An apparatus including a processor and a memory, where the processor and the memory are configured to provide a secure execution environment and the memory stores a hardware unique key and a class key. The processor is configured to recover, in the secure execution environment, a certificate signing key based on the class key, where the certificate signing key is associated with a certificate authority. The processor is further configured to derive a device key pair based on the hardware unique key, where the device key pair includes a device public key and a device private key, and generate a device certificate based on the device public key and the certificate signing key. The generated device certificate is configured to be validated based on a public key associated with the certificate authority.

A challenge/response authentication procedure determines whether a response is a correct response, a unique incorrect response, or a non-unique incorrect response, the unique incorrect response and non-unique incorrect response being differentiated by comparing the response value with a store of unique incorrect response values. For the correct response, client access to protected computer system resources is allowed, and the challenge value is discarded so as not to be used again. For the unique incorrect response, (1) when a predetermined limit of unique incorrect responses has not been reached, then the response value is added to the store of unique incorrect response values and the process is repeated with reuse of the challenge value, and (2) when the predetermined limit has been reached, then the client is locked out. For the non-unique incorrect response, the process is repeated with reuse of the challenge value.

A communication device for handling data transmission/reception for dual connectivity comprises a storage unit for storing instructions of connecting to a first base station (BS) and a second BS; receiving a message from the first BS, wherein the message configures a handover to a third BS and a connection change to a fourth BS; updating a first parent key to a first updated parent key and updating a second parent key to a second updated parent key based on the first updated parent key, in response to the message; updating a first security key to a first updated security key based on the first updated parent key and updating a second security key to a second updated security key based on the second updated parent key, in response to the message.

In an aspect, a network supporting client devices includes one or more network nodes implementing network functions. Such network functions enable a client device to apply a security context to communications with the network when the client device is not in a connected mode. The client device obtains a user plane key shared with a user plane network function implemented at a first network node and/or a control plane key shared with a control plane network function implemented at a second network node. The client device protects a data packet with the user plane key or a control packet with the control plane key. The data packet includes first destination information indicating the first network node and the control packet includes second destination information indicating the second network node. The client device transmits the data packet or control packet.

In one aspect, a system for managing data processes in a network of computing resources is configured to: receive, from an instructor device, a parent request for execution of at least one parent data process executable by a plurality of computing resources at least one computing resource; generate at least one child request for execution of at least one corresponding child data process for routing to at least one corresponding destination device, each of the at least one child data process for executing at least a portion of the at least one parent data process, and each of the at least one child request including a respective destination key derived from at least one instructor key; and route each of the at least one child request to the at least one corresponding destination device. The at least one child request can be obtained by a supervisor server via the routing.

The present disclosure relates to a secure transmitting and receiving method that crates a dynamic key on the basis of the features of real-time data, thereby performing authentication operation. A secure transmitting method for real time data according to an embodiment of the present disclosure includes: collecting an n-th datum; compressing the n-th datum; creating and storing an n-th dynamic key in a memory on the basis of a feature extracted in the compressing; creating an n-th security key using an n-m-th dynamic key stored in the memory and transmitting the n-th security key to a server; and transmitting the compressed n-th datum to the server when receiving an authentication success signal from the server.

Techniques for deriving a WLAN security context from an existing WWAN security context are provided. According to certain aspects, a user equipment (UE) establishes a secure connection with a wireless wide area network (WWAN). The UE may receive from the WWAN an indication of a wireless local area network (WLAN) for which to derive a security context. The UE then derives the security context for the WLAN, based on a security context for the WWAN obtained while establishing the secure connection with the WWAN and establishes a secure connection with the WLAN using the derived security context for the WLAN. This permits the UE to establish a Robust Security Network Association (RSNA) with the WLAN while avoiding lengthy authentication procedures with an AAA server, thus speeding up the association process.

A plurality of keys is obtained, with each obtained key of the plurality of keys being based at least in part on an information set for the plurality of keys and at least one other key distinct from the plurality of keys. A signing key is calculated by inputting a combination of the plurality of keys into a function with the information set for the plurality of keys, and the signing key is used to evaluate whether access to one or more computing resources is to be granted, with the information set preventing access from being granted when a request for the access is submitted out of compliance with the information set for the plurality of keys.

A method for generating cryptograms in a webservice environment includes: receiving, in a first environment of a computing system, a credential request transmitted by an external computing device using a secure communication protocol, the credential request including a transaction identifier and account identifier; transmitting, by the first environment, a data request to a second environment of the computing system, the data request including the account identifier; receiving, by the first environment, an account profile and session key from the second environment; transmitting, by the first environment, a cryptogram request to a third environment of the computing system, the cryptogram request including the account profile and session key; receiving, by the first environment, a cryptogram from the third environment generated using the account profile and session key; and transmitting, by the first environment, the cryptogram and transaction identifier to the external computing device via the secure communication protocol.

A method, apparatus, article of manufacture, and a memory structure for providing a security infrastructure that permits the programming of limited hardware resources that can accept newly downloaded applications and securely support a very large number of services offered by content providers each have the potential to utilize their own independent CAS/DRM system. The CE device owner can consume content from a variety of sources and enable switching among different and existing CAS/DRM security profiles as required by the content provider applications loaded in CE devices.