A client application performs certificate pinning as a means of authenticating the identity of a server. A proxy is interposed in the communications path of the client and the hosting server and provides a proxy security certificate to the client. In response to the client extracting a proxy authentication component from the proxy security certificate, operation of the client is paused and a hosting server authentication component is extracted from a hosting server security certificate. The client operation is resumed, providing the extracted hosting server authentication component to the client, in substitution for the proxy authentication component. Based on receiving the extracted hosting server authentication component, the client authenticates the proxy to receive communications directed to the hosting server.

A network system is provided for improving network communication performance between a first client site and a second client site, the network system including: at least one client site network component bonding or aggregating one or more diverse network connections; and at least one network server component, configured to interoperate with the client site network component, the network server component including a server/concentrator that is implemented at an access point to a high performing network, between the client site network component and the network server component data traffic is carried to a network backbone of the high performing network, while maintaining management of data traffic so as to provide a managed network path that incorporates both at least the bonded/aggregated connection and at least one network path carried over the high performing network. The system uses quantum key distribution to encrypt the managed network path.

Methods, computer readable media, and devices for escrow of master keys and recovery of previously escrowed master keys may be disclosed. A method for escrow of master keys may include registering a root certificate authority (CA) within each of two first-party hardware security modules (HSMs), initializing each of three third-party HSMs as master escrow recovery devices, performing a bootstrap operation on an authoritative blockchain to generate three master keys, generating a first set of master key shard ciphertexts using a first one of the three master escrow recovery devices, a second set using a second one of the three master escrow recovery devices, and a third set using a third one of the three master escrow recovery devices, and storing the first, the second, and the third set of master key shard ciphertexts as opaque objects in each of the two first-party HSMs.

A method of electronically displaying glyphs. The method includes receiving a glyph spacing, moving a first glyph toward a second glyph along an axis, identifying an intersection of a first axis coordinate of the first glyph with a second axis coordinate of the second glyph, and moving at least one of the glyphs along the axis to separate the first and second axis coordinates of the respective first and second glyphs by the glyph spacing.

Systems, methods, and non-transitory computer-readable medium are disclosed includes for secure online credential authentication. One method includes receiving, over an electronic network, identification information from an identity provider; accessing, from a database, previously stored hashed identification information stored in association with a previous identity provider; comparing the identification information to previously stored hashed identification information; and storing the identification information in association with the identity provider that provided the identification information in the database when the hashed identification information does not match previously stored hashed identification information.

A device implementing a digital credential revocation system includes at least one processor configured to maintain a valid digital credential list, a revocation list, and a synchronization counter value. The at least one processor is configured to transmit a request to synchronize the valid digital credential list with an electronic device, the request including the valid digital credential list and the revocation list. The at least one processor is further configured to, in response to receipt of an updated valid digital credential list from the electronic device: clear the revocation list, replace the valid digital credential list with the updated valid digital credential list, and increment the synchronization counter value, and fulfill a received credential maintenance request when the received credential maintenance request comprises an other synchronization counter value that is greater than or equal to the incremented synchronization counter value, otherwise deny the received credential maintenance request.

The present disclosure provides a provisioning method and a terminal device. The provisioning method is applied to the terminal device, including: the security module establishes a secure channel with the certificate authority CA server through one or more session keys shared by the security module and the CA server; and obtains one or more digital certificates from the CA server; wherein, the security module is to implement Universal Subscriber Identity Module (USIM) functions.

Performing cryptographic operations such as encryption and decryption may be computationally expensive. In some contexts, initialization vectors and keystreams operable to perform encryption operations are generated and stored in a repository, and later retrieved for use in performing encryption operations. Multiple devices in a distributed system can each generate and store a subset of a larger set of keystreams.

Methods are described for a data creator to securely send a data payload to another device in a transient symmetric key technology (TSKT) system, and for the other device to securely receive the payload data. One method includes receiving a first seed and a formula from a command and control server. A second seed is generated, and the first seed and the second seed are combined using the formula to create a data seed. A first key is generated using the first seed, and the second seed is encrypted using the first key to form an encrypted second seed. A second key is generated using the data seed, and the data payload is encrypted using the second key to form an encrypted data payload. The encrypted data payload and the encrypted second seed are combined in a secure container, and subsequently all keys and seeds and the formula are destroyed.

A honeypot file is cryptographically secured with a cryptographic key. The key, or related key material, is then placed on a central keystore and the file is placed on a data store within the enterprise network. Unauthorized access to the honeypot file can then be detecting by monitoring use of the associated key material, which usefully facilitates detection of file access at any time when, and from any location where, cryptographic access to the file is initiated.