A security system that provides for secure communication from a remote system operating on an unsecure network without the need for encrypting the packets related to the communication. The packets for the communications are sent over the network in clear text, which are readable by any systems on the network, however, only the systems that are authorized are able to determine what packets are the correct packets and what packets are the imitation packets. Moreover, a remote secure network may be utilized such that any system operating on an unsecure network may send packets through the remote secure network in a randomized routing in order to aid in hiding the systems sending and receiving the packets and the relays through which the packets are being sent.

A security system that provides for secure communication from a remote system operating on an unsecure network without the need for encrypting the packets related to the communication. The packets for the communications are sent over the network in clear text, which are readable by any systems on the network, however, only the systems that are authorized are able to determine what packets are the correct packets and what packets are the imitation packets. Moreover, a remote secure network may be utilized such that any system operating on an unsecure network may send packets through the remote secure network in a randomized routing in order to aid in hiding the systems sending and receiving the packets and the relays through which the packets are being sent.

A user device having a security context with a first network based on a first key may establish a security context with a second network. In a method, the user device may generate a key identifier based on the first key and a network identifier of the second network. The user device may forward the key identifier to the second network for forwarding to the first network by the second network to enable the first network to identify the first key at the first network. The user device may receive a key count from the second network. The key count may be associated with a second key forwarded to the second network from the first network. The user device may generate the second key based on the first key and the received key count thereby establishing a security context between the second network and the user device.

A user device having a security context with a first network based on a first key may establish a security context with a second network. In a method, the user device may generate a key identifier based on the first key and a network identifier of the second network. The user device may forward the key identifier to the second network for forwarding to the first network by the second network to enable the first network to identify the first key at the first network. The user device may receive a key count from the second network. The key count may be associated with a second key forwarded to the second network from the first network. The user device may generate the second key based on the first key and the received key count thereby establishing a security context between the second network and the user device.

Disclosed herein are a health device, a gateway device, and a method for securing a protocol using the health device and the gateway device. The method includes performing, by the health device and the gateway device, authentication and key exchange based on security session information; sending, by any one of the health device and the gateway device, an application message protected based on the security session information; and receiving, by a remaining one of the health device and the gateway device, the protected application message.

A method for configuring multiple electronic devices in a batch, is described. The method can include initializing, by a first computing device a communication network based on a pre-defined configuration parameter. The pre-defined configuration parameter is associated with a first instance of an application on the first computing device. Further, the method includes identifying, by the first computing device, an initialization of a second instance of an application at a second computing device. In response to identifying the initialization of the second instance of the application at the second computing device, the method includes, sending, by the first computing device configuration settings for the second computing device over a secured communication network. In this regard, the configuration settings can comprise at least the pre-defined configuration parameter for configuring the second computing device.

Systems and methods for connecting a private device to a public device based on various connection parameters. For example, a media guidance application may receive a communication requesting to use the public device from a private device that is implementing a private interface application (e.g., Netflix™ a streaming media application). In response, the media guidance application may generate an authorization key that is unique to the private device and comprises connection parameters. The media guidance application may transmit the authorization key to the private interface application to initiate a session between the public device and the private device. Whenever a command is received from the private device, the media guidance application may verify the authorization key and determine whether the connection parameters are satisfied. In response to verifying the authorization key and the connection parameters, the public device may execute the received command.

An apparatus is disclosed for storing a private key on an IoT device for encrypted communication with an external user device and includes a proximity-based communication interface, encryption circuitry and IoT functional circuitry. The encryption circuitry includes a memory having a dedicated memory location allocated for storage of encryption keys utilized in the encrypting/decrypting operations, an encryption engine for performing the encryption/decryption operation with at least one of the stored encryption keys in association with the operation of the IoT functional circuitry, an input/output interface for interfacing with the proximity-based communication interface to allow information to be exchanged with a user device in a dedicated private key transfer operation, an internal system interface for interfacing with the IoT functional circuitry for transfer of information therebetween, memory control circuitry for controlling storage of a received private key from the input/output interface for storage in the dedicated memory location in the memory, in a Write-only memory storage operation relative to the private key received from the input/output interface over the proximity-based communication interface, the memory control circuitry inhibiting any Read operation of the dedicated memory location in the memory through the input/output interface. The IoT functional circuitry includes a controller for controlling the operation of the input/output interface and the memory control circuitry in a private key transfer operation to interface with the external user device to control the encryption circuitry for transfer of a private key from the user device through the proximity-based communication interface for storage in the dedicated memory location in the memory, the controller interfacing with the encryption circuitry via the internal system interface, and operational circuitry for interfacing with the user device over a peer to peer communication link and encrypting/decrypting information therebetween with the encryption engine in the encryption circuitry.

A network node of a mobile communications network may need to generate at least one new Input Offset Value, IOV value, for use in protecting communications between the network node and a mobile station. The network node then associates a fresh counter value with the or each new IOV value; calculates a Message Authentication Code based on at least the at least one new IOV value, the fresh counter value associated with the or each new IOV value, and a constant indicating that the Message Authentication Code is calculated to protect the new IOV value; and transmits the at least one new IOV value, the fresh counter value associated with the or each new IOV value, and the calculated Message Authentication Code to the mobile station.

A network node of a mobile communications network may need to generate at least one new Input Offset Value, IOV value, for use in protecting communications between the network node and a mobile station. The network node then associates a fresh counter value with the or each new IOV value; calculates a Message Authentication Code based on at least the at least one new IOV value, the fresh counter value associated with the or each new IOV value, and a constant indicating that the Message Authentication Code is calculated to protect the new IOV value; and transmits the at least one new IOV value, the fresh counter value associated with the or each new IOV value, and the calculated Message Authentication Code to the mobile station.