CN111506932A

CN111506932A - Block chain calculation uplink implementation method

Info

Publication number: CN111506932A
Application number: CN202010559698.6A
Authority: CN
Inventors: 吴文杰; 李学生; 董政
Original assignee: Hainan Anmaiyun Network Technology Co ltd
Current assignee: Hainan Anmaiyun Network Technology Co ltd
Priority date: 2020-06-18
Filing date: 2020-06-18
Publication date: 2020-08-07

Abstract

The invention discloses a block chain calculation uplink implementation method, which is used for determining calculation data of a third-party digital asset and exchanging values between a calculation provider and a user; the data acquisition and processing module needs to apply a cross-chain technology, receive computing power output and map the output computing power data on a chain; and the calculation power provider accesses the block chain through the intelligent contract, and transfers the calculation power output to the output pool day by day after the block chain is accessed. The intelligent contract verifies the effectiveness of the computing power through the daily output receiving condition and distributes output computing power data to computing power supplier accounts; the calculation power supplier can sell the income right in a certain period to the calculation power buyer through the calculation power trading intelligent contract, and the income right uses the stable coin on the chain to settle accounts. The invention fuses the digital asset computing power ecology by applying the regional chain technology, introduces the computing power holder rights and interests into the consensus mechanism to ensure the chain safety, further expands the digital asset ecology by using the technologies such as intelligent contracts, cross-chain and the like, and realizes the application scenes such as high-concurrency quick payment and the like.

Description

Block chain calculation uplink implementation method

Technical Field

The invention relates to the field of block chains, in particular to a block chain computational uplink implementation method.

Background

With the development of the main chain-parallel chain mechanism, more users expect that parallel chains can also support privacy transactions. Common privacy transactions include ring signatures, zero knowledge authentication, and DASH; the ring signature and the DASH only support transfer transactions, and the requirement of a user for privacy protection of various types of transactions cannot be met; zero-knowledge authentication is not suitable for client to construct private transactions due to huge resource consumption; moreover, the three kinds of privacy transactions cannot be supervised, and legal entities cannot protect individuals under necessary conditions. Therefore, a block chaining method is needed to effectively solve the above problems.

Disclosure of Invention

The present invention provides a method for implementing block-linked computational uplink,

in order to achieve the purpose, the technical scheme adopted by the invention is as follows:

the invention comprises the following steps:

determining the calculation data of the third-party digital assets, wherein the calculation data is used for value exchange between a calculation supplier and a user;

b, the data acquisition and processing module needs to apply a cross-chain technology, receive computing power output and map the output computing power data on a chain;

c, the calculation power provider accesses the block chain through the intelligent contract, and after the block chain is accessed, the calculation power output is transferred to the output pool day by day. The intelligent contract verifies the effectiveness of the computing power through the daily output receiving condition and distributes output computing power data to computing power supplier accounts;

and D, the calculation power supplier can sell the income right in a certain period to the calculation power buyer through the calculation power transaction intelligent contract, and the income right uses the stable coin on the chain to settle accounts.

Furthermore, the intelligent contract is a rule which ensures flexible adjustment of the demand of the computing power during the DR event in a programmed mode, calculation of the incentive and penalty rate related to the response users and balance of the demand of the computing power and production, the generation of the intelligent contract triggers the start of the DR event transaction of both node users, the reasonable price of the DR event trigger period is automatically determined through real-time power quotation issued by each node user in the block chain, fund transfer is completed, and the transaction is completed.

Furthermore, the transaction funds are locked in the intelligent contract to be used as the guarantee fund, the fund is gradually unlocked along with the yield, and after the profit right is sold, the yield and the yield data are directly sent to the cost buyer through the intelligent contract until the contract period is finished.

Further, the verification server obtains a storage request of the blockchain client to obtain a data strip; inquiring the existing record to judge whether the data of the block exists, and if so, ignoring the data; the verification server verifies the historical data in the data strip, confirms the validity and the correctness of the serial number and sends a verification result to other verification nodes; after the verification is successful, writing the data strip into a corresponding block chain in the block chain system; and entering the next consensus for the data strip which does not meet the requirement until the consensus is completed or the time is out.

Further, the intelligent contract calculates the total demand response amount, formulates a demand response scheme and a demand response rule signal, and starts a DR event, wherein the content of the DR event comprises the total amount value of the adjustment power response and the related power increment financial subsidy and incentive price of the user in the adjustment time period.

A system for blockchain computational uplink implementation comprising a computational server implementing blockchain data storage and at least one computational gateway communication; the computing gateway is communicated with at least one edge data acquisition and processing module; the data acquisition and processing module: the module realizes the functions of computing power data acquisition, computing and storing and data forwarding and receiving; the calculation force data acquisition function realizes the acquisition of calculation force information through various sensors, and the data forwarding and receiving function transmits and receives information sent by a gateway through the transaction node by using the packaged data; the computing gateway is used for receiving the acquisition command from the server end and outputting the acquisition command to the computing gateway for receiving the data acquisition and processing module, and receiving the data from the computing gateway for receiving the data from the acquisition and processing module and forwarding the data to the server. A server side: the computational power data in the preset data format sent by the edge acquisition and processing module is stored in the block chain database, and later retrieval and display are facilitated.

A computer apparatus comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing a block-chaining computational-link implementation method when executing the computer program.

A computer readable storage medium storing a computer program for performing a method for block-chaining computational uplink implementation.

Compared with the prior art, the invention has the following beneficial effects:

the invention fuses the digital asset computing power ecology by applying the regional chain technology, introduces the computing power holder rights and interests into the consensus mechanism to ensure the chain safety, further expands the digital asset ecology by using the technologies such as intelligent contracts, cross-chain and the like, and realizes the application scenes such as high-concurrency quick payment and the like.

Drawings

Fig. 1 is a flowchart of a method for implementing block-link computational uplink.

Detailed Description

The present invention is further illustrated by the following examples, which are intended to be in a manner including, but not limited to, the following examples.

The invention comprises the following steps:

The intelligent contract is a rule which ensures that the calculation power is flexibly adjusted during the DR event in a programmed mode, calculates the incentive and penalty rate related to the response users and balances the calculation power demand and production, the generation of the intelligent contract triggers the start of the DR event transaction of both node users, the reasonable price of the DR event trigger period is automatically determined through the real-time power quotation issued by each node user in the block chain, the fund transfer is completed, and the transaction is completed.

The transaction fund is locked in the intelligent contract and used as the guarantee fund, the fund is gradually unlocked along with the yield, after the profit right is sold, the yield and the yield data every day are directly sent to the buyer of the yield through the intelligent contract until the contract period is finished.

The verification server obtains a storage request of a block chain client to obtain a data strip; inquiring the existing record to judge whether the data of the block exists, and if so, ignoring the data; the verification server verifies the historical data in the data strip, confirms the validity and the correctness of the serial number and sends a verification result to other verification nodes; after the verification is successful, writing the data strip into a corresponding block chain in the block chain system; and entering the next consensus for the data strip which does not meet the requirement until the consensus is completed or the time is out.

The intelligent contract calculates the total demand response amount, formulates a demand response scheme and a demand response rule signal, and starts a DR event, wherein the content of the DR event comprises the total value of the adjustment calculation power response and the related calculation power increment financial subsidy and incentive price of the user in the adjustment time period.

In the structure, the equity and the BHP holder equity are bound and restricted with each other, and the transfer of the digital asset equity credit to the BHP public link is realized.

Digital assets have many unique attributes that are likely to address some of the reachability and trustworthiness issues. Distributed governance is included to ensure that no single agent controls the network; open access allows anyone to participate through an internet connection; and an encryption security mechanism to protect the integrity of the funds. But existing research and attempts have not addressed the shortcomings of the current digital asset networks, and thus their actual value and trading media have been less than satisfactory to date. The BHP is supported on the basis of force calculation, and a better mode is found for solving the defect of the force calculation network of the digital assets.

And the calculation is taken as the bottom-layer asset of the digital asset ecology, and is the basis of the credit of the digital asset. Computing power is an extremely valuable asset, and the development of the computing power to the present now forms rich ecology of ore machine manufacturers, mine fields, mine ponds, computing power purchase and lease and the like, and is an extremely important ring in digital asset ecology. Meanwhile, the calculation power holder invests a large amount of assets to maintain the calculation power, the own benefits of the calculation power holder are closely related to the digital assets, and the calculation power holder is the most faithful champion of the digital assets. This makes it possible to create a secure distributed payment system with digital asset credit.

Therefore, the BHP public link integrates the digital asset computing power ecology by using a block chain technology, introduces the rights and interests of computing power holders into a consensus mechanism to ensure the safety of the link, further expands the digital asset ecology by using technologies such as intelligent contracts and cross-links, realizes application scenes such as high-concurrency quick payment, and creates a digital asset-based DeFi ecological system.

BHP pays for the network built on the Akka concurrency framework based on the Actor model. The Actor interacts by sending information to each other. The thread executing the task is not passed through the information to the receiver, and one Actor entity can continue to run other tasks without being blocked after sending the information. The Actor model can do more work in the same time. An Actor processes messages in a sequential manner, one message at a time, and the sender and recipient of the message can operate independently without interference. This way of operation avoids the damage to the object encapsulation by multiple threads concurrently in conventional multi-threaded programming.

(1) Decoupling the execution by means of signaling, maintaining the encapsulation of objects (method calls passing execution environment, but message passing does not)

(2) The internal state of the Actor can only be changed by passing messages and only one message will be processed at a time, which eliminates the problem caused by thread contention in conventional programming.

(3) The message sender is not blocked. Millions of actors can be efficiently arranged across multiple threads. This fully leverages the potential of modern CPUs. Task delegation through messaging is a common mode of operation for the Actor model.

In addition, the BHP public link has also established a BHP alliance with dominant enterprises in various fields, and provides a basic guarantee for creating a digital asset computing credit-based distributed financial network with sustainability, security, and trusted framework.

The above-mentioned embodiment is only one of the preferred embodiments of the present invention, and should not be used to limit the scope of the present invention, but all the insubstantial modifications or changes made within the spirit and scope of the main design of the present invention, which still solve the technical problems consistent with the present invention, should be included in the scope of the present invention.

Claims

1. A method for implementing block-linked computational uplink, comprising the steps of:

2. The method of claim 1, wherein the intelligent contract is a rule for ensuring flexible adjustment of the demand of the computing power during the DR event in a programmed manner, for participating in response to the incentive and penalty rate calculation related to the users, and balancing the demand of the computing power and the production, the generation of the intelligent contract triggers the start of the DR event transaction between the node users, and the transaction is completed by automatically determining a reasonable price of the DR event trigger period through real-time power quotations issued by each node user in the block chain and completing the transfer of funds.

3. The method of claim 1, wherein the transaction funds are locked in a smart contract as a margin, and wherein as the yield is gradually unlocked, the yield data is directly sent to the yield buyer via the smart contract after the yield right is sold until the end of the contract period.

4. The method of claim 1, wherein the verification server obtains a storage request from a blockchain client to obtain a data bar; inquiring the existing record to judge whether the data of the block exists, and if so, ignoring the data; the verification server verifies the historical data in the data strip, confirms the validity and the correctness of the serial number and sends a verification result to other verification nodes; after the verification is successful, writing the data strip into a corresponding block chain in the block chain system; and entering the next consensus for the data strip which does not meet the requirement until the consensus is completed or the time is out.

5. The method of claim 1, wherein the smart contract performs a total demand response calculation, generates a demand response scheme and demand response rule signal, and initiates a DR event, wherein the DR event comprises adjusting the total value of the demand response and the associated value-added financial subsidy and incentive price for the user during the adjustment period.

6. A system for blockchain computational uplink implementation comprising a computational server implementing blockchain data storage and at least one computational gateway communication; the computing gateway is communicated with at least one edge data acquisition and processing module; the data acquisition and processing module: the module realizes the functions of computing power data acquisition, computing and storing and data forwarding and receiving; the calculation force data acquisition function realizes the acquisition of calculation force information through various sensors, and the data forwarding and receiving function transmits and receives information sent by a gateway through the transaction node by using the packaged data; the computing gateway is used for receiving the acquisition command from the server end and outputting the acquisition command to the computing gateway for receiving the data acquisition and processing module, and receiving the data from the computing gateway for receiving the data from the acquisition and processing module and forwarding the data to the server. A server side: the computational power data in the preset data format sent by the edge acquisition and processing module is stored in the block chain database, and later retrieval and display are facilitated.

7. A computer apparatus comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, wherein the processor implements the block chaining computational uplink implementation method of any one of claims 1 to 5 when executing the computer program.

8. A computer-readable storage medium storing a computer program for performing the method of block-chaining computational uplink implementation according to any one of claims 1 to 5.