KR101937090B1 - Method of verifying block based on block chain - Google Patents

Abstract

A block-chain-based block verification method is provided that limits the number of nodes that generate a block, while ensuring integrity of the block even if 51% is contaminated. A block-chain-based block verification method includes the steps of (i) sequentially generating blocks by a plurality of representative nodes having authority to generate blocks constituting a block chain according to a block generation order; (ii) randomly selecting at least one of a plurality of common nodes; And (iii) adding the randomly selected at least one general node between a plurality of representative nodes of step (i) or after the last representative node to generate the block.

Description

[0001] METHOD OF VERIFYING BLOCK BASED ON BLOCK CHAIN [0002]

The present invention relates to a method for verifying a block of nodes in a block chain, more specifically, to a method for verifying a block by using a block-chain-based graphen engine verification method, a DPOS (Delegated Proof of Stake) And a method for verifying a combination of the existing block verification and the newly added verification.

The block chain technology began with the advent of bit coin currency in 2008, and a number of cryptographic coins have since been released that complement the technology. Most of the coins made in the early days are PoW (Proof of Work) method, literally meaning work enhancement. If you do not use industrial electric power, block generation through hash power will result in too much electricity charge compared to the amount of mining. There is a drawback to purchase. The block-chaining technique used in the bit coin has many nodes for generating blocks. In order to recognize the generated block, many new blocks are generated after the block, and the connection should be made. This means that it takes a lot of time for a transaction to be acknowledged by being written to the block, and it is also possible to easily manipulate the contents of a block in a group with more than 51% block generation power.

The PoS (Proof of Stake) method is called PoE (Proof of Stake) and it is advantageous to reduce the cost compared to PoW. However, since the individual has to turn the server and mined, it does not participate in the mining unless the majority shareholder or the high rate is high. Do not. In order to compensate for this, the graphen engine DPOS (Delegated Proof of Stake) method is used to limit the number of nodes that generate blocks and to generate blocks one at a time in a randomly generated order. Time was shortened.

However, since the number of nodes is predetermined and not large, it is likely that more than 51% of the nodes will be contaminated.

Patent Registration No. 10-1727525 {Registered Date: Apr. 11, 2017}

It is an object of the present invention to provide a block-chain-based block verification method that ensures the integrity of a block even if the number of nodes that generate the block is limited and 51% is polluted.

A block-chain-based block verification method according to the present invention includes the steps of: (i) sequentially generating blocks by a plurality of representative nodes having authority to generate blocks constituting a block chain according to a block generation order; (ii) randomly selecting at least one of a plurality of common nodes; And (iii) adding the randomly selected at least one general node between a plurality of representative nodes of step (i) or after the last representative node to generate the block.

The representative nodes may be determined at regular intervals through voting between member configurations, and the general nodes may not be authorized to generate the block with a copy of the block chain data, and may be a node that has been omitted from the determination of the representative nodes. Step (i) comprises: (i-1) determining a block generation order for a plurality of blocks; (i-2) starting the block generation by the representative nodes according to the block generation order determined in the step (i-1); (i-3) determining whether all of the representative nodes have generated a block; (i-4) proceeding to step (ii) if all of the representative nodes have generated a block; (i-5) returning to step (i-2) if one of the representative nodes does not generate the block. The block chain-based block verification method may further include a step of repeating the block generation procedure by randomly selecting a general node and leaving only a representative node if all blocks are generated once in a predetermined order.

A block-chain-based block verification method according to the present invention includes the steps of: (a) determining a block generation order for a plurality of blocks; (b) starting the block generation of the representative nodes according to the block generation order determined in step (a); (c) determining whether the representative nodes have all generated blocks; (d) randomly selecting at least one of a plurality of general nodes when all of the representative nodes have generated a block; (e) inserting the randomly selected at least one general node between the plurality of representative nodes to generate the block; And (f) generating a block once all in a predetermined order, leaving only the representative node and repeating the block generation procedure by randomly selecting the general node again.

 The present invention determines a block generation order by grouping representative nodes that generate blocks and randomly selected general nodes, and sequentially generates blocks in the determined order. If all the nodes have generated blocks in the specified order, we select random nodes again and set the block generation order with the representative nodes. Accordingly, in the present invention, randomly selected general nodes as well as predetermined representative nodes can generate a block, so that even if the representative node is contaminated or the common node is contaminated, 51% Integrity can be maintained.

1 is a block diagram of a general graphen engine.
FIGS. 2 and 3 are block diagrams for explaining an improved block according to the present invention.
4 is a flowchart illustrating a block-chain-based block verification method according to an embodiment of the present invention.

A block chain is a linked list that starts with the first block (Genesis Block) and has a link to the previous block. Since block chains are distributed and stored across multiple nodes, and blocks contain transaction information (transactions), the block chain, which is an aggregate of blocks, is a large distributed book containing all transaction information. In other words, a block is an element of a block chain and conceptually means a bundle of a plurality of transaction information (transactions). A block consists of a block header, transaction information, and other information.

Hereinafter, a block-chain-based block verification method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of a conventional graphen engine. In FIG. 1, representative nodes C, B, D, E and T are sequentially determined as blocks 10, 11, 12 and 13 , 14). A representative node is a node that is authorized to create a block constituting a block chain. The decision is made at regular intervals through voting among member members. A general node is a node that has a copy of the block chain data. In general, there is no authority to create a block and it is a node that is missing from the representative node selection.

FIGS. 2 and 3 are block diagrams for explaining an improved block according to the present invention. 2 and 3, the present invention creates a block together with a representative node by randomly selecting a few nodes among general nodes.

Hereinafter, a block-chain-based block verification method according to an embodiment of the present invention will be described with reference to FIG. 4 is a flowchart illustrating a block-chain-based block verification method according to an embodiment of the present invention.

A block generation order for a plurality of blocks is determined (step S402).

The representative nodes start block generation according to the block generation order determined in step S402 (step S404).

It is determined whether all of the representative nodes have generated a block (step S406).

If it is determined in step S406 that all of the representative nodes (representative node C, representative node B, and representative node E in FIG. 3) have generated a block, at least one of the plurality of general nodes, Two general nodes including a normal node G and a general node E are randomly selected (step S408).

The randomly selected at least one normal node is added between the plurality of representative nodes or next to the last representative node to generate the block (S410). Referring to FIG. 3, the normal node G may be added between the representative node B and the representative node E, and the common node E may be added after the last representative node E.

If there is a block to be generated one by one in the determined order, that is, if there is a block to be additionally generated (S412), the process returns to the step S402 and performs the following steps to leave only the representative node, And the block creation procedure can be repeated.

To summarize, if all the nodes that can generate a block generate a block once, it is necessary to determine the order in which to generate the block again. Then, the representative node and the selected general node are grouped together to determine the order of generating the block. If all blocks are created in the specified order, only the representative node is left, and the general node is randomly selected again, and the block generation procedure is repeated.

 To describe a block chain, it is a technique of grouping multiple records (eg transaction records) into one block when it is created, and then linking it with the previously created block and chain. In addition, the block-chain data has the same contents as all the nodes, thereby eliminating the risk of hacking. However, when several nodes of many nodes are contaminated and each node has different block-chain data, a longer-connected block chain is selected and connected. Accordingly, it becomes possible to manipulate block-chain data if a majority (51%) of exposed representative nodes are contaminated.

 However, when the present invention is applied, even if a large number of representative nodes are polluted, a block operated by a general node randomly selected every time is not connected for a long time, so that the integrity of the block chain can be maintained.

Claims (5)

(i) sequentially generating blocks by a plurality of representative nodes having authority to generate blocks constituting a block chain according to a block generation order;
(ii) randomly selecting at least one of a plurality of common nodes; And
(iii) adding said randomly selected at least one general node between a plurality of representative nodes of step (i) or after the last representative node to generate said block. 2. The method of claim 1, wherein the representative nodes are determined at regular intervals through voting between member configurations, and the normal nodes are not authorized to generate the block with a block-chain data copy, Block Chain Based Block Verification Method. The method of claim 1, wherein step (i)
(i-1) determining a block generation order for a plurality of blocks;
(i-2) starting the block generation by the representative nodes according to the block generation order determined in the step (i-1);
(i-3) determining whether all of the representative nodes have generated a block;
(i-4) proceeding to step (ii) if all of the representative nodes have generated a block;
(i-5) returning to step (i-2) if one of the representative nodes does not generate the block. The method of claim 1, further comprising: (iv) repeating a block generation procedure by randomly selecting a normal node only after leaving a representative node if all blocks are generated in a predetermined order. (a) determining a block generation order for a plurality of blocks;
(b) initiating block generation by representative nodes according to the block generation order determined in step (a);
(c) determining whether the representative nodes have all generated blocks;
(d) randomly selecting at least one of a plurality of general nodes when all of the representative nodes have generated a block;
(e) inserting the randomly selected at least one general node between the plurality of representative nodes to generate the block; And
(f) generating a block once in all the determined order, leaving only the representative node, and then repeating the block generation procedure by randomly selecting the general node.

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