing Mechanisms

The ICB network has enhanced the methods of processing transactions. These enhancements boost efficiency and save transaction-related gas fees.

Optimization Strategies for implementing smart contract

Optimizing the strategies for executing smart contracts has helped reduce gas fees. The resultant-improvements enhance efficiency in the execution of contracts and reduce relevant fees.

Win-Win Situation

Everyone involved has come out ahead thanks to the ICB Network's technically feasible solution for lowering gas expenses.

Applicants will see a decrease in the costs associated with their transactions. As compensation, they've developed a more effective blockchain network. This mutually beneficial arrangement demonstrates that the cutting-edge blockchain technology can adjust to the requirements of candidates while efficiently controlling costs.

Candidates will have more faith in the ICB Network after these updates. Consequently, there will be an incentive for applicants to engage in additional transactions and activities.

Technical Explanation

Architecture Overview

Consensus: PoS helps optimize scalability and performance without forgoing Byzantine fault tolerance. It acts as the consensus mechanism of Polygon Edge and features a consensus engine, IBFT 2.0, and a consensus protocol, including bridge, staking, and other utilities.

Networking: The use of libp2p protocol promotes decentralised communication among peers. It also offers P2P networking primitives such as peer discovery, secure messaging, and connection management.

Blockchain: This decentralised distributed ledger records transactions and verifies every transaction with end-to-end encryption. It involves new block addition, retrieving blocks using hash value, verifying block headers, updating the chain's average gas price, etc.

Memory Pool: Acts as a temporary storage area for pending transactions before they get added to a block. After submitting transactions, they are initially held in the memory pool, allowing miners to include them in the next block.

Transaction Pool: Effectively handles incoming transactions for processing. It manages a list of unprocessed transactions and makes sure they comply with certain restrictions before entering the pool.

JSON-RPC: Allows seamless communication within the distributed systems and aids developers in developing scalable apps with low-latency communication. This RPC protocol helps clients in making requests to the server and obtaining responses.

gRPC: gRPC offers exceptionally faster communication and bidirectional streaming while sending and

receiving multiple requests and responses.

An improved consensus technique that builds on Proof of Stake's foundational principles is Proof of Stake (PoS). The 2014 Proof of Stake (PoS) consensus mechanism was created by BitShares, Steemit, and EOS creator Daniel Larimer.

Every staker in a Proof of Stake network has an equal opportunity to take part in the "mintage" process, where they may choose the nodes in layer two that validate blocks further and get rewards for adding them to the blockchain. An election mechanism selects nodes to verify blocks in the Pos system. "Witnesses" or "block producers" are the terms used to describe these nodes.

Delegates:

Delegates are elected by users in PoS systems to manage the governance of the blockchain. When it comes to controlling transactions, they have no role. Any delegate has the right to suggest changes to the block size or the witness payment for verifying a block. The blockchain community votes on whether or not to implement modifications proposed by delegates.

In PoS, complete nodes are known as block validators, and their job is to ensure that blocks generated by witnesses adhere to the norms of consensus. The network may be verified by any user running a block validator. Block validators don't get anything out of the job.

Networking:

• Libp2pp: The decentralized networking layer used by Pos is built on top of the libp2p protocol. Peer-to-peer networking primitives including connection management, peer discovery, and encrypted messaging are provided by the protocol. To control peer connection and handshaking and guarantee that only legitimate peers may join the network, the network depends on a secure Identity Service.

• Identity: The Identity Service controls peer handshaking and verifies inbound connections. It communicates with the underlying networking layer through a networkingServer interface and keeps track of pending peer connections.

• Peer discovery: Pos employs the distributed hash table (DHT) of libp2p, which is based on the Kademlia algorithm. The DHT keeps track of other peers' addresses and availability inside the network. A newly connected node searches for additional peers that are online via the DHT. Periodically, in order to keep a sufficient number of connections in the network, the procedure of utilizing the DHT to find peers and then sending out connection requests is repeated.

• Peer routing: Bootnodes assist new nodes in finding and connecting to the network by serving as rendezvous servers. When generating the genesis file, you can specify one or more bootnodes using the polygon-edge command. Libp2p multiaddrs, which provide details about the protocol, network address, and node port number, are used to define bootnodes.

• Gossip Sub: In Polygon Edge, Gossip Sub is a decentralized, peer-to-peer messaging system that facilitates effective message dissemination throughout the network. It is utilized by the TxPool, among other network components, to broadcast new transactions and transport transaction data across nodes. Gossip Sub reduces network capacity consumption while enabling effective and dependable message dissemination.

Blockchain Mechanics

The foundation of ICB chains is a shared blockchain architecture that efficiently administers and preserves the blockchain data structure, which is made up of a state database and a sequential chain of blocks holding transactions and other metadata. The fundamental blockchain implementation provides a number of features, including: extending the chain with additional blocks. obtaining blocks by their number or hash.

Managing reorganizations of chains (that is, transferring to a more challenging chain). checking the gas limitations and block headers. Block headers and receipts are cached to increase retrieval speed. updating the average gas price for the chain. Several sub-components are used by the implementation to deliver these features, including: a consensus mechanism in charge of approving fresh blocks and adding them to the chain. a part of a database that keeps blockchain data permanently.

An event component that broadcasts information about fresh block additions and chain reorganizations to other components. a transaction signer component that shows the sender address and confirms transaction signatures. a part of the gas price calculator that figures out the average gas price for the chain.

Token Utility

The ICB token is a versatile tool that can be utilized in a variety of businesses and ecosystems due to its wide but distinctive qualities. This coin has the potential to be extremely important for streamlining transactions, trading assets, and enhancing user satisfaction.

Transaction Fees: Every transaction in the ICB Network needs transaction fees that are paid by the ICB tokens. These fees will use the ICB tokens with very low decimals approaching zero. They are collected as a part of the token deflation mechanism. These financial resources help develop and maintain the ICB platform.

Governance: The ICB token holders can participate in the governance of this platform. They can be involved in voting on recommendations and decisions concerning the future of this platform. This feature allows a community to participate in major decisions made in the network and influence the future of the platform.

Ecosystem Rewards: The ICB token holders can acquire financial rewards by participating in different ecosystem activities, e.g., using tokens as bonds, extracting tokens, and participating in governance.

Growth Potential: Given the limited supply of tokens ( 100B tokens) and the use of an economical token deflation model, the ICB token has considerable potential for higher values. As there is an upward trend in the demand for the ICB platform and tokens, the value of the ICB token can increase significantly. This can be viewed as an additional motive for the ICB token holders to keep their tokens and participate actively in the network ecosystem

Gaming Industry: The ICB token can be used as a cryptocurrency in the gaming industry to purchase and sell virtual objects and assets in online games and VR environments.

DeFi (Decentralized Finance) Projects: The ICB token can be used as a currency in DeFi projects to pay fees, make down payments, and conduct transactions without intermediaries.

Digital and Tech Industry: The ICB token can be used as a motivational, payable currency in software development projects, engineering services, and data processing.

Asset Exchange Platforms: The ICB token can be used on asset exchange platforms (e.g., financial marketing, real estate markets, exchange of valuable assets such as stocks and securities) in both the real world and the virtual world.

Metaverse Projects: In Metaverse projects that present virtual worlds and provide VR experiences, the ICB token can be used as an exchange currency in transactions conducted by users and businesses.

Connection to IoT Devices: In the IoT industry, the ICB token can be used as a denomination to pay for different services concerning the devices that connect to the Internet. These services include monitoring and managing devices, conducting IoT-connected transactions, and creating secure transactions.

Health and Medicine: Given the MICB project in health and medicine, the ICB token can be used as a denomination to pay for medical services, manage electronic medical files, and conduct digital commerce in this area.

Supply Chain and Logistics Projects: In the areas of supply chain and logistics, the ICB token can be used as a denomination to pay transportation fees, manage the supply chain, and improve experiences with virtual transactions.

Energy Industry and Environment: In the projects of energy management and environmental protection, the ICB token can be used as a currency to pay for the fees of renewable energy, environmental management, and ecological data exchange.

More information about the ecosystem ahead:

Part1: Blockchain in Gaming - ICB Ecosystem

Revolution in gaming: ICB leverages blockchain technology to revolutionize the gaming industry, offering games within its ecosystem that enable players to earn income through Play-to-Earn models and experience ownership of rare and unique digital assets.

For Example:

Game Name: Cryptic Conquest

Genre: MMORPG (Massively Multiplayer Online Role-Playing Game)

Game Introduction: Cryptic Conquest immerses players in a fantasy world called Eldoria. Players assume roles as warriors, wizards, and strategists from various clans competing to control lands and natural resources. Each player can expand their territory, build armies, forge alliances, or engage in warfare.

Utilizing Blockchain and NFTs: Every land piece, weapon, magic item, and character in Cryptic Conquest is represented as a unique Non-Fungible Token (NFT). Players can trade these NFTs within the game's internal marketplace, lease them out, or even use them as collateral for in-game decentralized finance (DeFi) loans.

Game Scenario: Players begin by selecting a tribe and acquiring a small territory. Through missions, resource gathering, and battles, players earn experience and resources necessary to upgrade territories and build formidable armies. Regular tournaments offer opportunities to win rare and valuable NFTs.

Play-to-Earn Mechanism: Cryptic Conquest implements a Play-to-Earn model where players earn in-game tokens by advancing through the game and participating in various activities and events. These tokens can be exchanged for other cryptocurrencies on external markets, enabling players to earn real income.

Technology and Security: Built on the ICB blockchain, Cryptic Conquest ensures high transparency and security. All transactions and changes in NFT ownership are securely recorded to prevent fraud and ensure fair play.

Development and Future Plans: ICB intends to enhance player engagement by expanding the game universe and introducing new features. Continual development aims to provide fresh content and additional earning opportunities for players.

NFT Technology: ICB is dedicated to developing games utilizing NFTs, allowing players to legitimately buy, trade, and sell digital assets with confidence and security.

This approach not only enhances player immersion and enjoyment but also pioneers new avenues for monetization and asset ownership within the gaming community.

Part2: Blockchain in Metaverse - ICB Ecosystem

Development of the Metaverse: Leveraging blockchain technology, ICB has created metaverses where users can own and develop their virtual spaces. These spaces are designed for business, entertainment, and social interactions.

For Example:

Metaverse Name: AICBVille

Genre: Simulation of Virtual Society and Business

Introduction to AICBVille:

AICBVille is a metaverse where users can actively participate by starting companies, buying or building houses and land, and engaging in social and recreational activities. This metaverse integrates virtual reality, social networks, and video games, all on the ICB blockchain platform.

Metaverse Scenario:

In AICBVille, each user enters with a digital avatar and can buy or sell land anywhere in this expansive world. These lands are offered as NFTs, with ownership that can be transferred and traded. Users can construct buildings, parks, shopping malls, and even towns, each of which can generate income through rentals or hosting events.

Game Market Development:

- Assets and Transactions: Users can buy and sell land, buildings, and even cities as NFTs, each with varying economic values based on location, usage, and market demand.

- Business and Economic Activities: Users can create and develop virtual businesses that sell digital services or goods, such as fashion design, virtual furniture, or entertainment services.

- Events and Entertainment: Users can host concerts, theater shows, art exhibitions, and seminars for which digital tickets can be purchased.

- Social Interactions: AICBVille enables networking, making friends, and engaging in virtual interactions that enrich the user experience and help create online communities.

Security and Privacy:

All interactions and transactions in AICBVille are recorded and secured through smart contracts on the ICB blockchain, ensuring the protection of users' data and assets.

Development and Future Plans:

ICB plans to continually enhance user experiences by introducing new features such as advanced augmented reality, social functions, and non-gaming uses in the AICBVille metaverse.

Augmented Reality and Physical Interactions:

- Augmented Reality: ICB aims to enhance user experiences by incorporating augmented reality technology. This allows users to view virtual elements in their physical environment, such as displaying purchased artwork in their real homes or attending virtual concerts held in their living rooms.

- Physical Interactions: To bridge the real and virtual worlds, AICBVille enables direct communication of avatars with IoT devices, allowing users to receive metaverse news or environmental changes through physical devices in their homes.

Advanced Social Functions:

- Virtual Learning System: AICBVille offers spaces for virtual courses where students and teachers can participate in virtual classes and enjoy real social interactions.

- Dynamic Classrooms: Classrooms in AICBVille can be set up as amphitheaters, interactive workshops, or open discussion rooms, allowing teachers to adapt the environment to their curricular needs and teaching styles.

- Interactive Boards and Educational Tools: Each class is equipped with digital boards, drawing tools, and interactive educational software, enabling students to work in groups and interact with course materials through their avatars.

Access and convergence:

• Wide access: AICBVille's virtual space allows students from anywhere in the world to participate in classes, without the need to be physically present.

• Integration with existing educational systems: AICBVille collaborates with various universities and educational institutions to offer their existing courses on Metaverse and the educational qualifications offered on AICBVille are globally valid and verifiable.

AICBVille virtual education system is provided with the aim of creating an innovative and efficient platform for learning and cultural and knowledge exchange, to create a fundamental transformation in the way of education in the digital age.

• Networking events: holding special networking events for different industries that users can participate in to establish professional connections and access new job opportunities.

Non-gaming applications:

• Digital businesses and stores: ICB allows businesses to create virtual business spaces where physical or digital products can be sold. Also, companies can create their own virtual offices for remote employees.

• Galleries and exhibitions: holding art exhibitions and digital galleries with the aim of displaying the works of artists from all over the world, which users can view and even buy.

Development and Future Plans:

ICB is committed to maintaining AICBVille as a living and dynamic metaverse. Relying on user feedback and continuous development, ICB Network plans to introduce new features that will continuously improve the user experience and make Metaverse a reference for more and more engaging social and professional interactions.

Progress Evaluation and Follow-Up System:

Blockchain-Based Evaluations: Students' performance and academic records are digitally recorded using blockchain technology, ensuring transparency and accuracy of information.

Certificates and Degrees in NFT Form: Students who successfully complete courses are awarded digital certificates in the form of NFTs, which are easily transferable and valid worldwide.

Social and Educational Interactions:

Study Groups and Workshops: Students can form digital study groups or participate in educational workshops provided by other students or teachers. These activities offer opportunities for collaborative learning and social networking.

Access and Convergence:

Wide Access: AICBVille's virtual space allows students from anywhere in the world to participate in classes without needing to be physically present.

Integration with Existing Educational Systems: AICBVille collaborates with various universities and educational institutions to offer their existing courses on the Metaverse. The educational qualifications provided on AICBVille are globally valid and verifiable.

Purpose and Goals:

The AICBVille virtual education system aims to create an innovative and efficient platform for learning, cultural exchange, and knowledge sharing, fundamentally transforming education in the digital age.

Networking Events:

Special Networking Events: These events cater to different industries, allowing users to establish professional connections and access new job opportunities.

Non-Gaming Applications:

Digital Businesses and Stores: ICB enables businesses to create virtual spaces where physical or digital products can be sold. Companies can also create virtual offices for remote employees.

Galleries and Exhibitions: ICB hosts art exhibitions and digital galleries to showcase the works of artists from around the world, which users can view and purchase.

Development and Future Plans:

ICB is committed to maintaining AICBVille as a vibrant and dynamic metaverse. By relying on user feedback and continuous development, ICB Network plans to introduce new features that will continuously improve the user experience, making the Metaverse a hub for more engaging social and professional interactions.

Part3: DeFi - ICB Ecosystem

DeFi Financial Solutions

DeFi Financial Services: ICB offers decentralized financial services, including lending, trading, and insurance, through DeFi platforms. These services are universally accessible and highly secure.

DeFi Platform Design and Idea: ICBLoan

Introducing ICBLoan: ICBLoan is a DeFi platform developed by ICB that allows users to lend and borrow digital assets. Designed with blockchain transparency and security principles, this platform enables users to conduct financial transactions in a safe and low-risk environment.

Market Mechanism in ICBLoan

Lending and Borrowing:

- Lending: Users can deposit their digital assets in stablecoins or other cryptocurrencies into the platform's smart contracts to earn interest.

- Borrowing: Users can obtain loans by pledging their collateral, such as NFTs or other digital assets. The interest rate is determined by factors such as the amount of collateral, the loan period, and the borrower's financial history.

DeFi Transactions:

Digital Asset Trading: The platform allows users to buy and sell digital assets using Swap technology. This feature facilitates transactions without the need for direct matching between buyers and sellers.

DeFi Insurance

Insurance Coverage: ICBLoan provides insurance coverage for users' loans and investments to protect their assets in case of unexpected events, such as hacking or technical errors. This insurance service is managed through smart contracts that handle risks and conditions.

Security Guarantee

Advanced Security: All transactions and contracts on the ICBLoan platform are executed using advanced encryption and up-to-date security protocols, ensuring that users' data and assets are protected against unauthorized access.

Part4: Interchain Exchanges - ICB Ecosystem

Example Platform Name: InterChain Exchange (ICE)

ICE Platform Introduction

ICE is an inter-chain exchange platform developed by ICB to facilitate the exchange of data and digital assets between various blockchain networks such as Ethereum, Binance Smart Chain, Polygon, Avalanche, and ICB itself. This platform is specially designed with a focus on using bridge technologies like Polkadot and Cosmos to enhance interactions and efficiency.

Working Mechanism of ICE Platform

Interchain Bridges:

Construction and Use of Digital Bridges: ICE utilizes bridge technologies to establish secure connections between different chains. These bridges enable users to transfer assets and information at minimal cost and in the fastest possible time.

Decentralized Exchange (DEX):

Integration with DEXs: ICE seamlessly integrates with reputable DEXs on any chain, allowing users to exchange their digital assets within minutes. This integration facilitates cross-chain transactions, enabling users to benefit from the features of various blockchains.

Advanced Working Mechanism of ICE Interchain Exchange Platform

Using Oracles for Two-Way Communication:

Two-Way Communication with Oracles: ICE employs oracles to obtain data and verified prices from outside the blockchain and provide this information to the blockchain. This data helps verify transactions and calculate accurate conversion rates between different chains.

Using Hash Time Locked Contract (HTLC) Protocol:

HTLC Protocol: This protocol is a key mechanism in ICE, ensuring the security and execution of contracts in inter-chain transactions. HTLC allows assets to be transferred only when both parties to the transaction meet the required conditions.

Multi-Signature Approval Process for Transactions:

Verification of Multiple Signatures: ICE requires multiple signatures (multisig) to verify significant and large transactions. This process helps prevent unauthorized changes and fraud, providing users with greater confidence.

Programmable Events and Smart Contract Hooks:

Event Scheduling: ICE enables the scheduling of specific events and reactions in smart contracts, allowing users to set up automated responses to market conditions or price changes.

Reducing Costs and Increasing Speed through Network Optimizations:

Network Optimization: ICE continuously optimizes network algorithms and protocols to enhance transaction speed and reduce costs, making markets more accessible to all users.

Exchange Security

Support and Maintenance:

Continuous Support and Updates: The ICE development team continually reviews and improves the platform's technologies to ensure security against new threats and maintain optimal performance.

Development and Future Plans

ICB aims to develop ICE into a hub for decentralized financial innovation. By integrating new technologies and fostering international cooperation, ICE intends to push the boundaries of digital exchanges and provide access to digital financial services to a global audience.

Conclusion and Foresight

Committed to innovation and continuous improvement, ICB seeks to enhance and expand its blockchain ecosystems. In the future, ICB plans to optimize its products and services using user feedback and emerging technologies to offer a better and more inclusive experience for all participants.

Marketing Strategy

Given the great potential of this platform, a fundamental strategy must be adopted to promote and accept the local ICB token. Some marketing strategy elements were addressed for the ICB platform, and certain strategies were offered to improve its popularity and acceptance.

Purposive Advertisements: Using purposive advertisements on the websites and services of blockchain and IT can help extend the acceptance of the ICB platform. These advertisements can intelligently show users how they can participate in this platform and benefit from our network services.

Communicating with Influential People: One of the earliest steps in the ICB marketing strategy is to communicate with influential people in the blockchain and IT industry. These individuals can be influential users in the blockchain community. Cooperating with these individuals and gaining their support will improve the advertising validity and power of the ICB. These individuals can also act as the ICB brand ambassadors and convey positive messages on this platform to society.3) Airdrop Distribution: Airdrop is a valid method for promoting a blockchain platform. We can increase the number of users by distributing free-of-charge ICB tokens to the users users who actively participate in the ICB community or perform specific tasks. As a result, these users will be encouraged to keep this platform dynamic. These distributions can motivate new customers to join the ICB and actively participate in the ecosystem of our platform.

Advertisements on Social Media and Weblogs: An important tool in the ICB marketing strategy is to run advertisements on social media (e.g., X, Instagram, and Telegram), official websites, and blogs. Considering the huge communities on these ICB Network-based platforms, designing engaging and targeted advertising campaigns can help grow the ICB and attract new users. Moreover, collaborations with the reputable bloggers and writers of blockchain and IT can help improve the influence and publicity of the ICB platform.

Social Media Campaigns: In the ICB marketing strategy, a major tool is socialization on social media. We can disseminate more information on the ICB Network and its advantages by creating interesting valid campaigns on social media (e.g., Twitter, Telegram, Instagram, and Google). These campaigns can share articles, videos, and interesting advertisements that show users how the ICB Network can help them solve their financial problems.

Strategic Partnerships: Other important aspects of the ICB marketing strategy include interaction and cooperation with blockchain platforms and reputable players in the industry. Forming strategic partnerships with these platforms can lead to cross-over advertisements, develop joint smart contracts, and increase inter-platform interactions. These interactions can then help develop the blockchain ecosystem and promote the ICB Network further.

Participation in Blockchain Events: Participation in blockchain/IT events and conferences can provide the industrial society with a great opportunity to introduce the ICB platform. By participating in these events, the ICB team can be in contact with decision-makers, developers, and potential users and provide them with comprehensive information.

Regional Delegates and Counselors: Recruiting regional delegates and counselors that know locals and specific conditions in every region can help develop the ICB platform on a global scale. These individuals can be employed to share local ads, provide local users with support, and facilitate communication with different communities.

Referrals: Another strategy for improving the acceptance of the ICB platform is to make pleasant invitations and develop referral programs. We can increase the number of new users and help expand the ICB community by offering discounts and making special offers to the users who introduce their friends and acquaintances to the ICB platform.

Economic Promotion and Advantages: Focusing on the economic advantages of the ICB platform can play an effective role in the marketing strategy. We can encourage businesses andindividuals to use this platform by explaining how we intend to reduce the fees and improve efficiency through the ICB platform. It is also possible to enhance the public trust in this platform by showing the real results and achievements of the ICB through witnesses from the blockchain population.

Tokenomics

Given the distribution of the ICB tokens, we can analyze Tokenomics more comprehensively and determine the effects of each class of these distributions on the growth and development of the network.

Total supply : 100B Public Sale (Initial Distribution):

● 35% (35B tokens) This portion can be distributed over several phases or rounds to ensure a fair and decentralized launch.

● Team : 10% (10B tokens)

● Advisors: 5% (5B tokens)

● Ecosystem Development Fund: 30% (30B tokens)

● Reserve Fund: 5% (5B tokens)

● Staking Rewards: 12% (12B tokens)

● Community Grants and Airdrops: 3% (3B tokens)

ICB Network Roadmap

Phase 1 of Train V. 1.2

Testnet is used in the ICB Network to test and validate codes and transactions before they are executed in the main network. This section reviews some of the important features and information on the ICB testnets. Different Testnets: The ICB platform has different testnets, each of which is used to test specific components of the network.

TICB Tokens: The TICB tokens act quite the same as the real ICB platform on the ICB Network. These tokens are used to send transactions and conduct tests; they have no real value. Applications and Developers: The ICB Network testnet allows developers to test their codes in a virtual environment before running the codes in the main network. This feature helps develop and correct codes.

High Speed: In the ICB testnet, transactions are conducted very much faster. Given the EVM compatibility, the validation time of each transaction will be minimized.

Development Networks: The TICB testnet usually benefits from development networks that allow developers to access specific tools and features, e.g., test transactions and test tokens.Free Access: The test tokens are available to the public free of charge; therefore, users can easily select and use testnets. Tetnets are considered the most important phase in the development and validation of projects based on the ICB Network. They allow developers to fully test and troubleshoot their codes before publishing them on the main network

Phase 1 of Reservoir V. 1.3

ICB Liquidity Pool

Liquidity pools are considered a fundamental component of the ICB coin exchange and other blockchain cryptocurrencies, e.g., Ethereum, Binance Smart Chain (BSC), Polygon, Avalanche, and all transferrable second layers. These pools act as major sources of accessible liquidity through automated exchange (DEX). In other words, they allow users to give their cryptocurrencies to the local ICB DEX protocol and conduct transactions fast and efficiently.

Performance of the ICB Liquidity Pool

Every liquidity pool consists of two different cryptocurrencies that are used for exchange. There is usually a primary cryptocurrency, e.g., the ICB Coin (ICB), and another cryptocurrency, e.g., Stablecoin (USDT or DAI), in the pool.

The ICB liquidity pool functions as below:

Flexibility: Users can enter their cryptocurrencies into the liquidity pool for storage. In return, they receive equal ICB Coins.

Income Reward: The users who have staked their cryptocurrencies in the ICB liquidity pool will benefit from the transaction fees of other users in return for conducting transactions on the ICB platform and using the ICB liquidity. In fact, another form of staking is performed.

Cryptocurrency Exchange: Users can exchange their cryptocurrencies in different currency classes. For instance, they can exchange the ICB Coin to the USDT, or vice versa. These exchange processes are performed through specific ratios in the liquidity pool.

Phase 1 of Fuel V. 1.4 : Importance of the ICB Liquidity Pool

The ICB liquidity pool plays a key role in the blockchain ecosystem:

Facilitating Exchange: By supplying sufficient liquidity, the liquidity pool enables fast and efficient cryptocurrency exchanges.

Maintaining Market Robustness: By striking a balance between the supply and demand for cryptocurrencies, the liquidity pool avoids sharp fluctuations in their prices.

Profitability: The users who place their cryptocurrencies in the liquidity pool will be rewarded. Their rewards come from the fees of transactions. The type and validation of rewards are determined by smart contracts.

Importance of ICO in the ICB Project Development

Known as a capital collection method in blockchain projects, the ICO operation plays a key role in developing and growing these projects. In the ICB Network project, the ICO bears special importance as a financial resource used for technical development, ecosystem features enhancement, and communication with a community of contributors interested in the ICB blockchain.

The ICO is a method to raise capital and it allows the ICB-based projects to quickly supply the necessary financial resources and strive to a more advanced state. These financial resources can be utilized to facilitate the technical development of a blockchain project, recruit developers, create a surrounding ecosystem (e.g., the meta ICB project), implement advertising strategies, and introducing delegates in different markets.

In addition, the ICO provides an opportunity to motivate and attract active contributors to the project. Those who work at the ICO and collect the ICB tokens will turn into collaborative entities in the project development. Therefore, they feel that they own something in the digital asset ecosystem of the ICB platform, as the value of the preordered token is lower than its real value in the market.

Finally, the ICO acts as an effective tool for developing the local ICB tokens and enhancing the general knowledge on a project of interest. This feature develops the ICB ecosystem and increases the value of tokens. As a result, investors will find an opportunity for profitability on airdrop in this project.

In conclusion, the ICO is a vital method for developing blockchain projects and providing financial support, thereby it plays a pivotal role in the ICB project development. This engaging approach brings together investors, developers, and blockchain aficionados to help develop the ICB ecosystem. Therefore, like any other accurate, legal investments, participation in the ICO can provide you with an opportunity to join this advanced ecosystem.

Phase 1 of Ship V. 1.5 : Mainnet of the ICB Network

Mainnet is the main network of the ICB Network. In other words, it is an environment where all transactions and operations are really conducted with their material values in the ICB Network. This Mainnet is known as the core of the ICB Network, in which all transactions and DApps are executed mutually. The following section provides further information on the ICB Mainnet and its role.

Conducting Real Transactions: The ICB Mainnet is an environment where real transactions and operations, e.g., ICB cryptocurrency exchange and smart contracts executions, are conducted. In this network, users can send their cryptocurrencies to other users or smart contracts and conduct different operations such as validating transactions.

Technological Advance: ICB Crypto Services Company has a leading role in developing blockchain platforms and providing smart capabilities in smart contracts. The ICB Mainnet is an environment where developers can execute their innovative DApps and programs on this blockchain platform and benefit from its advanced technological capabilities.

Test and Development: The ICB Mainnet allows developers to execute and test their applications in real-world environments. This phase of test and development plays a key role in ensuring applications run smoothly and preventing unexpected errors.

Project Support: The ICB Mainnet is an environment where different projects are developed on this blockchain platform. These projects include DApps, ERC-20 cryptocurrencies, and various types of smart contracts. All advantages and tasks that have already been described can be executed on the Mainnet platform in order to enter the real financial digital world.

Smart Contracts – ERC-20

A prominent feature of the ICB Mainnet is to support smart contracts. These contracts define certain rules to conduct specific transactions and operations on the ICB platform without any intermediaries. Moreover, ERC-20 is a standard for the cryptocurrencies created on this blockchain. This standard allows developers to generate a wide variety of digital tokens.

Smart Contracts – ERC-721

ERC-721 is an NFT (non-fungible token) standard in the Ethereum blockchain. Unlike NFTs, the ERC- 921 tokens have a unique feature. Every token can be defined as a unique item or asset. This standard allows developers to create a wide variety of digital tokens that can be used as the ownership certificates of artworks, group assets, and vocations. As a result, this standard has started the NFT Talent marketplace platform.

Smart Contracts – ERC-1155

ERC-1155 is a multi-fungible token standard that is compatible with the Ethereum blockchain and all blockchain structures that operate on the Ethereum virtual machine. Powered by Enjin, this standard allows for the issuance of diverse digital tokens. Unlike the conventional standards that define tokens as fungible (e.g., ERC-20), ERC-1155 enables developers to combine different digital tokens with various features in a single smart contract. Therefore, developers can create digital tokens with diverse features, e.g., cryptocurrencies, series of cards, and gaming items. As a result, the developing team has decided to use the meta ICB. ERC-1155 has specific features, e.g., limited resource usage (Resource IDs) and additional token exchange. This standard is used widely in DApps and digital games, allowing for the exchange of tokens in the same smart contract.

Explorer: The comprehensive guidelines on the ICB Network are available to the public. The ICB Network Explorer is a vital tool for the developers and users of the ICB Crypto Services, allowing them to observe and analyze relevant data and transactions. These tools facilitate the processes of developing and testing blockchain-based applications and smart contracts and ensure their correct performance in the ICB Mainnet.

ICB Scan Explorer : An explorer is considered an important tool in the realm of blockchain, enabling developers, researchers, and casual users to check transactions and network-related information. Explorers play a valuable role in observing and checking the data of a network and pursuing transactions.

Why Is the ICB Network Explorer Important?

Pursuing Transactions: Developers and users can pursue their transactions in an explorer and see different pieces of information, e.g., transaction status, completion time, and addresses.

Checking Contracts: If a smart contract is executed on a testnet, it is possible to check its status and information via an explorer.

Running Tests: An explorer allows users to test their transactions and contracts and check their execution status.

Human Aspect of the ICB Network Blockchain

ICB Network projects do not only need one group of developers. They need a wide range of experts including the developers of smart contracts, PR experts, and legal experts for development and management. Cooperating under the leadership of Mike Verdish as an idea creator, all experts try to contribute to the success of ICB blockchain projects. They are considered crucial contributors of advancement in this novel industry. The essential roles of various experts in the ICB blockchain projects will be analyzed.

Developers of Smart Contracts: The developers of smart contracts play a key role in the ICBS blockchain projects. These developers use Solidity to create and implement smart contracts on the ICBS platform. They can design smart contracts and offer diverse features, e.g., creating exchangeable pre-extracted tokens, distributing tokens, developing DeFi contracts, and creating blockchain-based games.

DApps Developers: DApps developers (user experience of blockchain applications) play a significant role in the ICBS blockchain projects. They can develop Web-based mobile applications on the ICBS platform. They can also use blockchain resources to develop a wide variety of applications, e.g., wallets, DeFi markets, online games, and other decentralized applications and Metaverse directed applications.

Public Relations Department: In the ICBS blockchain projects, this department is responsible for communication with the blockchain community, the media and the international community. Members of this department may be responsible for public relations issues within a project and for communicating news about project developments. They can also interact with other coworkers and the blockchain community at large. They also participate in marketing and advertising activities of the project.

Legal Department: The legal experts are experienced in blockchain services; therefore, they play a key role in the ICB blockchain projects. They are responsible for analyzing rules and regulations concerning the blockchain platform and the ICBS network. They check the legal documents and contracts, preserve the intellectual rights, and settle down legal disputes.

Marketing Department: The marketing experts can codify and implement marketing and advertising strategies for the ICBS projects. They can help determine the target users, analyze the market and competitions, develop advertising strategies, and increase the project knowledge. Financial and Risk Management Experts: The financial and risk management experts play a key role in the ICBS blockchain projects. They are responsible for analyzing the financial aspects of the project. They can also analyze tokens, distribution mechanisms, economic models, valuation, and other financial aspects to guide project developers and project managers.

Technical Support Team: The technical support nodes in the ICBS are involved in providing technical support services and troubleshooting technical problems in the network. Network Control Fi-Chain: The network control nodes are responsible for managing and controlling the ICBS Network performance. They manage the network traffic to ensure that the network is operating optimally and reliably.

The ICB Network: A Positively Effective Breakthrough in the Future of Economy and Technology In brief, the ICB Network is considered an innovative technology that can provide different features for improving economic performance, enhancing security, and offering new opportunities. We employ the blockchain technology to achieve cooperation and development in the digital world and move toward abetter and brighter future. Known as a novel base in technology and economy, blockchain plays a pivotal role in shaping our economic future and leads to new stable features for developments and advancement in society. Not only does this technology bring economic improvement and security to the world, but it also paves the way for reaching a better modern society. Therefore, blockchain is considered a golden opportunity for making positive, sustainable developments in our modern world.

Security Assurance: Blockchain employs certain security algorithms, e.g., PoS, to prevent fraud and unauthorized use of data. Therefore, it can enhance trust between individuals and businesses and ensure that transactions and information remain intact and safe.

Speed and Efficiency: Limiting intermediaries and reducing the need for validation by central brokers, blockchain can accelerate transactions. This feature bears special importance in such cases as transferring funds between countries or validating the ICB transactions.

Transparency: Blockchain operates publicly and transparently. The history logs of transactions are available to the public. This level of transparency reduces the risk of corruption and fraud in transactions and provides further information for the analysis of markets.

Economic Improvement: The use of blockchain in the ICB projects and other industries will help improve the economy. This novel technology provides new opportunities for businesses and organizations, thereby enhancing efficiency and allowing for fees management.

Optimization of Gas Parameters: The optimization of gas parameters is a major factor in reducing gas fees in the ICB Network. This optimization process includes the detailed setting of gas values based on smart contracts and transactions. As a result, the fees of transactions will be minimized, and the esteemed clients will incur lower fees for their transactions.

Employment and Development: Developing the blockchain-based projects can help provide new job opportunities and achieve economic development. This technology allows developers and entrepreneurs to actualize their ideas and experience participation in the novel digital economy. With efforts and collaborations aimed at improving scalability, reducing gas fees, and accelerating transactions, the ICB blockchain is emerging as a powerful platform for developing DApps and innovative blockchain services. It continues to serve honorably as an efficient responsive platform in the digital world.

TEST NET

Network name : ICB Testnet

Network URL : https://rpc1-testnet.icbnetwork.info

Chain ID : 73114

Currency symbol : ICBT

MAIN NET

Network name : ICB Network

Network URL : https://rpc1-mainnet.icbnetwork.info

Chain ID : 73115

Currency symbol : ICBX

1. High-Throughput Consensus Mechanism

• Utilizes a Proof-of-Stake (PoS) variant, optimizing for high transaction throughput and minimal latency, akin to the efficiency seen in top-tier blockchain infrastructures.

2. Modular Network Design

• Employs a modular framework, allowing customization and scalability while maintaining core network integrity and performance.

3. Enhanced Security Protocols

• Integrates state-of-the-art cryptographic techniques and multi-layered security protocols, ensuring robust defense against cyber threats.

4. Interoperability and Cross-Chain Communication

• Facilitates seamless interoperability with various blockchain networks, enabling efficient cross-chain transactions and data exchange.

5. Smart Contract Functionality

• Supports advanced smart contract capabilities, enabling complex decentralized applications (dApps) and automated contract execution.

6. Energy-Efficient Operations

• Focuses on sustainability, adopting energy-efficient processes to reduce the network's environmental footprint.

7. Decentralized Governance Model

• Implements a decentralized governance structure, allowing community participation in decision-making and network upgrades.

8. Developer-Friendly Interface

• Provides a comprehensive set of developer tools and a user-friendly interface, simplifying the development and deployment of dApps.

9. Scalable Data Storage Solutions

• Incorporates scalable and secure data storage mechanisms, ensuring the safekeeping and accessibility of vast amounts of data.

10. Ecosystem Integration

• Offers broad ecosystem support, including integration with wallets, exchanges, and other blockchain services, enhancing user experience.

This technical overview underscores our commitment to delivering a state-of-the-art blockchain platform. By focusing on these key technical features, we aim to address the current challenges in blockchain technology while paving the way for future innovations.

In the ever-evolving landscape of blockchain technology, while there are numerous advancements, several critical challenges still need to be addressed. Understanding these challenges is key to developing more efficient, secure, and sustainable blockchain solutions.

Indeed, the Proof of Stake algorithm is a mechanism in the blockchain that validates transactions based on the amount of shares a person holds, rather than relying on miners' computing power. This algorithm offers many advantages but also has some disadvantages. Let's examine the disadvantages of the Proof-of-Work and Proof-of-Stake algorithms and consider an example:

Scalability and Efficiency

Transaction Throughput and Approval Delays

• PoW Limitations: Networks using Proof of Work (PoW) often face slow transaction processing rates and lengthy approval times, making them less suitable for high-volume systems.

• Energy Consumption: The energy-intensive nature of PoW consensus mechanisms not only impacts environmental sustainability but also adds to operational costs.

• Inability to process transactions when the number increases: This is usually related to scalability issues, which reduce the speed and efficiency of the network over time as the number of transactions increases.

• High fees and costs to operate on the network: To perform transactions or operate on the blockchain network, the associated fees and transaction processing costs may be high, which can be inconvenient for users.

• Public access to the network and the possibility of viewing transactions by anonymous people: Some blockchains may have security problems that lead to the disclosure of personal or sensitive information in transactions.

• Network Single Point of Failure (SPOF): The existence of weak points may cause a single point of failure that affects the entire network if it fails.

• High cost of miner preparation and activity in the network: Activity in some blockchain networks requires expensive equipment and high costs, which may be unacceptable for companies or individuals.

• Unnecessary competition of businesses for activities in the network: In some blockchain networks, unnecessary competition between companies for quotas in activities may lead to a waste of resources and energy.

Presenting the three main features of a blockchain: decentralization, security, and scalability.

Disadvantages of the Proof-of-Stake Algorithm:

• Slow Execution: One of the main disadvantages of the Proof-of-Stake algorithm is that the decision-making process for new transactions and blocks can be very slow. This issue arises from the need for the majority of shareholders to approve the production of a new block.

Example: Suppose a new transaction has been made in a Proof-of-Stake network and needs to be approved by the shareholders. If we have to wait for the approval of the majority of shareholders, it may take a longer time for the next block to be generated.

• Unwanted Centralization: In some implementations of the Proof-of-Stake algorithm, unwanted centralization can occur in the decision-making process for generating new blocks. This reduces trust and increases the concentration of power among a small number of entities.

Example: In a Proof-of-Stake network, individuals or companies that own the most shares have more decision-making power in the block production process. This may lead to an unwanted concentration of power and control in the network.

• Vulnerability to Attacks: The Proof-of-Stake algorithm is vulnerable to various attacks, such as 51% attacks and stock theft attacks.

Example: A 51% attack can occur when one person or group takes over the majority of the shares and then controls transactions, potentially destroying the network.

• Security Issues: While the Proof-of-Stake algorithm has some security advantages, it also has weaknesses. Security problems include various attacks such as delinquency attacks and attacks by selfish players.

Example: A delinquency attack may distort information or compromise the security of transactions. In such attacks, a person or group changes information to improve their situation, undermining the credibility and security of the network.

• Limitations Related to Share Distribution: The distribution of shares in the Proof-of-Stake algorithm can lead to disadvantages for the security and efficiency of the network. Excessive concentration of shares in one entity's hands can slow the decision-making process and increase the risk of 51% attacks.

Example: If one person or group holds the majority of shares in a Proof-of-Stake network, they may control the decision-making process and the selection of new blocks.

• Scalability Issues: One of the significant challenges the Proof-of-Stake algorithm may face is scalability. As the number of users and transactions increases, the algorithm may struggle with processing and decision-making speed.

Example: When the number of users and transactions in a blockchain network grows significantly, the time required to validate transactions and select new blocks increases, reducing the network's efficiency and usability.

• Administration Issues: Managing a large blockchain network that uses a Proof-of-Stake algorithm can present challenges. These include decisions related to protocol changes, technical repairs, and choosing appropriate platforms for the network.

Example: Deciding on an important protocol change in a blockchain network can be contentious. Additionally, selecting the right technical platforms for the network may cause problems due to technical and management complexities.

• Cost and Economic Issues: Implementing the Proof-of-Stake algorithm may incur costs related to network operations and algorithm implementation. These costs may include high energy consumption for computing, network maintenance, and upgrade costs.

Example: Computation and execution of the Proof-of-Stake algorithm may require significant energy consumption, especially in large networks. This energy consumption increases the costs associated with running the network and may not be economical for some users.

• Privacy Issues: Maintaining the privacy of transactions and user information is a fundamental challenge in the Proof-of-Stake algorithm. This can cause users to worry about the security and privacy of their information.

Example: If transactions are publicly available and their information is easily traceable, this can lead to privacy violations and increased risks associated with the misuse of information.

By addressing these problems and challenges and providing appropriate solutions within the ICB blockchain, it is possible to improve the efficiency and security of the Proof-of-Stake algorithm in blockchain networks.

Data Management

Challenges in Blockchain Ledger Storage

• Growing Size: As the blockchain ledger expands, it becomes increasingly difficult to sync and store, particularly on devices with limited storage capacity.

Security and Privacy

Vulnerabilities and Data Concerns

• Attack Risks: Despite their security advantages, blockchains are susceptible to 51% attacks, double-spend issues, and smart contract vulnerabilities.

• Privacy Issues: The immutable nature of blockchain transactions can lead to privacy risks, especially in handling sensitive data.

Interoperability and Standardization

The Need for Seamless Integration and Uniformity

• Cross-Chain Limitations: The lack of interoperability among different blockchain networks hinders the development of cross-chain applications.

• Standardization Gap: A lack of uniform standards in consensus algorithms, smart contract languages, and governance models poses challenges for broader adoption.

User Experience and Adoption

Overcoming Technical and Regulatory Barriers

• Complex Technology: The intricate technical nature of blockchain can be daunting for new users and hinder mainstream adoption.

• Interface Design: Many blockchain applications struggle with user-friendly interfaces, making them less accessible to a broader audience.

• Regulatory Uncertainty: Navigating the evolving regulatory landscape remains a significant challenge for businesses and developers in the blockchain space.

Environmental Sustainability

Addressing the Ecological Impact

• High Energy Requirements: The substantial energy needs of PoW consensus methods raise concerns about blockchain's environmental footprint.

• Electronic Waste: The demand for specialized hardware contributes to a rise in electronic waste, exacerbating environmental pollution.

Proof of Stake (PoS) Explained

PoS stands for Proof of Stake, a blockchain consensus mechanism that combines elements of both Proof of Stake (PoS) and Proof of Work (PoW) to achieve faster transaction speeds, lower energy consumption, and more efficient governance. Here's how it works:

1. Token Staking: PoS participants stake their tokens to secure the network. Staking involves locking up a portion of your tokens in a smart contract, essentially indicating your commitment to the network's stability.

2. Block Production: Block producers compete to create the next block on the blockchain. This competition can involve solving cryptographic puzzles (similar to PoW) or using an alternative consensus algorithm depending on the specific PoS implementation.

3. Rewards: Block producers who successfully create blocks receive rewards in the form of newly minted tokens or transaction fees. This incentivizes them to act honestly and maintain the network's security.

Advantages of PoS:

• Faster Transaction Speeds: PoS eliminates the need for all stakers to participate in consensus, leading to faster block times and higher transaction throughput compared to standard PoS.

• Lower Energy Consumption: PoS avoids the energy-intensive mining process of PoW, making it a more sustainable and environmentally friendly option.

• Improved Governance: Voting allows for more direct participation in network governance, potentially leading to faster decision-making and increased community involvement.

• Scalability: PoS has the potential to scale efficiently as the network grows due to its limited number of block producers.

Blockchain technology is constantly changing and growing, and it's always exciting to see new projects that have the potential to completely transform industries and change the way we interact with the digital world. Out of all these options, the ICB Network is particularly notable for being a dynamic and innovative initiative that operates on a Proof of Stake (POS) consensus mechanism.

A Paradigm Shift through POS

POS, which stands Proof of Stake, is the foundation of the consensus mechanism used by the ICB Network. POS is different from traditional Proof of Work (POW) systems because it is more efficient and scalable. POW systems can consume a lot of energy and be slow, but POS provides a better solution.

Here's how POS works:

• Token Holders Hold the Power: Instead of having everyone validate transactions, token holders choose delegates to carry out this important task on their behalf. Assigning authority to a delegation promotes a smoother and more efficient process.

• Faster Transactions, Higher Efficiency: POS is designed to have faster transaction confirmation times and higher throughput compared to POW systems because it limits the number of validators.

• Environmentally Friendly Choice: POS greatly reduces the amount of computational power needed for consensus, which in turn lowers the network's energy consumption and makes it a more environmentally friendly option.

• Enhanced Security: POS, or Proof of Stake, is a system where elected delegates are responsible for governing the network. These delegates have a personal stake in the success of the network, which motivates them to make responsible decisions. This approach not only encourages responsible decision-making but also enhances the overall security of the system.

Unpacking the ICB Network Architecture

The architecture of the ICB Network is designed to make sure it is as efficient, scalable, and secure as possible. The system is made up of several important parts that function together smoothly

1. ICB Chain: The core of the network is like a secure and unchangeable blockchain ledger. It keeps a permanent record of all transactions and data. Every block in the chain is built on top of the one before it, which means that it forms a clear and trustworthy record of all the activity that has taken place on the network.

2. ICB Token: The ICB Token, the network's native token, has several uses. It powers transactions, encourages staking, which encourages involvement in network governance, and makes a variety of dApps developed on the ICB Network easier to use.

3. Delegates: These people, who are chosen by token holders, are essential to the network's functionality since they validate transactions and maintain the ICB Chain's integrity. The selection procedure is intended to guarantee that this duty is only given to capable and reliable people.

4. Smart Contracts: These bits of code, which are located on the ICB Chain, allow decentralized apps (dApps) to be developed. These dApps enable users to engage with the network in novel ways, automate intricate procedures, and enable safe transactions.

Unleashing Potential across Industries

The POS consensus mechanism of the ICB Network is strong, and its adaptable architecture allows for a wide range of potential applications in different industries. Let's examine a few crucial areas where the ICB Network can completely transform our daily operations:

1. Supply Chain Management: Envision a society in which supply networks exhibit complete transparency and traceability. Businesses can be empowered by the ICB Network to trace materials and goods in real-time, ensuring authenticity, thwarting counterfeiting, and streamlining logistics.

2. Financial Services: A new age in financial services could be ushered in by the ICB Network. Imagine fractional ownership of assets, safe and effective cross-border payments, and creative DeFi solutions. There are countless options.

3. Data Management: Manage and distribute sensitive data in a transparent and fully controlled manner. By offering a decentralized and impenetrable platform for managing sensitive data, the ICB Network has the potential to completely transform the data management industry.

4. Identity Management: Provide people with self-sovereign identity solutions to empower them. Users will have more control over their personal data and be able to engage seamlessly across several online platforms with the help of the ICB Network, which can enable safe and verifiable digital identities.

5. And Beyond: The ICB Network has a wide range of potential uses that are always changing. We can anticipate even more ground-breaking and inventive ideas to emerge as the project develops and flourishes, changing many facets of our life.

A Future Brimming with Possibilities

The ICB Network is actively progressing through its roadmap, with a clear vision for the future. Key milestones include:

• Mainnet Launch: Unleashing the full potential of the network by enabling the deployment of dApps and facilitating widespread adoption.

• Community Building: Fostering a vibrant and engaged community of developers, users, and stakeholders to drive innovation and collaboration.

• Expanding Horizons: Continuously exploring new industries and developing solutions that address critical challenges across various sectors.

The ICB Network is not just a blockchain project, it goes beyond that. It serves as a catalyst for bringing about change. The ICB Network has a POS-powered architecture, which means it has a system in place to ensure efficient and secure operations. This network has a wide range of potential applications, making it versatile and adaptable to various needs. Additionally, the ICB Network benefits from a dedicated development team that is committed to making a positive and meaningful impact on the world. As it keeps developing and expanding, we can anticipate it playing a significant part in shaping a future that is more secure, transparent, and efficient for everyone.

When you use our services, personal information about you is collected, used, and protected by ICB Network This is explained in this privacy policy (the "Policy"). You accept this Policy by using the Project.

Scope

All personal data gathered by the Project is covered by this policy, including: Details that you voluntarily supply, including your name, email address, and wallet address. Device information, transaction history, and IP address are examples of automatically gathered data. Data That We Gather

We might gather the personal data listed below: Name, email address, wallet address, and any other information that can be used to identify you personally are examples of identifying information.

Transaction data: Details about the transactions you've made on the Project, such as the sums you paid and the dates they were completed, together with any associated metadata.

Device information: Details about your device, including its identifiers, operating system, and type of browser.

Usage data: Details on your usage of the project, including the sites you visit, the features you utilize, and the amount of time you spend working on it. How Your Information Is Used by Us

We make use of your data to: Supply and uphold the Project. Handle transactions and keep the blockchain ledger updated. Enhance the functionality and features of the project. Make your experience unique. Talk to you regarding the Project. Provide promotional and marketing materials to you (with your permission).

We might divulge your details to: outside service providers who help us deliver the Project. agencies of law enforcement or other governmental bodies as mandated by legislation. others with your permission. Data Preservation If a longer retention period is mandated or allowed by law, we will keep your information for as long as it takes to achieve the goals stated in this policy.

Your Right to Privacy

About your personal information, you are entitled to the following rights:

the ability to view your personal data. the ability to have any inaccurate information about you corrected. the ability to ask that your information be deleted. the ability to object to how your information is processed. the ability to limit how your information is processed. the freedom to transfer data. Safety Procedures

We implement security protocols to safeguard your confidential data, such as:data that is sensitively encrypted. safe keeping of data. Authorization protocols and access controls. routine examinations of security. Modifications to this Policy

This Policy may be revised from time to time. If there are any significant changes, we'll let you know by updating the Policy and publishing it on the Project website.

Get in touch with us

For any inquiries concerning our Policy, kindly reach out to us at support@icb.network.