Abstract: A biometric authentication platform (10) uses fault-tolerant distributed computing to determine if a supplied biometric sample and a sample stored in a registry are from the same person. A collection of reference samples is maintained in a distributed ledger (115) with immutable history of modifications. Results of matching are stored in a separate distributed ledger (125) providing an immutable history log. Coordinated use of both ledgers (115, 125) enable biometric authentication of registered users (140) in real time. Users (140) may interact with providers (150) and/or trusted circles of other users in order to recover user records from the user ledger (115).

Abstract: A biometric authentication platform (10) uses fault-tolerant distributed computing to determine if a supplied biometric sample and a sample stored in a registry are from the same person. A collection of reference samples is maintained in a distributed ledger (115) with immutable history of modifications. Results of matching are stored in a separate distributed ledger (125) providing an immutable history log. Coordinated use of both ledgers (115, 125) enable biometric authentication of registered users (140) in real time. Users (140) may interact with providers (150) and/or trusted circles of other users in order to recover user records from the user ledger (115).

Abstract: A biometric authentication platform uses fault-tolerant distributed computing to determine if a supplied biometric live scan and template are from the same person. Features provide additional protection for biometric data. The template and live scan may be encrypted using a symmetric encryption key. The encrypted template and live scan may be sent with copies of the symmetric key, each copy further encrypted by a public key associated with one processor's public-private key pair. Each processor may decrypt a copy of the symmetric key, which may then be used by the processor for decrypting the live scan and template for matching. A decentralized user ledger may store an encrypted copy of the biometric template, with the key stored locally in a registered device. Alternatively, a decentralized user ledger may store a hash of the biometric template, for verification of a template that is maintained on a registered device.

Abstract: A biometric authentication platform uses fault-tolerant distributed computing to determine if a supplied biometric sample and a template sample, which may be stored in a registry, are from the same person. Samples may be subdivided and assigned to Sub-Sample Processing Clusters for processing in parallel to determine sub-results. A consensus authentication result may then be determined by the processing cluster based upon the sub-results.

Abstract: A biometric authentication platform (10) uses fault-tolerant distributed computing to determine if a supplied biometric sample and a sample stored in a registry are from the same person. A collection of reference samples may be maintained in a distributed user ledger (115), and results of matching are stored in a separate distributed authentication ledger (125). Coordinated use of both ledgers (115, 125) enable biometric authentication of registered users (140) in real time. Variations enable use of a user ledger (115) without an authentication ledger (125), and use of an authentication ledger (125) without a user ledger (115). Either or both ledgers (115, 125) may be shared, private, or combinations of shared and private. Secondary channel audits verify reliability of nodes within a network. Samples may be subdivided and processed in parallel. Sample encryption may be maintained for each processor in a node network.