An example operation may include one or more of storing chaincode comprising executable steps of a multi-party process generated from a state diagram in which a blockchain is an intermediary between a plurality of off-chain systems, receiving a request to execute the multi-party process, processing a step of the multi-party process based on the request via execution of the stored chaincode including the executable steps of the multi-party process to generate a processed result for the step, and storing an identification of the processed step and the generated processed result via a data block among a hash-linked chain of data blocks of the blockchain.

A method for interconnecting data between a plurality of blockchain networks according to an embodiment of the present invention includes receiving a request of an interconnecting transaction for interconnecting data between a plurality of blockchain networks, querying information of an ongoing or scheduled transaction through the plurality of blockchain networks in response to the request, and selectively determining any one of a plurality of interconnecting schemes as an interconnecting scheme of the interconnecting transaction with reference to the queried information, and performing the interconnecting transaction according to the determined interconnecting scheme.

Computer-implemented methods and systems are provided which are suitable for implementation in transaction validation nodes of a blockchain network. Modified blockchain node structures, network architectures, and protocols for handling large numbers of transactions and large transaction blocks are described. The invention is particularly suited, but not limited, to use with the Bitcoin blockchain. A computer-implemented method is provided which includes: (i) receiving transactions from the blockchain network; (ii) validating transactions received from the blockchain network; (iii) maintaining a distributed, decentralized storage of validated transactions with other transaction validation nodes in the blockchain network; and (iv) distributing data corresponding to said validated transactions to the blockchain network for mining.

Computer-implemented methods and systems are provided which are suitable for implementation in transaction validation nodes of a blockchain network. Modified blockchain node structures, network architectures, and protocols for handling large numbers of transactions and large transaction blocks are described. The invention is particularly suited, but not limited, to use with the Bitcoin blockchain. A computer-implemented method is provided which includes: (i) receiving transactions from the blockchain network; (ii) validating transactions received from the blockchain network; (iii) maintaining a distributed, decentralized storage of validated transactions with other transaction validation nodes in the blockchain network; and (iv) distributing data corresponding to said validated transactions to the blockchain network for mining.

A method for document transformation is provided. Documents for different types of transactions are obtained. Each document includes one or more form elements and each form element is represented by a data box to receive data from a user. A library of document templates is generated based on the obtained documents by assigning a common identifier to each of the form elements that match in the obtained documents and receiving a common definition for association with each of the matching form elements. At least a portion of the form elements in in one or more of the document templates are auto populated with the data values received from the user based on the identifiers associated with the form elements in the portion.

A scalable cryptocosm platform has a first data structure comprising a plurality of geographic blocks. A first blockchain has a plurality of property profiles. Each of the plurality of property profiles includes a first connection to one of the geographic blocks. A second blockchain comprises a plurality of occupant profiles. Each of the plurality of occupant profiles includes a second connection to one of the property profiles. The plurality of occupant profiles can include an individual profile, a business profile, and an essential services profile.

An electronic device may include logic to provide a trust credential for linking to a permissioned network over a local network, comprising a plurality of user devices; retrieve a document in an initial status for editing, corresponding to a first state of a distributed ledger, maintained by the permissioned network; generate a first change in the document, wherein the document is in a second status; send, to the permissioned network via the local network, the first change for storage in the distributed ledger, in a second state; retrieve the document in a third status, including a second change, performed subsequently to the first change, the second change being generated by a user device, external to the electronic device, and coupled to the local network; and link to the distributed ledger to retrieve a third state of the distributed ledger, the third state comprising the first change and the second change.

In the labor claim transaction system in response to a selection of a claim to be sold, a worker node notifies an employer node of a sale application, and records the buyer and the sale amount. When determining that there is no problem with the claim to be sold, the employer node records sale approval information in a distributed ledger, and notifies a buyer node of a sale approval notification. When determining that there is no problem with the claim to be sold, the buyer node records buying approval information in the distributed ledger, and notifies a financial institution node of the sale approval notification. The financial institution mode checks that the sale approval information and the buying approval information are recorded, and records sale amount transfer completion information.

The present disclosure relates generally to storing computer models, and more specifically to a platform for achieving replicability of a computer model (e.g., a trained machine-learning algorithm) by storing and providing access to data associated with the computer model using an immutable and decentralized ledger system (e.g., a blockchain ledger) and a distributed database. An exemplary computer-enabled method for storing a computer model, the method comprises: receiving data associated with the computer model; generating one or more asset files based on the data associated with the computer model; generating one or more hash values corresponding to the one or more asset files; generating one or more of location trackers corresponding to the one or more asset files; generating a ledger entry comprising the one or more hash values and the one or more location trackers; and adding the ledger entry to a blockchain ledger.

The disclosed embodiments provide a distributed transaction system including a group of validator nodes that are known to each other in a network but are indistinguishable to other network nodes. The validator nodes form a Committee including a Leader node and one or more Associate nodes configured to receive and process transaction requests and candidate requests, for example, to add new blocks to one or more blockchains. The Committee may be dynamically changed, such that new network nodes may be added to the Committee or may replace existing validator nodes. The Associate nodes also may coordinate with each other to select a new Leader node. The system may allow multiple request-fulfillment process to run simultaneously, thereby enhance the efficiency of the system. The disclosed embodiments reduce the distributed system's reliance on the stability of any particular node(s) in the network, as the validator nodes in the Committee may be changed at a sufficient frequency to remove unreliable, unavailable, or otherwise untrusted nodes. Further, the disclosed embodiments provide a scheme that helps ensure the Leader node, as well as the other Committee members, functions properly.