Briefly, in accordance with one or more embodiments, an apparatus of a user equipment (UE), comprises one or more baseband processors to derive a dynamic scrambling key, and a memory to store the dynamic scrambling key and a temporary UE identifier (temporary UE ID) assigned to the UE. The one or more baseband processors monitor a paging request for a scrambled UE identifier (UE ID) to determine if the paging request is intended for the UE by unscrambling the scrambled UE ID with the dynamic scrambling key to produce the temporary UE ID. The paging request is intended for the UE if the temporary UE ID produced by unscrambling the scrambled UE ID matches the temporary UE ID stored in the memory. A new dynamic scrambling key may be derived each time the UE returns to a radio resource control idle (RRC_IDLE) state.

A communication system for resuming a connection comprises a user equipment (UE) and network nodes. A first network node is configured to prepopulate a UE context, and send, to a second network node, the UE context. The second network node is configured to receive, from the first network node, the UE context, and send, to a UE, a resume request message including a freshness parameter and the UE context. The UE is configured to receive, from the second network node, a resume request message including the freshness parameter and the UE context, generate an authentication token based on the freshness parameter and the UE context, and send, to the second network node, a resume response message including the authentication token. The communication system provides a freshness parameter and a prepopulated UE context to secure and facilitate resume procedure against replay attacks.

Example embodiments provide systems and methods for securing a deployed camera. A security apparatus is coupled to the deployed camera and accesses video content from the coupled camera. The security apparatus accesses video content from the coupled camera, splits the video content within a plurality of RTP packets, encrypts payloads of the RTP packets, embeds in a header of the encrypted RTP packets, at least two key identifications for decryption of the encrypted RTP packets, and transmits the plurality of RTP packets over a network to a video management system.

An electronic device (such as an IoT controller) that distributes a link key is described. During operation, while an administrator is logged in, the electronic device may receive the link key using a secure widget, where the link key may facilitate secure communication via a link. Then, the electronic device may generate an access key, and may generate an encrypted version of the link key based at least in part on the access key and the link key, where the access key enables access to the link key based at least in part on the encrypted version of the link key. Next, the electronic device may store the link key, the access key and/or the encrypted version of the link key in a trusted envelope or partition in the memory with encryption. Moreover, when the administrator logs out, the electronic device may disable access to the trusted envelope.

Embodiments of this application provide a key update method and a related apparatus. One example method includes: sending a first key update request to a second node, where the first key update request includes a first key negotiation parameter and first identity authentication information, and the first identity authentication information is generated by using a first shared key; receiving a first response message from the second node, where the first response message includes second identity authentication information; performing verification on the second identity authentication information by using the first shared key; and if the verification on the second identity authentication information succeeds, determining a first target key based on the first key negotiation parameter.

In one embodiment, a method comprises: securing, by a security agent executed within a network device, first secure data structures for secure storage in the network device and second secure data structures for secure communications in a secure peer-to-peer data network; monitoring, by the security agent, a corresponding mandatory lifecycle policy for each of the first secure data structures; and cryptographically erasing one of the first secure data structures in response to expiration of the corresponding mandatory lifecycle policy.

A system and method for providing remote access to a device is disclosed. The method comprises receiving an automatically expiring authentication token having encrypted authentication token data including a session key from the device, transmitting the authentication token to secure facility, receiving the decrypted authentication token data from the secure facility, signing a tool package with a package verification key derived at least in part from the session key, the tool package comprising processor instructions providing remote access to the device when executed by the processor, providing the signed tool package to the device. The device verifies the signed tool package using the package verification key and executes the tool package only if the signature of the tool package is verified.

A network device may establish a media access control security (MACsec) key agreement (MKA) session with another network device via a MACsec communication link; establish a fast heartbeat session via the MACsec communication link, between a first packet processing engine of the network device and a second packet processing engine of the other network device, where the fast heartbeat session is to permit the first packet processing engine and the second packet processing engine to exchange fast heartbeat messages via the fast heartbeat session and the MACsec communication link; place an MKA protocol of the MKA session in a pause state until the first packet processing engine detects a rekey event; determine that a key for the MKA session is to be regenerated based on detection of the rekey event; and perform an action based on the rekey event for the MKA session.

A Secure/Multipurpose Internet Mail Extensions (S/MIME) key material publication system that converts cryptographic material extracted from digitally signed and validated S/MIME messages it receives into key material formats suitable for populating email address books. Publication of the address book contents both internal and external to an organization is done using the standard address book lightweight database access protocol (LDAP). The wide availability and coordination of such automated address books distributing key material across the Internet allows the large installed base of S/MIME email clients to immediately send secure encrypted email across organizational boundaries. The system serves the role of public key server thus removing a barrier to ubiquitous secure encrypted email by simplifying global key management.

One embodiment of the present invention includes a server machine configured to establish a secure communication channel with a client machine via renewable tokens. The server machine receives a plurality of messages from a client machine over a secure communication channel, where the plurality of messages includes a first message that includes at least two of user authentication data, entity authentication data, first key exchange data, and encrypted message data. The server machine transmits, to the client machine, a second message that includes a master token comprising second key exchange data associated with the first key exchange data and at least one of a renewal time and an expiration time.