A Data Protection Server (DPS) configured to authenticate, encrypt and decrypt blocks of data by using dynamic tokens. Instances of a DPS may be deployed in association with a host server and with multiple client devices to protect data exchanged between them. Since each DPS instance typically requires minimal device storage and computational resources, use of a DPS may be particularly advantageous in connection with the protection of data generated by limited resources devices.

A Data Protection Server (DPS) configured to authenticate, encrypt and decrypt blocks of data by using dynamic tokens. Instances of a DPS may be deployed in association with a host server and with multiple client devices to protect data exchanged between them. Since each DPS instance typically requires minimal device storage and computational resources, use of a DPS may be particularly advantageous in connection with the protection of data generated by limited resources devices.

The present application describes a method, system, and non-transitory computer-readable medium for exchanging encrypted communications using hybrid encryption. According to the present disclosure, a first device receives an encrypted communication from a second device. The encrypted communication includes a first encrypted secret, a second encrypted secret, a first signature, and a second signature. The first device verifies the first signature and the second signature, and, when the first and second signatures are valid, decrypts the first encrypted secret using a first encryption algorithm and the second encrypted secret using a second encryption algorithm. The first device combines the first decrypted secret and the second decrypted secret to recover a first communication and provides the first communication to a user of the first device.

The present application describes a method, system, and non-transitory computer-readable medium for exchanging encrypted communications using hybrid encryption. According to the present disclosure, a first device receives an encrypted communication from a second device. The encrypted communication includes a first encrypted secret, a second encrypted secret, a first signature, and a second signature. The first device verifies the first signature and the second signature, and, when the first and second signatures are valid, decrypts the first encrypted secret using a first encryption algorithm and the second encrypted secret using a second encryption algorithm. The first device combines the first decrypted secret and the second decrypted secret to recover a first communication and provides the first communication to a user of the first device.

A key server network device may install, on the key server network device, a new decryption key based on a timer-based key rollover setting and may provide, to peer network devices, messages identifying the new decryption key. The key server network device may utilize an original encryption key, to encrypt traffic, until all of the peer network devices provide acknowledgements of installation of the new decryption key. The key server network device may be configured to utilize the original encryption key based on the timer-based key rollover setting. The key server network device may generate an alarm. The alarm may include information indicating that the key server network device is waiting for the acknowledgements from one or more peer network devices and information identifying the one or more peer network devices.

The disclosure provides an approach for certificate management for cryptographic agility. Embodiments include receiving, by a cryptographic agility system, a cryptographic request related to an application. Embodiments include selecting, by the cryptographic agility system, a cryptographic technique based on contextual information associated with the cryptographic request. Embodiments include determining, by the cryptographic agility system, based on the cryptographic request, a certificate for authenticating a key related to the cryptographic technique. Embodiments include providing, by the cryptographic agility system, the certificate to an endpoint related to the cryptographic request for use in authenticating the key.

The disclosure provides an approach for auditable cryptographic agility. Embodiments include receiving, by a cryptographic agility system, a request to perform a cryptographic operation related to an application. Embodiments include selecting, by the cryptographic agility system, a cryptographic technique for performing the cryptographic operation based on contextual information associated with the request. Embodiments include performing, by the cryptographic agility system, the cryptographic operation using the cryptographic technique. Embodiments include writing, by the cryptographic agility system, data related to selecting the cryptographic technique to a secure digital ledger.

Systems and methods provide a transient component limited access to data in a composition. One method includes receiving a request for the transient component to access data in the composition. The composition may include permanent components operable to utilize encryption keys generated at selected intervals from a seed value shared by the permanent components. The encryption keys utilized by the permanent components at each selected interval may be identical to one another. The method also includes generating a set of encryption keys from the seed value for a specified period of time. The set of encryption keys may be identical to the encryption keys to be utilized by the permanent components at the selected intervals to occur during the specified period of time. The method further includes granting the transient component access to data in the composition for the specified period of time via the set of encryption keys.

In one implementation, a method for providing end-to-end communication security for a controller area network (CANbus) in an automotive vehicle across which a plurality of electronic control units (ECU) communicate is described. Such an automotive vehicle can include, for example, a car or truck with multiple different ECUs that are each configured to control various aspects of the vehicle's operation, such as an infotainment system, a navigation system, various engine control systems, and/or others.

In one implementation, a method for providing end-to-end communication security for a controller area network (CANbus) in an automotive vehicle across which a plurality of electronic control units (ECU) communicate is described. Such an automotive vehicle can include, for example, a car or truck with multiple different ECUs that are each configured to control various aspects of the vehicle's operation, such as an infotainment system, a navigation system, various engine control systems, and/or others.