WO2020169323A1 - Method for controlling a hardware system using a blockchain - Google Patents

Abstract

The method for controlling a hardware system using a blockchain is characterised in that a dynamisation of the blockchain is provided by moving the logic and parameters into the blocks on the blockchain itself and/or on a separate library chain, wherein the node software is declustered, the blocks are classified into types, and a container structure containing the logic and the parameters for the block processing method is added to the blocks. It is proposed to publish the abstract without a drawing.

Description

Method for controlling a hardware system using a blockchain

The invention relates to a method for controlling a hardware system using a blockchain.

background

The invention is a method with which dynamic

Database properties can be applied on a decentralized blockchain. Blockchains can either be forked or joined together by linking or referencing. They can be ended finally and

Data blocks can be deleted. This is made possible by de-clustering the procedural logic, declaring new block types and a proof-of-completion consensus. The previous use of the blockchain as a continuous add-only memory becomes a dynamic, decentralized database through the invention and opens up many new areas of application that were previously only possible with native database applications.

State of the art

In the known, static methods, in contrast to the invention, the following problems arise:

The main feature of a blockchain is the tamper-proof storage of data, in the form of continuous, coherent logging of a hash calculated using an algorithm. The blockchain has the

Property of an “add-only memory”, which allows any subsequent

Makes changing the data such as deleting or editing impossible. The

The main feature of a database-based application is the flexible handling of data. They can also be deleted or changed. As a consequence, this means that the properties of the blockchain and those of a database-based application are mutually exclusive. In its current form, the blockchain can only be used for very special areas of application in the form of permanent and continuous

consistent documentation, e.g. can be used for account management, notary tasks, ledgers, etc. The area of application of a blockchain in everyday life is therefore very limited.

The US 9 608 829 B2 shows a description of the well-known blockchain technology. In addition, the font describes a concept in which a Blockchain can be forked and in which logics and parameters for block processing called "rules" are kept in the blockchain itself.

US Pat. No. 9,608,829 B2 describes a blockchain that outputs so-called “slide chains”. These slidechains can have a different procedural logic than the blockchain from which they were extracted. Although the procedural logic is also written there in the first block of the slide chain, there - unlike in the present invention - the solution is not described via a separate library chain.

The connection between the outputting end of the blockchain and the beginning of the new slidechain is made both by a hash and a short hash, which must be written to the respective counterpart. This means that both ends are firmly connected to one another precisely at this connection. The consequence of this is that technical, write access to both chains must actually be possible. This creates the problem that foreign chains for which there is no write access cannot be connected.

Likewise, blockchain and slidechains can only ever be connected at one end, but never afterwards anywhere in the middle. In contrast to this, the connection can also be established by referencing in the present invention. As a result, in the present invention, any chain can be linked to any block of the chain by referencing. Write access to the external chain is not required. Only then is the flexible use of mixed infrastructures possible at all.

The most important point, however, is that both the blockchain and the slidechains are pure "add-only storage". Data cannot be deleted, it will be added forever. A "dynamic, decentralized database" (see the explanations above, page 1, lines 12 - 20 of the description, after the

Subheading “Background”) is therefore not possible at all, because a flexible database application requires not only writing data but also deleting and changing data. This is not possible without the new, individual block types and the proof-of-completion consensus.

Only in this way can the requirements of the EU GDPR, especially with regard to Art. 17 (right to be forgotten / erased), be met in a decentralized environment become. Only through the present invention can a flexible database management be realized in a public space and decentralized distribution at all. The present invention thus enables the creator of data or another authorized person to actually delete or change the data without violating the integrity of the blockchain itself.

Summary of the disadvantages of the known static methods

1. Narrowly limited area of application.

2. Long time until a new one is available and used

Block processing method.

3. When sharing a blockchain (fork), the network is also divided.

4. Computing power (hash power) of the

Network.

5. Non-controllable energy demand for block processing.

6. Limited production quantity in block production (scaling).

7. It is not possible to prevent new entries (no termination of the blockchain).

8. Stored data cannot be changed (add-only memory).

9. High storage space requirements from the overall increase in the blockchain history (fragmentation).

10. Required software change of the nodes after a fork.

11. Mandatory publicly transparent inspection of the source code.

12. Specified type of script or programming language.

13. No reliable and economically sensible prioritization of transactions.

14. No merging of existing blockchains.

15. Software with procedural logic can be manipulated.

16. Forks are only possible on the last block of a blockchain.

Problem and solution of the invention

Object of the invention: The above-mentioned disadvantages of the prior art are to be avoided. In a method for controlling a hardware system using a blockchain of the type mentioned at the outset, this object is achieved according to the invention in that the blockchain is made dynamic by shifting the logic and Parameters are provided in the blocks on the blockchain itself and / or on a separate library chain by declassifying the node software, classifying the blocks into types and expanding the blocks by a

Container structure, which contains the logic and parameters for the

Contains block machining processes.

All writing and deleting processes, compliance with all for

The time the order is placed, the applicable rules and any changes to the

Blockchain infrastructures are monitored and ensured via a proof-of-completion consensus.

Advantages of the invention

With the invention of the dynamic method, the following problems are solved or the following advantages are achieved:

The architecture of the blockchain and its infrastructure was changed so that the properties of the blockchain, together with the properties of a database-based application, can be mapped directly on the blockchain or via a separate library chain. Smart block types contain all of the processing logic. You can have a different consensus mechanism from the data blocks. Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. As a result, a wide range of new

Areas of application for the secure, decentralized storage and management of data in industry and for everyday purposes with an attractive cost-benefit factor.

Thanks to the proof-of-completion consensus, these properties and compliance with all rules applicable at the time the order is placed can also be ensured on a public and decentralized blockchain infrastructure.

Summary of the advantages of the method according to the invention

1. Broad spectrum of new areas of application.

2. Immediate provision and use of a new processing method.

3. Fork-resistant, cross-blockchain network.

4. Computing power dynamically distributed across all blockchains (hash power). 5. Energy demand adapted to requirements.

6. Variable production quantity in block production (scaling).

7. Final termination of a blockchain.

8. Entries can be deleted and changed.

9. Lower storage space requirements for selected blockchain sections

(Defragmentation).

10. It is not necessary to change the node software in the event of process changes.

11. Outsourcing of processes in non-public areas.

12. Free choice of script or programming language.

13. Reliable and economically sensible prioritization of transactions.

14. Merging of existing blockchains.

15. Software with procedural logic tamper-proof.

16. Forks possible at any time on any block.

These advantages are achieved through the following process steps Advantage 1 - Wide range of new areas of application achieved through the following process steps:

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source posts a task as a transaction in the transaction pool. 5. She selects transaction: fork, merge, quit, delete, inform or save.

6. A node fetches a transaction from the transaction pool.

7. Creation and appending of an intelligent block by a privileged node.

8. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion

Consensus.

9. Storage of rights, logic and parameter definitions by privileged nodes. Conclusion: Through the use of intelligent block types, in addition to the previous, narrowly defined area of application of a blockchain, namely the storage of data as secure add-only memory, a wide range of new areas of application is available opened up. They contain the entire processing logic and can have a consensus mechanism that is different from the data blocks. Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. The topicality and the

Authenticity and compliance with all rules applicable at the time the order is placed are ensured by a proof-of-completion consensus. Tasks such as forking, merging, terminating, deleting and informing are thus immediately possible.

Advantage 2 - Immediate use of a changed processing method.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Ensuring up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed through the use of a proof-of-completion consensus.

6. Including new logic and parameter definitions on the fly

Processing.

7. Immediate application of the new logic and parameter definitions.

Conclusion: Changes to the logic and parameter definitions are immediately available to the nodes and can be used immediately to edit the following blocks.

Advantage 3 - Fork-resistant. the cross-blockchain network.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain). 5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof of completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

Conclusion: The network is retained because the nodes no longer have to decide which blockchain (fork) they will process exclusively for in the future. You can opt for multiple blockchains at the same time because you have instant access to the logic and parameter definitions. For faster processing, the nodes can internally keep a library with the various logic and parameter definitions of the individual blockchains for immediate availability.

Advantage 4 - computing power dynamically distributed over all blockchains (hash power)

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof of completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

9. Utilization, ownership or reward related priorities in the

Block processing. Conclusion: The computing power of the entire network can be used for all blockchains (forks). Depending on the workload and the number of transactions for a

Blockchain, the available computing power can be used optimally. Standstill or waiting times are avoided. Decisions can e.g.

Be utilization, ownership or reward dependent.

Advantage 5 - energy demand adapted to requirements.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

9. Block processing priorities subject to ownership or authority.

Conclusion: Purpose-adapted processing parameters (e.g. lower

Difficulty) reduce the computing effort. Tasks or parts of them can be outsourced to privileged nodes in a protected environment. As a result, the energy requirement is reduced. This is

environmentally friendly and saves costs.

Advantage 6 - Variable scaling of the amount of block production.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers. 3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

9. Block processing priorities subject to ownership or authority.

Conclusion: The purpose-adapted processing as well as the outsourcing of tasks or their subareas to privileged nodes in a protected environment reduces the computing effort. The saved computing capacity is available for other tasks. More tasks can be processed in the same time. This increases production.

Benefit 7 - Final termination of a blockchain.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions. 9. Block processing priorities subject to ownership or authority.

10. A data source posts a transaction to the transaction pool for termination.

11. Ensuring up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

12. A privileged node fetches a transaction from the

Transaction pool.

13. Put an end block at the end of a blockchain.

14. Storage of information.

Conclusion: An end block can be added to the end of a blockchain. This prevents the addition of new blocks. The chain is now closed. The end block can contain information in a container. Processes can thus be finalized. Completed processes no longer have to be taken into account for ongoing processes. This saves memory and computing capacity.

Advantage 8 - Entries can be deleted and changed.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Including new logic and parameter definitions on the fly

Processing.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Immediate application of the new logic and parameter definitions.

8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

9. Block processing priorities subject to ownership or authority.

10. A data source posts a transaction for deletion in the transaction pool. 11. A privileged node fetches a transaction for deletion from the

Transaction pool.

12. Ensuring up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed through the use of a proof-of-completion consensus.

13. Delete the blocks contained in the delete transaction.

14. Storage of information.

Conclusion: data that should optionally be deleted are stored on a separate

Blockchain outsourced. This blockchain is marked as deletable in its limb block or an independent blockchain (library chain). After deletion, this data area can optionally be written again or finally closed by an end block before further writing. The up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed are ensured by a proof-of-completion consensus. This enables, among other things, the "right to be forgotten" from the EU GDPR to be implemented. An info file can explain the reason for the deletion (e.g. personal data on

Customer request deleted).

Advantage 9 - space requirement only for selected blockchain sections.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source posts a transaction for forking into the transaction pool.

5. A privileged node fetches a transaction from the transaction pool for fork.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain). 10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

12. Storage of the history for the new blockchain.

Conclusion: Tasks are outsourced in independent chains. Only the path from the historical beginning of the chain to the current most recent block is required for the task (Figure 10). All other tasks on the blockchain are not relevant to the outsourced task. This minimizes the storage space at the nodes. A full node feature with a task history is guaranteed.

Advantage 10 - it is not necessary to change the node software when the process changes.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source posts a transaction for forking into the transaction pool.

5. A privileged node fetches a transaction from the transaction pool for fork.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

Conclusion: There is no need to replace or update the node software, because the logic and parameter definitions are obtained directly from the superordinate limb block of the block to be processed or from a block of an independent blockchain (library chain) by the declassified node software. The nodes For faster processing, you can internally keep a library with the various logic and parameter definitions of the individual blockchains for which you want to process, for immediate availability.

Advantage 11 - outsourcing of processes to areas that are not open to the public.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source posts a transaction for forking into the transaction pool.

5. A privileged node fetches a transaction from the transaction pool for fork.

6. Ensuring the topicality and authenticity as well as compliance with all the

Time of placing the order according to the applicable rules through the use of a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions, interface to external systems.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

Conclusion: Sub-processes can optionally be transferred to external areas (black box) during block processing. The results of the external processing can optionally be returned to the block processing process as processing parameters. The processing process within the external area is not publicly visible (black box).

Advantage 12 - Free choice of script or programming language.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers. 3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source posts a transaction for forking into the transaction pool.

5. A privileged node fetches a transaction from the transaction pool for fork.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions with scripts in different languages.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

Conclusion: A software choice adapted to the hardware and purpose leads to optimized production results. Middleware between different script and

Programming languages are not required. This is economical and makes the overall system less prone to errors.

Advantage 13 - Reliable and economically sensible prioritization of transactions.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

5. Ensuring up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed through the use of a proof-of-completion consensus.

6. Including new logic and parameter definitions on the fly

Processing.

7. Immediate application of the new logic and parameter definitions. 8. Parallel processing of blockchains using appropriate logic and

Parameter definitions.

9. Utilization, ownership or reward related priorities in the

Block processing.

Conclusion: privileged nodes that e.g. can be owned by a data source, always process their own transactions first. If there is free capacity, they use their computing power, e.g. available to other blockchains for a fee. From an economic point of view, this can result in a cost-neutral node operation or even a further source of income.

Advantage 14 - Merging of existing blockchains.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source represents a transaction to be merged into the

Transaction pool.

5. A privileged node fetches a transaction from the transaction pool for merging.

6. Ensuring the topicality and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions with references.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

12. Storage of the history for the new blockchain and its references.

Conclusion: By merging any blockchains at any data blocks, blockchains outside of the network access can also be accessed with external Technologies become referential. This means that supply chains and manufacturing processes can be clearly documented across all suppliers.

Advantage 15 - software with procedural logic tamper-proof.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in optional containers of the blocks on the blockchain itself or on an independent blockchain (library chain).

4. A data source represents a transaction for a new procedure in the

Transaction pool.

5. A privileged node fetches the transaction for the new procedure from the

Transaction pool.

6. Ensuring the topicality and authenticity as well as compliance with all the

Time of placing the order according to the applicable rules through the use of a proof-of-completion consensus.

7. Creation and appending of a limb block by a privileged node.

8. Storage of rights, logic and parameter definitions.

9. Nodes access new logic and parameter definitions directly from the blocks on the blockchain or from an independent blockchain (library chain).

10. Including new logic and parameter definitions on the fly

Processing.

11. Immediate application of the new logic and parameter definitions.

Conclusion: The procedural logic is an integral part directly on the blockchain or in an independent blockchain (library chain). It belongs to the data of a genesis block, a limb block or a merge block or any data block on the blockchain itself or on an independent blockchain (library chain) and is used together with the start value for hash calculation of the

Final value used in these blocks. Any manipulation of it inevitably leads to a recognizable inconsistency of the blockchain.

The timeliness and authenticity as well as compliance with all the

The time of placing the order according to the applicable rules is ensured by means of a proof-of-completion consensus. Advantage 16 - Forks possible at any block at any time.

1. De-clustering of the node software by removing the logic and

Parameter definitions.

2. Optional creation of an independent library chain.

3. A privileged node fetches the transaction for the new procedure from the

Transaction pool.

4. Ensuring up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed by using a proof-of-completion consensus.

5. Creation and attachment of a limb block by privileged nodes to an independent blockchain (library chain) or to the referencing blockchain itself.

6. Storage of rights, logic and parameter definitions with the block reference. 7.Nodes get the new logic and parameter definitions from the library chain or from the referencing blockchain itself.

8. Including new logic and parameter definitions on the fly

Processing.

9. Immediate application of the new logic and parameter definitions.

Conclusion: The procedural logic is an integral part directly on the library chain or on the referencing blockchain itself. It contains a reference to any block of a backbone chain. Because the referencing blockchain does not have to make any changes with regard to the fork, the fork can also take place retrospectively on any block, i.e. also on blocks that already have subsequent blocks. This creates another property that otherwise only database-based applications have.

The dynamization of the blockchain and its infrastructure is important for the

Opening up new areas of application using intelligent block types for immediate use is particularly important.

Only the relocation of the logic and parameters to the blocks on the blockchain itself or on a separate library chain creates the possibility of immediate changes to the processing method. It enables an advanced

Functional scope with new block types, block connections and Possible combinations (Figure 12, compare with Figure 18, also Figure 19). They contain the entire processing logic and can have a consensus mechanism that is different from the data blocks. Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. The up-to-dateness and authenticity as well as compliance with all rules applicable at the time the order is placed are ensured by a proof-of-completion consensus. There is a speed and production advantage. It is immediately transferred to the subsequent blocks of the newly created blockchain. The previous processing method on the original blockchain is not affected. Existing documentation channels are guaranteed. Both machining processes can be used in parallel independently of one another. There is no need to coordinate the network. An economic and ecological advantage is achieved.

Compared to the previous procedures, the licensees participate in the shortened value chain for data applications, a considerable one

Speed advantage for provision and lower manufacturing costs.

The unique selling point is the dynamization of the blockchain and its infrastructure.

The target group are all companies that have to store and manage data securely and decentrally. The data can also be made available to the public in a tamper-proof manner for documentation purposes. Manufacturing and supply chains can also be mapped transparently, quickly and securely. Possible partners can be found both in industry and in the form of service providers or manufacturers for everyday purposes. The range of uses is broad.

Small excerpt of specific application examples:

1. Maintenance contracts

2. Tenders

3. Proof of ID (e.g. to be able to conclude contracts - identify yourself - age check over 18)

4. Algorithm check (e.g. banknotes - the system checks the presence of the serial number and, by means of the algorithm, abnormalities such as average overuse)

5. Fingerprint storage e.g. B. at authorities 6. M2M solutions

7. Participation and examination certificate (e.g. online seminars - training courses - high school diploma)

8. Time clock

9. Vacation planner

10. Sweepstakes

11. Photo evidence (ownership and creation date) also in real time directly when the photo is taken

12.Advertising (Ads control)

13. Business processes and document management (especially for

Compliance, data protection, contract management and investment management

14. Testament

15. Heating, electricity, gas, water reading service

16. Multi-signature = triggers contracts

17. Declaration of consent

18. Shareholder resolutions

19. Conclusion of contracts

20. Medicinal prescription

21. POS systems

22. IoT communication in networked systems

23. Copyright - rights management and access authorization for digital assets

24. Archiving - documents and file storage - audit-proof

Archiving - e.g. B. Land registers State archives

25. Public or private directories, information services or credit agencies that are relevant to the EU GDPR. (Schufa, job management, classified ads, etc.)

In particular, the following areas are strongly influenced by this:

1 logistics

2. Cloud storage

3. Public sector

4. Energy

5. Utilities

6 Supply Chain Management

7. Government

8 ride sharing

9. Music 10. Elections

11. Donate

12. International Payments

13. Insurance

14. Artists, Media & Advertising

15. Detect counterfeits

16. Mobility

17. Healthcare

18. Citizen data management

19. Identity Management

20. Elections

21. Taxes

22. N GOs and N on-Profit Organizations

23. Compliance and Legislative Controls

24. Shareholder voting

25. Data Management

26. Cybersecurity

27. Diplomas and certificates

28. Big data & data storage

29. Internet of Things (IoT)

30. Public or private exchange of information relevant to EU GDPR data.

In developing the system according to the invention, the inventors have overcome the following technical difficulties in an unobvious way.

1. The nodes are statically linked to software.

2. This software contains the logic of how to edit each block.

3. Each block is subject to the same processing rules.

4. All blocks are rigid of the same type.

5. Individual processing of blocks is not possible.

6. Due to the lack of logic of conventional one-part or multi-part

Blockchains / sidechains create no dynamic. Solution: First declassifying the node software, classifying the blocks in

Types and the expansion of the blocks by a container structure, which contains the logic and the parameters for the block processing method, enables a fast, individual block processing. They contain the entire processing logic and can have a consensus mechanism that is different from the data blocks. Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. The timeliness and authenticity as well as compliance with all the

The time of placing the order according to the applicable rules is ensured by means of a proof-of-completion consensus.

Advantageous configurations of the invention are given in the subclaims.

Examples

Several exemplary embodiments of the invention are described in more detail below with reference to drawings. In all drawings, the same reference symbols have the same meaning and are therefore only explained once if necessary.

Show it

Figure 1: Declustering the node software of the new, dynamic process,

Figure 2: Fork of a blockchain of the new, dynamic process,

Figure 3: Final termination of a blockchain of the new, dynamic process,

Figure 4: Deletion of data blocks on a blockchain of the new, dynamic method,

Figure 5: Script and black box use of the new, dynamic process,

Figure 6: Merging of blockchains of the new, dynamic process,

Figure 7: Practical example of customer management on the blockchain (focused), new, dynamic process,

Figure 8: Practical example EU GDPR Art. 17 on the blockchain (focused), new, dynamic procedure,

Figure 9: Practical example of production documentation (focused), new, dynamic process,

Figure 10: Storage space requirements and grouping of the data in the new, dynamic process,

Figure 11: Simplest definition of a blockchain (minimum requirement), new, dynamic process,

Figure 12: Possible block connections in the new, dynamic method,

Figure 13: Possible structure of the container in the new, dynamic process,

Figure 14: Static blockchain of the method known from the prior art, FIG. 15: Fork of a static blockchain of the method known from the prior art,

Figure 16: Storage space requirements and fragmentation of the data in the known, static method,

Figure 17: Simplest definition of a blockchain (minimum requirement), known, static method,

FIG. 18: Possible block connections in the known, static method and FIG. 19: Referential fork of a blockchain of the new, dynamic method. Figure 20: Use of the proof-of-completion consensus.

Operation of the invention

The method of operation of the method according to the invention is explained in detail below with reference to the drawings:

9 1 De-clustering of the node software of the new procedure

Figure 1: The nodes (2) of a network (3) fetch software (6) with the basic operating function (4) of a node from a central software memory (1). The initial processing logic (5) for processing the data blocks (7) on a backbone chain (8) is obtained by the nodes (2) directly from a container (17, Figure 13) in the genesis block (9) of the backbone chain (8) from. It contains the entire

Processing logic (5) and can have a consensus mechanism that is differentiated from the data blocks (7). Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. The nodes (2) fetch the transactions (29) from a transaction pool (28) for processing the new data block (11), which were delivered there from a data source (30). The content of a new data block (11) is calculated with the aid of the processing logic (5) (FIG. 11). The backbonechain (8) is created from a Genesis block (9) which is equipped with a container (17) for holding files, including, but not limited to, the processing logic (5) for processing data blocks (7) . Further data blocks (7) are added to this Genesis block (9). The newest data block (11) is added to the last data block (10) added. Written data blocks (7) cannot be changed and cannot be deleted. The backbone chain (8) extends infinitely (Figure 10).

9.2 Fork a blockchain of the new procedure Figure 2: At a fork (16) from the backbone chain (8), a limbchain (13) is created. A rights file (19) stored in the Genesis block (9) in the container (17, FIG. 13) can equip certain nodes (18) with special rights. One of these rights can be the addition of a limb block (20) to the backbone chain (8). It contains the entire processing logic (5) and can have a consensus mechanism differentiated from the data blocks (7). Proof-Of-Work, Proof-Of-Stake etc. can be used in parallel. The privileged node (18) fetches the transaction (29) from the transaction pool (28) to add a limb block (20), which was previously delivered there from a data source (30). The limb block (20), like the genesis block (9), is equipped with a container (17) for files. Here the limb block (20) receives the new processing logic (15) and a new rights file (21) from the privileged node (18) for the limbchain (13). The nodes (2) get the processing logic (15) from the Limb block in addition to the already existing processing logic (5) and can now use both blocks of the original

Process the backbonechain (8) as well as the limbchain (13). The network (3) remains intact (see Figure 15). All nodes (2) can add new data blocks (11) according to the original processing logic (5) to the most recently added limb block (20) of the original backbonechain (8), as well as new data blocks (14) for the limb chain (13) with a modified one

Add processing logic (15) and new rights (21) to the limb block (20).

9.3 Final termination of a blockchain of the new procedure

Figure 3: At a fork (16, Figure 2) (fork) of the backbone chain (8) a limbchain (13) is created. A rights file (19) stored in the Genesis block (9) in the container (17, FIG. 13) can equip certain nodes (18) with special rights. In addition to adding a limb block (20) to the backbone chain (8), one of these rights can also be the final option to terminate the addition of further blocks by setting an end block (22). The privileged node (18) fetches the transaction (29) from the transaction pool (28) to add an end block (22) that was previously delivered there from a data source (30). The end block (22), like the genesis block (9) or the limb block (20), is equipped with a container (17) for files. An info file (23) can provide information about the reason for the termination or further procedures. No further data blocks (14) can be added to the limbchain (13) (Figure 10).

9.4 Deletion of data blocks on a blockchain of the new procedure Figure 4: A limbchain (13) is created at a fork (16, Figure 2) of the backbone chain (8). A rights file (21) stored in the limb block (20) in the container (17, FIG. 13) can equip certain nodes (18) with special rights. In addition to adding a limb block (20) to the backbone chain (8), one of these rights can also be the possibility of deleting data blocks (14). The privileged node (18) fetches the transaction (29) from the transaction pool (28) for deleting and adding an info block (24) that was previously delivered there from a data source (30). Deletion is only possible from the end of the limb chain (13), up to a maximum of before the limb block (20). There can also be the right to add an info block (24). The info block (24), like the limb block (20), is equipped with a container (17) for files. An info file (23) can contain information about the reason for the deletion or further procedures. Further data blocks (14) can be added to an info block (24).

9 5 Script and black box use of the new procedure

FIG. 5: The nodes (2) of a network (3) fetch software (6) with the basic operating function (4) for nodes (2) from a central software memory (1). The initial processing logic (5) for processing the data blocks (7) on a backbone chain (8) is picked up by the nodes (2) directly from a container (17, FIG. 13) in the genesis block (9) of the backbone chain (8). The nodes (2) fetch the transactions (29) from a transaction pool (28) for processing the new data block (11), which were delivered there from a data source (30). The content of a new data block (11) is calculated with the aid of the processing logic (5). The backbonechain (8) is made up of a Genesis block (9) with a container (17) for holding files, including, but not limited to, the

Processing logic (5) for processing data blocks (7) is equipped. In this container (17) there is also a rights file (19) the certain nodes (18) special rights, e.g. the insertion of a limb block (20) allows. Further data blocks (7) are added to this Genesis block (9). The latest data block (11) is added to the last data block (10) added.

Written data blocks (7) cannot be changed (FIG. 11) and cannot be deleted. The backbone chain (8) extends infinitely (Figure 10). The privileged node (18) fetches the transaction (29) to add a limb block (20) from the

Transaction pool (28) that was previously delivered there from a data source (30). At a fork (16, Figure 2) (fork) of a limb block (20) from the

Backbonechain (8) creates a limbchain (13). The limb block (20), like the genesis block (9), is equipped with a container (17) for files. The node (18) fills this container with a rights file (21) and a new processing logic (15). For processing the data blocks (14), the nodes (2) pick up the processing logic (15) on the limbchain (13) in addition to the already existing processing logic (5) of the backbone chain (8). In a processing logic (15), multilingual scripts can also access external systems (25) via an interface (26) during the block processing time, deliver data there and receive a result back. The result can influence the processing of the data block (14). The processes of the external system (25) are not visible to the nodes (2) in the network (3).

9 6 Merging of blockchains using the new procedure

Figure 6: A privileged node (18) from the network (3) forks (27, Figure 2) from a backbone chain (8) a new blockchain for merging as a merge chain (32). When the blockchains (13a-c) are merged (31a-c) from a limb block (20) or from any data block (14b + c), a blockchain becomes a merge chain (32). A rights file (21) stored in the merge block (33) in the container (17, FIG. 13) can equip certain nodes (18) with special rights for the merge chain (32). A parameter file (34) also stored there contains the identifier of the merged (31a-c) blockchains (13a-c) as well as the identifier of the limb block (20) or the data block (14b-c) from which the merge (3 la-c) has been referenced. When referencing a limb block (20) that was added specifically for the merging, an info file (23) for the reason for the merging (31a) can be stored in its container (17). Referencing to data blocks (14b + c) from any blockchains (13b + c) and any architecture outside the network (3) is possible and does not require any special authorization for referencing. The blockchains (13a-c) continue to run in accordance with their intended use regardless of the merge (3 la-c). The privileged node (18) fetches the transaction (29) to create a merge block (33) from the transaction pool (28), which was previously delivered there from a data source (30). The merge block (33) is equipped with a container (17) for files. Here the merge block (33) from the node (18) for the new merge chain (32) contains the new processing logic (15), a new one

Rights file (21) and a parameter file (34). The nodes (2) also get the new processing logic (15) from the merge block (33). All nodes (2) can create new data blocks (11) for the new blockchain (32) with a new one

Add processing logic (15) and new rights (21) to the merge block (33). 9.7 Practical example of customer management on the blockchain (focused) new procedure

Figure 7: A backbone chain (8) is forked for a customer by an authorized node (18) from the network (3) (27, Figure 2). The authorized node (18) adds a limb block (20a) for the fork (16a) of a blockchain (13a)

Processing of personal data, another limb block (20b) for the fork (16b) of a blockchain (13b) for processing account movements and a limb block (20c) for the fork (16c) of a blockchain (13c) for a secret one Purpose one. Nodes (2) from the network (3) can according to their

Authorization from the rights file (21a-21c) fill the blockchains (13a-13c) with data blocks (14a-c) according to the conditions from the processing logic (15a-15c) (Figure 11). Processing logic (15c) requires the data for the secret purpose to be transferred to an external system (25) via the interface (26). The external system (25) sends a return value via the interface (26), which is taken into account when processing the data block (14c).

9.8 Practical example EU GDPR Art. 17 on the blockchain (focused) new

Procedure

Figure 8: A backbone chain (8) is forked (27, Figure 2) for a customer by an authorized node (18) from the network (3). The authorized node (18) adds a limb block (20a) for the fork (16a) of a blockchain (13a)

Processing of personal data, another limb block (20b) for the fork (16b) of a blockchain (13b) for processing account movements and a limb block (20c) for the fork (16c) of a blockchain (13c) for a secret one Purpose one. Nodes (2) from the network (3) can according to their

Authorization from the rights file (21a-21c) fill the blockchains (13a-13c) with data blocks (14a-c) according to the conditions from the processing logic (15a-15c) (Figure 11). The rights file (21a) allows authorized nodes (18) to delete data blocks (14a) and to add an end block (22) with information about the reason for the deletion in the info file (23). The customer's personal data (14a) are permanently deleted. Data of the account (14b) and the secret purpose (14c) are permanently retained (FIG. 10).

9.9 Practical example of production documentation (focused) new dynamic process

Figure 9: A milk processing plant documents the production of

Strawberry yoghurt on a merge chain (32). In addition, a privileged forks (27, Figure 2) Node (18) from the network (3) from a backbone chain (8) a new blockchain as a merge chain (32). The packaging supplier uses the same dynamic documentation model and documents the production of its yoghurt pots on its own limbchain (13a, Figure 10). The delivery of the batch to the

He documented the milk processing company in a limb block (20). Of the

Milk supplier documents the individual milk deliveries on a continuous blockchain (13b, Figure 16). The strawberry supplier documents the origin of his strawberries on a blockchain (13c, Figure 16). Both suppliers use external, static documentation models (13b + c). The published delivery of the packaging manufacturer is referenced in the merge block (33) (31a). The milk batch and the strawberry batch are referenced directly to the ongoing production (14b + c) in the external documentation models (31b + c). The completely filled and packaged yoghurt pots are continuously documented in data blocks (11) (FIG. 11). The entire production chains of the milk processing company and the suppliers can be viewed at any time.

9.10 Storage space requirements and grouping of the data in the new dynamic

Procedure

Figure 10: The backbone chain (8) grows by adding new data blocks (11) from the Genesis block (9) through the data blocks (7) to the last added data, limb, info or merge block ( 10) infinitely further. Transactions (29) of a task are processed via a limb block (20) in an independent limb chain (13). The task can finally be completed by an end block (22). Transactions (29) of a task are grouped and not fragmented. For complete documentation of a self-contained task, only the backbone chain (8) from the genesis block (9) to the limb block (20) and the limb chain (13) to the end block (22) need to be saved and held.

Forks (Figure 2) on the backbone chain (8), both before and after the limb block (20), are not relevant for the task on the limb chain (13) and therefore do not have to be saved and documented for task-related full nodes ( compare Figure 16).

9.11 Simplest definition of a blockchain (minimum requirement) dynamic procedure

Figure 11: The backbone chain (8) can also be a limb chain (13) or a merge chain (32). Depending on which one, it starts with a Genesis block (9), a Limb block (20) or a Merge block (33). The first block becomes any, free selectable start value (35) [here: 00000000000000000000000000000000] assigned. From the start value (35) together with any data (36) [here: DATA1], together with a container (17, Figure 13) with possible scripts for

Dynamization, here representing the processing logic (5), a rights file (19) and a parameter file (34), an end value (38) [here: 7906ded4f829316e0e4ea7b6e5dcad56] is calculated with an algorithm (37) [here: MD5]. In the following data block (7), the end value (38) of the Genesis block (9) is specified in a binding manner for the start value (35). Together with any data (36) [here: DATA2], the final value (38) [here:

2c82a8b4ca93ebf5f60041b9fl087f9d] is calculated. In the last data block (10), the final value (38) from data block (7) is defined as the binding start value (35).

Together with any data (36) [here: DATA3], the final value (38) [here: c820465ddl80deff225939057ffb9915] is calculated using an algorithm (37). This process is continued with all further appendices of new data blocks (11). The backbone chain (8) extends infinitely (Figure 10). The method (37) always remains the same. Subsequent changes to a start value (35), any data (36), the scripts (5/19/34) or an end value (38) make the ongoing structure of the backbone chain (8) inconsistent. A recalculation automatically leads to different final values. The content of the data blocks can therefore be recognized as not authentic. Scripts (5/19/34) are available from the beginning

Tampering is protected because they are a fixed, unchangeable part of the blockchain. Required changes are transparently documented in limb blocks (20) or merge blocks (33).

9 12 Possible block connections in the new dynamic method

Figure 12: The beginning (39, Figure 11) of a backbonechain (8) begins with a Genesis block (9). This contains a container (17, FIG. 13) for receiving files, for example the process logic (5) for calculating the end values (38). A new data block (11) is appended directly to the Genesis block (9) (FIG. 11).

The further sequence (40, Figure 11) is done by adding new data blocks (11) directly to the last added data block (10) on the backbone chain (8).

At the fork (41, FIG. 2) of the backbone chain (8), a limb block (20) is first added. This contains a container (17, Figure 13) for receiving

Files, for example the new processing logic (15) for the new, forked (16) Limbchain (13). New data blocks (11) can be attached to the limb block

Continuation of the backbonechain (8) can be added, as well as new data blocks (14) for the limbchain (13).

A limb block (20) is added to change the performance (42) of the running backbone chain (8). This contains a container (17) for receiving files, here e.g. the new processing logic (15) the forked (16, Figure 2) on the Limbchain

(13) will be applied from now on. An end block (22, FIG. 3) is added to the limb block (20). This contains a container (17, Figure 13) for receiving files, here e.g. an info file (23) that informs about the change in service. To the

Long blocks cannot be added to backbonechain (8). New data blocks

(14) are continuously added, instead of to the backbone chain (8), exclusively on the limbchain (13) under the conditions of the new processing logic (15) (Figure 11).

When referencing (43) to a dynamic blockchain section in a limbchain (13), a limb block (20) is attached to the blockchain (13) to be referenced. This contains a container (17, Figure 13) for receiving files, here e.g. an info file (23) which informs about the referencing. A merge chain (32) is forked from a previously described fork process (27, FIG. 2). This contains a merge block (33) with a container (17) for receiving files, here e.g. the new processing logic (15) and a parameter file (34) with reference information to the limb chain (13) to be referenced and the position of the limb block (20) to which referencing (31) is made. The limbchain (13) continues unchanged as before. The forked (27) merge chain (32) is operated from now on with reference to the reference (34) according to the processing logic (15).

For referencing (44) to any block of an unknown blockchain (13) with any architecture, a merge chain (32) is forked from a previously described forking process (27, FIG. 2). This contains a merge block (33) with a container (17, Figure 13) for receiving files, here e.g. the new

Processing logic (15) and a parameter file (34) with reference information to the blockchain (13) to be referenced and the position of the data block (14) to which reference is made. The blockchain (13) continues to run unchanged as before. The forked (27) merge chain (32) is operated from now on with reference to the reference (34) according to the processing logic (15). When merging (45) several (31) dynamic blockchains (13a + b), a limb block (20) is attached to each of the (31) blockchains (13a + b) to be merged. This contains a container (17, FIG. 13) for receiving files, here for example an info file (23) which provides information about the merging. An end block (22, FIG. 3) is added to each of the limb blocks (20) to terminate the previous processing method. Both end blocks contain a container (17) for holding files, here, for example, an info file (23) that provides information about the merging. A merge chain (32) is forked from a previously described fork process (27, FIG. 2). This contains a merge block (33) with a container (17) for holding files, here for example the new one

Processing logic (15) and a parameter file (34) with reference information on the merged (31) blockchains (13a + b) and the position of the limb blocks (20) to which the merge references. No further blocks can be attached to the blockchains (13a + b). The forked (27) merge chain (32) will henceforth be operated with reference to the references (34) to the blockchains (13a + b) according to the processing logic (15).

To add information (46), an info block (24) is appended to the last data block (10) of a backbone chain (8). This contains a container (17, Figure 13) for receiving files, here e.g. an info file (23) which informs about any things. Further blocks can be appended as before (Figure 11).

For the final termination (47, FIG. 3) of a backbone chain (8), an end block (22) is appended to the last data block (10) of a backbone chain (8). This contains a container (17, Figure 13) for receiving files, here e.g. an info file (23) which informs about the termination. No further blocks can be appended (Figure 10).

To delete blocks and connections (48, FIG. 4), these are deleted one after the other from the newest data block (11) via the respective last data block (10). To do this, the deletion option must be explicitly permitted in a blockchain rights file. New blocks can then be appended (Figure 11). The block positions are overwritten.

9 13 Possible structure of the container using the new dynamic method

Figure 13: The container (17) has a tree structure that is common today

(e.g. arrays, XML, JSON, SQL, CSV, etc.) can be mapped. The structure is that of a file system consisting of folders and files. Thanks to this structure, it can contain further containers. Content can be any files

(5/21/15/19/23/34 /?) Be. Parameters are shown in it, for example, as a key-value pair. The scripts and parameters contained here can be included as software for further use by the nodes (2). In its digital form, it and all of its content become an integral part of the dynamic blockchain (Figure 11).

Comparative example: method known from the prior art

9.14 Static blockchain of the method known from the prior art

Figure 14: From a central software memory (1), the nodes (2) of a network (3) fetch software (6) that binds the basic operating function (4) and processing logic (5) for processing the data blocks (7) on a blockchain (52 ). The content of a new data block (11) is calculated with the aid of the processing logic (5). The blockchain (52) is created from a Genesis block (9). Further data blocks (7) are added to this genes block (9). To the last appended

The newest data block (11) is added to data block (10). Written

Data blocks (7) cannot be changed and cannot be deleted. The blockchain (52) extends infinitely as an add-only memory (see Figure 1).

9.15 Fork of a blockchain of the method known from the prior art Figure 15: At a fork (16) from the blockchain (52), a new blockchain (13) is created. The nodes (2) have to decide for which blockchain they will process in the future. Such a decision-making process can take several months. A new network is created (12). The reduced, original network (3) continues to add new data blocks (11) according to the original processing logic (5) to the most recently added data block (10) of the original blockchain (52). The nodes (2) in the new network (12) fetch new software (6) consisting of basic operating software (4) and modified processing logic (15) from a central storage location (1). New data blocks (14) of the new blockchain (53) are processed according to the new processing logic (15). The original blockchain (52) and the new blockchain (53) only have the shared computing power available exclusively. A dynamic distribution is not possible (see Figure 2).

9.16 Storage space requirements and fragmentation of the data in the known static method

Figure 16: The blockchain (52) continues to grow infinitely by adding new data blocks (11) from the Genesis block (9) via the data blocks (7) to the last added data block (10) (Figure 17). It's an add-only store. Transactions (29) of one task are fragmented with other transactions (29) of other tasks over the entire blockchain (52). For complete documentation of a self-contained task, the entire blockchain (8) must be linked to each individual Data block (7) are always stored and kept up-to-date (compare FIG. 10).

9.17 The simplest definition of a blockchain (minimum requirement) static

Procedure

Figure 17: The blockchain (52) begins with a Genesis block (9). Since it is the first block in the blockchain (52), it receives any starting value (35) [here:

00000000000000000000000000000000] An end value (38) [here: 7906ded4f829316e0e4ea7b6e5dcad56] is calculated from the start value (35) together with any data (36) [here: DATA1] using an algorithm (37) [here: MD5]. In the following data block (7), the end value (38) of the Genesis block (9) is specified in a binding manner for the start value (35). Together with any data (36) [here: DATA2], the final value (38) [here:

2c82a8b4ca93ebf5f60041b9fl087f9d] is calculated. In the last data block (10), the final value (38) from data block (7) is defined as the binding start value (35).

Together with any data (36) [here: DATA3], the final value (38) [here: c820465ddl80deff225939057ffb9915] is calculated using an algorithm (37). This process is continued with all further appendices of new data blocks (11). The blockchain (52) extends infinitely. The

Method (37) always remains the same. Subsequent changes to a start value (35), any data (36) or an end value (38) make the ongoing structure of the blockchain (52) inconsistent. A recalculation automatically leads to different final values. The content of the data blocks can therefore be recognized as not authentic. The processing logic (5) is not part of the blockchain (52) (see Figure 11).

9.18 Possible block connections known static method

Figure 18: The beginning (49) of a blockchain (52) begins with a Genesis block (9). A new data block (11) is attached directly to the Genesis block (9).

The further stringing (50) takes place by directly adding new data blocks (11) to the respectively most recently added data block (10) on the blockchain (52).

At the fork (51) of the blockchain (52) arise after a lengthy

Coordination process of the network (3, Figure 15) two separate blockchains (52 + 53). There is no dynamic connection. Both blockchains are used infinitely as add-only memories separately from one another (see Figure 12).

9.19 Referential fork of a blockchain of the new procedure

Figure 19: A fork (16) from the backbone chain (8) creates a new limbchain (13). A rights file (19) stored in the library chain (54) in the limb block (20a) in the container (17) can equip certain nodes (18) with special rights. One of these rights can be the insertion of a limb block (20b) on the library chain (54). The privileged node (18) fetches the transaction (29) for adding a limb block (20b) from the transaction pool (28), which was previously submitted there from a data source (30). The limb block (20b), like the limb block (20a), is equipped with a container (17) for files. Here the limb block (20b) from the node (18) for the new limbchain (13) contains the new processing logic (15) and a new rights file (21). The nodes (2) also fetch the new processing logic (15) from the limb block (20b) and can now use both the original backbone chain (8) and the new ones

Process Limbchain (13). The network (3) remains intact. All nodes (2) can add new data blocks (11) according to the original processing logic (5) to the most recently added data block (10) of the original backbone chain (8), as well as new data blocks (14) for the limbchain (13 ) with a modified processing logic (15) and new rights (21) to the limbchain (20).

9.20 Use of the proof-of-completion consensus

FIG. 20: A data or order source (30) uses a software / app (6a) with which orders / data can be encrypted / decrypted. The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without these

Update is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) from the network (3) and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can compare the result with the status of the completion of all orders on the library chain (54) and thereby check the current status and the Ensure authenticity. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use.

In the following, the use of the proof-of-completion consensus ‘is illustrated using concrete practical examples.

9 20a Use of the proof-of-completion consensus for the creation of a digital identity by a person _" Seif Sovereign Identity" (SSI)

Figure 20: A person (30) uses a software / app (6a) with which

personal data (name, address, personal ID, etc.)

can be encrypted / decrypted and instructs the creation of a digital data record. The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the

Library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can compare the result with the status of the completion of all orders on the library chain (54) and thereby check the current status and the Ensure authenticity. The node (2c) delivers the data to the

Software / app (6b) to an inquiring point (55) for further use. This makes it possible for the digital identity to become completely self-managing. Only the person himself, for whom the data is provided, determines what information is provided and what is not. Data or parts of it can be deleted at any time. They are no longer available for further reading. 9.20b Use of the proof-of-completion consensus for the confirmation of the identity of a digital identity Verifiable Claims "(VC)

Figure 20: An authority (e.g. residents' registration office), a bank or another institution (30) uses a software / app (6a) with which personal data (name, address, personal ID, etc.) is compared with the person (personal

Identification) can be encrypted / decrypted as an identification result (Trusted Point) and instructs the attachment of the identification result (Trusted Point) to be added to the digital data record. The software / app (6a) takes over the

Connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network.

This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can see the result with the status of the completion of all orders on the

Compare the library chain (54) and thereby ensure that it is up-to-date and authentic. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use. The digital identity remains completely in self-administration. Only the person himself, for whom the data is provided, determines what information is provided and what is not. Trustee Points / Verifiable Claims (VC) can be added by authorized third parties. Data or

Parts of it can be deleted at any time, both by the creator and by the person for whom the data was provided. They are no longer available for further reading. 9 20c Use of the proof-of-completion consensus for querying a digital

Identity through a person / institution / company Figure 20: A person / institution / company (30) uses a software / app (6a) with which orders / data can be encrypted / decrypted. It identifies itself through a customized authentication process

(Username / password, NFC, iris scan, DNA sequence, x-factor authentication). The software / app (6a) handles the connection and authentication with the network (3). A node (2a) asks the current one in the library chain (54)

Order status of the blockchain (8). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) with information about the query can be attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the

Network (3) wants to read the current status of the data on the blockchain (8), he can compare the result with the status of the completion of all orders on the library chain (54) and thereby ensure that it is up-to-date and authentic. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use.

9 20d Use of the proof-of-completion consensus for the creation of a

Debtor information

Figure 20: A person or debt collection company / bank / institution / company (30) uses a software / app (6a) with which personal data (name, address, personal ID, credit entry, affidavit, etc.)

can be encrypted / decrypted and instructs the creation of a digital data record. The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, which complies with the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the

Library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can compare the result with the status of the completion of all orders on the library chain (54) and thereby check the current status and the Ensure authenticity. The node (2c) delivers the data to the

Software / app (6b) to an inquiring point (55) for further use.

9 20e Use of the proof-of-completion consensus to query a

Debtor information

Figure 20: A person (self-disclosure) or a bank / institution / company (30) uses a software / app (6a) with which orders / data can be encrypted / decrypted. It identifies itself through a purpose-adapted

Authentication process (username / password, NFC, iris scan, DNA sequence, x-factor authentication). The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). When the state of

If the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) with information about the query is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the

Library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can compare the result with the status of the completion of all orders on the library chain (54) and thereby check the current status and the Ensure authenticity. The node (2c) delivers the data to the

Software / app (6b) to an inquiring point (55) for further use. 9.20f Use of the proof-of-completion consensus for orders from a smart

Household appliance. Machinery. Production lines (ΊOT / T angle)

Figure 20: A smart household appliance refrigerator / SmartHome / machine / probe (30) uses a software / app (6a) with which personal data (name, address, stocks, orders, deliveries, status, etc.) can be encrypted / decrypted and orders the creation of a digital data record. The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without these

Update is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. When a Node

(2c) wants to read the current status of the data on the blockchain (8) from the network (3), he can compare the result with the status of the completion of all orders on the library chain (54), thereby ensuring that it is up-to-date and authentic. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use. A household appliance can also be a node. Confirmations can also be made from node to node via a tangle process, similar to IOTA.

9 20g Use of the proof-of-completion consensus for a supply chain (Delivery Chain - Supply-Chain-Managemenf)

Figure 20: A sender (30) uses a software / app (6a) with which

personal data (name, address, recipient, sender, order,

Deliveries, states etc.) can be encrypted / decrypted and instructs the creation of a digital data record. The software / app (6a) takes over the

Connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not match the orders from the library chain (54) the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network.

This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can see the result with the status of the completion of all orders on the

Compare the library chain (54) and thereby ensure that it is up-to-date and authentic. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use. After delivery and expiry of the objection period, all personal data on the blockchain will be deleted.

9 20h Use of the proof-of-completion consensus for writing, deleting and changing in a blockchain-based data management as a service (BDMaaS)

FIG. 20: An order source person / machine / probe (30) uses one

Software / app (6a) with which personal data (name, address, status, any data, etc.) can be encrypted / decrypted and orders the creation of a digital data record. The software / app (6a) handles the connection and authentication with the network (3). A node (2a) asks in the

Library chain (54) the current order status of the blockchain (8). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without this update, he is not allowed to continue working on the blockchain and is ignored in the network.

This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) is off the network (3) wants to read the current status of the data on the blockchain (8), he can see the result with the status of the completion of all orders on the

Compare the library chain (54) and thereby ensure that it is up-to-date and authentic. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use. This makes the blockchain self-managing (Seif Souverän, SS).

9 20i Using the proof-of-completion consensus for reading in one

Blockchain based data management as a service (BDMaaS)

Figure 20: A person / machine / script (30) uses a software / app (6a) with which orders / data can be encrypted / decrypted. It identifies itself via a purpose-tailored authentication process (username / password, NFC, iris scan, DNA sequence, x-factor authentication). The software / app (6a) handles the connection and authentication with the network (3). A node (2a) queries the current order status of the blockchain (8) in the library chain (54). If the status of the blockchain (8) does not correspond to the orders from the library chain (54), the blockchain (8) is first updated. Without these

Update is not allowed to continue working on the blockchain and is ignored in the network. This ensures, among other things, that a deletion order is actually carried out, whereby the rules of the EU GDPR are met accordingly. The new block (11) with information about the query is attached to the current blockchain (8). Another node (2b) from the network (3) queries the new status of the blockchain (8) and compares it with the status of the orders from the library chain (54). If both match, the addition of the block (11) to the blockchain (8) is confirmed by the node (2b) in the network (3), otherwise the addition of block (11) to the blockchain (8) is confirmed by the network (3) rejected and ignored. If a node (2c) from the network (3) wants to read the current status of the data on the blockchain (8), it can compare the result with the status of the completion of all orders on the library chain (54) and thereby check the current status and the Ensure authenticity. The node (2c) delivers the data to the software / app (6b) to a requesting point (55) for further use. Possible blockchain types of the new dynamic process

Possible block types of the new dynamic procedure

Possible contents of a container (17) of the new dynamic method

List of reference symbols

1 central software storage (location where software is stored for download)

2 Node (executing computer)

3 network (grouping of nodes)

4 basic software (software for operating a node)

5 processing logic (software that defines the process and type of processing)

6 software package (may contain software for various purposes)

7 data block within a chain (contains e.g. transaction data)

8 Backbonechain (chaining of data blocks, carrier of

Limbchains)

9 Genesis block (first block of a blockchain)

10 Last data block (block to which a subsequent block can be added)

11 New data block (block to be added)

12 New network (split from the original network)

13 Limbchain (fork, fork of a backbonechain)

14 data block in a new blockchain (contains e.g. transaction data)

15 New processing logic (method and type defines a privileged

Node)

16 fork process (fork of the blockchain)

17 container (contains folders or files e.g. scripts, binary, text,

Rights, parameters)

18 Node with special rights (privileged, can have its own properties and rights)

19 Rights file of the Genesis block (privileges certain nodes) 20 Limb block (controls the fork, is used by a privileged

Node inserted)

21 Rights file of a limb block (is defined by a privileged node)

22 End block (ends a blockchain, is used by a privileged

Node inserted)

23 Info file (contains information from a privileged node) Info block (only informational, is inserted by a privileged node)

External system (black box outside the network)

Interface (connection between node and external system) Abstract, focused process (placeholder for a process already described above)

Transaction pool (contains transactions that must be processed)

Transaction (contains data or instructions, is processed by a

Data source supplied)

Data source (an external system, a machine, sensors or other data generator)

Merge process (merge, merging of

Blockchains)

Mergechain (arises from the merging of blockchains) Merge block (defines the merging, merging, generation by privileged nodes)

Parameter file (contains parameters for initiation, referencing, processing, etc.)

Start value (output value, reference for calculating the end value) Data (any data, e.g. scripts, binary, text, rights, parameters) Calculation (any hash algorithms such as MD5, SHA128, SHA256, etc.)

End value (calculated hash value from start value and data)

Beginning of a blockchain (dynamic block connection)

Alignment of data blocks (dynamic + static

Block connection)

Fork in two blockchains (dynamic block connection)

Change in performance during operation (dynamic block connection) Referencing to dynamic blockchain section (dynamic block connection)

Referencing to static blockchain section (dynamic block connection)

Merging of dynamic blockchains (dynamic

Block connection)

Appending information (dynamic block connection)

Ending a blockchain (dynamic block connection) Deleting blocks and connections (dynamic

Block connection)

Start of a blockchain (static block connection)

Alignment of data blocks (dynamic + static

Block connection)

Fork in two blockchains (static block connection)

Blockchain (chaining of data blocks, carrier of limbchains) New blockchain (fork, fork of a blockchain)

Library chain (directory of all limbchains and their

Processing logic)

Requesting body expecting a result

Claims

Expectations

1. A method of controlling a hardware system using a

Blockchain in which a blockchain can be forked and in which

Logics and parameters for block processing are kept in the blockchain itself,

characterized ,

that a dynamization of the blockchain by shifting the logic and parameters into the blocks on the blockchain itself and / or on a separate

The library chain is provided by declustering the node software, classifying the blocks into types and expanding the blocks to include a container structure that contains the logic and parameters for the

Contains block processing procedures, as well as a proof-of-completion consensus that ensures authenticity and rule conformity is carried out.

2. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4. A data source enters a task as a transaction in the transaction pool,

5. She chooses transaction: fork, merge, quit, delete, inform or save,

6. A node picks up a transaction from the transaction pool,

7. Creation and appending of an intelligent block by a privileged node,

8. Storage of rights, logic and parameter definitions by privileged nodes,

9. Ensuring authenticity and compliance with rules through a proof-of-completion consensus. 3. A method for controlling a hardware system using a blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Ensuring authenticity and compliance with rules through a proof-of-completion consensus.

4. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Parallel processing of blockchains by means of appropriate logic and parameter definitions,

8. Ensuring authenticity and compliance with the rules through a proof-of-completion consensus. 5. A method for controlling a hardware system using a blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Parallel processing of blockchains by means of appropriate logic and parameter definitions,

8. Utilization, ownership or reward-related priorities in block processing,

9. Ensuring authenticity and compliance with rules through a proof-of-completion consensus.

6. Method of controlling a hardware system using a

Blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Parallel processing of blockchains by means of appropriate logic and parameter definitions, 8. Priorities related to ownership or entitlement to

Block processing,

9. Ensuring authenticity and compliance with rules through a proof-of-completion consensus.

7. A method for controlling a hardware system using a

Blockchain according to claim 1,

characterized ,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Parallel processing of blockchains by means of appropriate logic and parameter definitions,

8. Priorities related to ownership or entitlement to

Block processing,

9. A data source provides a transaction to terminate in the

Transaction pool,

10. A privileged node fetches a transaction from the transaction pool to end it,

11. Put an end block at the end of a blockchain,

12. Storage of information,

13. Ensuring authenticity and compliance with rules through a proof-of-completion consensus.

8. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized,

that the following procedural steps are carried out: 1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

5. Including new logic and parameter definitions on the fly

Processing,

6. Immediate application of the new logic and parameter definitions,

7. Parallel processing of blockchains by means of appropriate logic and parameter definitions,

8. Priorities related to ownership or entitlement to

Block processing,

9. A data source provides a transaction for deletion in the

Transaction pool,

10. A privileged node fetches a transaction for deletion from the

Transaction pool from,

11. Delete the blocks contained in the delete transaction,

12. Storage of information,

13. Ensuring authenticity and compliance with the rules through a proof-of-completion consensus.

9. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers,

3. Insertion of the logic and parameter definition in the optional containers of the blocks,

4. A data source enters a transaction for forking into the transaction pool,

5. A privileged node fetches a transaction for fork

Transaction pool from,

6. Creation and appending of a limb block by a privileged node, 7. Storage of rights, logic and parameter definitions,

8.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

9. Including new logic and parameter definitions on the fly

Processing,

10. Immediate application of the new logic and parameter definitions,

11. Storage of the history for the new blockchain,

12. Ensuring authenticity and compliance with the rules through a proof-of-completion consensus.

10. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized,

that the following procedural steps are carried out:

1. De-clustering of the node software by removing the logic and

Parameter definitions,

2. Extension of the block parameters by optional containers.

3. Insertion of the logic and parameter definition in the optional containers of the blocks.

4. A data source posts a transaction for forking into the transaction pool.

5. A privileged node fetches a transaction for fork

Transaction pool.

6. Creation and appending of a limb block by a privileged node.

7. Storage of rights, logic and parameter definitions.

8.Nodes access new logic and parameter definitions directly on the blockchain itself or on a separate blockchain (library chain),

9. Including new logic and parameter definitions on the fly

Processing,

10. Immediate application of the new logic and parameter definitions,

11. Ensuring authenticity and compliance with rules through a proof-of-completion consensus.

11. A method of controlling a hardware system using a

Blockchain according to claim 1,

characterized,

that the following procedural steps are carried out: 1. Querying the current order status for a blockchain,

2. Update of the blockchain with the current order status,

3. Failure to perform any activities as long as the order status has not been updated,

4. Checking executed orders for authenticity and compliance with rules,

5. Confirmation of positively checked executed orders,

6. Rejection of negatively checked executed orders,

7. Assurance by comparing the orders placed with the orders executed before delivery for further use.