Abstract: The present disclosure provides systems for updating firmware of a CIoT device. The CIoT device activates, based on one or more activation commands received by the first receiver and the second receiver. The CIoT device connects by the second receiver and the second transmitter, to a device. The CIoT device receives, by the second receiver, from the device, a firmware upgrade file. A CIoT device deactivates the second receiver.

Abstract: Apparatuses, methods, and computer readable media for secure discovery and connection to internet of things devices in a wireless local-area network are disclosed. An apparatus of a station comprising processing circuitry is disclosed. The processing circuitry may be configured to: encode a first packet to indicate to an access point to start discovery of Internet of Things (IoT) devices, and decode a second packet from the access point. The second packet may include identifications of IoT devices unauthenticated with the access point. The processing circuitry may be configured to receive a selection from an application of the station of one of the one or more identifications of the IoT devices, and encode a third packet including the identification of the IoT device and an indication that the access point is to request establishment of a secure session with the IoT device.

Abstract: This document discusses, among other things, a Cellular Internet-of-Things (CIoT) network architecture to enable communication between an apparatus of a CIoT User Equipment (UE) and a network through a CIoT enhanced Node B (eNB) according to a lightweight Non-Access Stratum (NAS) protocol. An apparatus of a CIoT eNB can process data for communication between the CIoT UE and the network. The lightweight NAS protocol supports a reduced set of NAS messages for communication between, for example, the CIoT UE and the CIoT eNB, such as using a modified NAS message, or one or more new messages.

Abstract: Described herein are architectures, platforms and methods for dynamic re-distribution of magnetic fields in a device during near field communication (NFC) related functions or transactions and/or wireless charging.

Abstract: This disclosure describes systems, methods, and apparatus related to receiving, at an access point and from a wireless communication station, a media access control (MAC) address of the wireless communication station; assigning, at the access point, a prefix to the MAC address of the wireless communication station; receiving, at the access point and from the wireless communication station, a frame comprising the prefix and a random MAC address; replacing, at the access point and using the prefix, the random MAC address in the frame with the MAC address of the wireless communication station, thereby resulting in a processed frame; and transmitting, at the access point and to a destination device, the processed frame.

Abstract: Disclosed herein is a computing device configured to send display data to a display through a near-field communication (NFC) interface. The computing device includes a chassis, a primary display, and a near-field communication interface to transmit display data to a secondary display.

Abstract: Generally discussed herein are systems, apparatuses, and methods that can provide a key authentication and identity verification in a D2D communication regime. A method can include providing a first public key of a first D2D device to a second D2D device and receiving a second public key of the second D2D device, providing a connection request packet to the second D2D device including a first attested key and a third public key, the first attested key including the first public key signed using a private key of a public key attestation service (PAS), receiving a connection accept packet from the second D2D device including a second attested public key, and a fourth public key, the second attested public key including the second public key signed using the private key of the PAS, and verifying the identity of the second D2D device using the received keys.

Abstract: A user equipment (UE) is configured to send a direct communication request to a peer UE, wherein the direct communication request comprises a signature authenticating an identity of the UE. The UE is configured to process a direct communication response from the peer UE to authenticate an identity of the peer UE, wherein the direct communication response comprises a signature authenticating the identity of the peer UE. In response to processing the direct communication response from the peer UE to authenticate the identity of the peer UE, the UE is configured to engage in direct communication with the peer UE.

Abstract: Device to device (D2D) communication can be performed with packet data convergence protocol (PDCP) based encapsulation without internet protocol (IP) addressing. The non-IP D2D PDCP-encapsulated communication can further include two forms of secure data transfer. A first non-IP D2D PDCP-encapsulated communication can be a negotiated non-IP D2D PDCP-encapsulated communication. A second non-IP D2D PDCP-encapsulated communication can be a non-negotiated non-IP D2D communication. The non-negotiated non-IP D2D PDCP-encapsulated communication can include a common key management server (KMS) version and a distributed KMS version. The encapsulated communication can be used with various protocols, including a PC5 protocol (such as the PC5 Signaling Protocol) and wireless access in vehicular environments (WAVE) protocols.

Abstract: Various systems and methods for locking computing devices are described herein. In an example, a portable device comprises an electro-mechanical lock; and a firmware module coupled to the electro-mechanical lock, the firmware module configured to: receive an unlock code; validate the unlock code; and unlock the electro-mechanical lock when the unlock code is validated. In another example, device for managing BIOS authentication, the device comprising an NFC module, the NFC module comprising an NFC antenna; and a firmware module, wherein the firmware module is configured to: receive an unlock code from an NFC device via the NFC antenna; validate the unlock code; and unlock a BIOS of the device when the unlock code is validated.

Abstract: A cellular IoT (CIoT) device can comprise a coverage and/or processing constrained device e.g., devices operating primarily MTC or M2M (e.g., sensor devices, controller devices, etc.). These devices can have limited or no user interface, and can be used for machines or devices with little mobility. CIoT devices can be deployed in usage scenarios such as home automation (e.g., security, appliances, energy packages, etc.), industry automation, and smart cities with low-power devices (e.g., devices having a battery life of several years), and can be easily installed and operated in challenging coverage conditions, such as lower or basement levels of buildings. CIoT devices can be provisioned to connect to a cellular carrier network and an associated CSP. The CSP can execute end2end solutions (e.g., service portal, service sign-up, etc.) while the cellular carrier can provide the bulk data pipe to the CSP.

Abstract: Methods and apparatus to support secure Wi-Fi AP protocols are disclosed. An example method includes in response to receiving a request from a computing device to connect to a network, limiting, with a processor of a Wi-Fi access point, access of the computing device to the network to connect to a server; authenticating, with the processor of the Wi-Fi access point, the computing device based on data received from the server; and expanding, with the processor of the Wi-Fi access point, the access of the computing device to connect to the network.

Abstract: Described herein are architectures, platforms and methods for dynamic amplification/boosting of near field communications (NFC) antenna transmission power in a device during NFC related functions that require increase in an NFC antenna transmission power such as a payment transaction. For example, to comply with Europay MasterCard and Visa (EMVco) standards with regard to higher NFC antenna transmission power during the EMVco transactions, the NFC antenna transmission power may be dynamically controlled to maximize efficiency of a battery/power supply of the device.

Abstract: Methods and devices for NFC-tap file encryption, decryption and access via Near Field Communication (NFC) are disclosed. A user can select an unencrypted file stored in a computing device for encryption. Upon encryption, the file name of the selected file and the encryption key used to encrypt the selected file are transmitted to an NFC-enabled wireless device for storage. The user can select an encrypted file stored in the computing device for access. As the user taps the computing device with the wireless device, the file name of the selected file is transmitted to the wireless device, which in turn transmits a decryption key for decrypting the selected file to the computing device. The computing device decrypts the selected file with the decryption key. The user can now access the decrypted file.

Abstract: Methods and devices for NFC-tap file encryption, decryption and access via Near Field Communication (NFC) are disclosed. A user can select an unencrypted file stored in a computing device for encryption. Upon encryption, the file name of the selected file and the encryption key used to encrypt the selected file are transmitted to an NFC-enabled wireless device for storage. The user can select an encrypted file stored in the computing device for access. As the user taps the computing device with the wireless device, the file name of the selected file is transmitted to the wireless device, which in turn transmits a decryption key for decrypting the selected file to the computing device. The computing device decrypts the selected file with the decryption key. The user can now access the decrypted file.

Abstract: Device to device (D2D) communication can be performed with packet data convergence protocol (PDCP) based encapsulation without internet protocol (IP) addressing. The non-IP D2D PDCP-encapsulated communication can further include two forms of secure data transfer. A first non-IP D2D PDCP-encapsulated communication can be a negotiated non-IP D2D PDCP-encapsulated communication. A second non-IP D2D PDCP-encapsulated communication can be a non-negotiated non-IP D2D communication. The non-negotiated non-IP D2D PDCP-encapsulated communication can include a common key management server (KMS) version and a distributed KMS version. The encapsulated communication can be used with various protocols, including a PC5 protocol (such as the PC5 Signaling Protocol) and wireless access in vehicular environments (WAVE) protocols.

Abstract: Device to device (D2D) communication can be performed with packet data convergence protocol (PDCP) based encapsulation without internet protocol (IP) addressing using a PC5 protocol (such as PC5 Signaling Protocol). The non-IP D2D PDCP-encapsulated communication can further include two forms of secure data transfer. A first non-IP D2D PDCP-encapsulated communication can be a negotiated non-IP D2D PDCP-encapsulated communication. A second non-IP D2D PDCP-encapsulated communication can be a non-negotiated non-IP D2D communication. The non-negotiated non-IP D2D PDCP-encapsulated communication can include a common key management server (KMS) version and a distributed KMS version.

Abstract: A cellular IoT (CIoT) device can comprise a coverage and/or processing constrained device e.g., devices operating primarily MTC or M2M (e.g., sensor devices, controller devices, etc.). These devices can have limited or no user interface, and can be used for machines or devices with little mobility. CIoT devices can be deployed in usage scenarios such as home automation (e.g., security, appliances, energy packages, etc.), industry automation, and smart cities with low-power devices (e.g., devices having a battery life of several years), and can be easily installed and operated in challenging coverage conditions, such as lower or basement levels of buildings. CIoT devices can be provisioned to connect to a cellular carrier network and an associated CSP. The CSP can execute end2end solutions (e.g., service portal, service sign-up, etc.) while the cellular carrier can provide the bulk data pipe to the CSP.

Abstract: Apparatuses, methods, and computer readable media for secure discovery and connection to internet of things devices in a wireless local-area network are disclosed. An apparatus of a station comprising processing circuitry is disclosed. The processing circuitry may be configured to: encode a first packet to indicate to an access point to start discovery of Internet of Things (IoT) devices, and decode a second packet from the access point. The second packet may include identifications of IoT devices unauthenticated with the access point. The processing circuitry may be configured to receive a selection from an application of the station of one of the one or more identifications of the IoT devices, and encode a third packet including the identification of the IoT device and an indication that the access point is to request establishment of a secure session with the IoT device.

Abstract: A network device determines the traffic specification values based on the session values that represent the application parameters of an application, which is provided differentiated service levels. A user of the network device may provide and/or choose the session values. The network device may generate one or more streams corresponding to a plurality of the applications. Each stream may comprise one or more traffic instances. The network device may assign a priority value to each stream and instance identifier to each traffic instances within the stream to manage the transfer of data units.