Disclosed embodiments relate to distributed, crowd-sourced Internet of Things (IoT) discovery using Block Chain. In one example, a method includes scanning a network and generating a signature based on IoT device traits discovered, determining whether the signature is already in a verified or an unverified Block Chain, when the signature exists in the verified Block Chain, providing a verified entry including at least the IoT device type, otherwise, when the signature exists in the unverified Block Chain, providing an unverified entry including at least the IoT device type, incrementing a count, and promoting the unverified entry to the verified Block Chain when the count reaches a threshold, and otherwise, when the signature is in neither Block Chain, using the traits to guess the IoT device type, generating a new entry including the IoT device type, a location, and a timestamp, and storing the new entry in the unverified Block Chain.

A connected car and an onboard user equipment (UE) may establish independent cellular connections and may also establish a connection between each other. The UE establishes a first cellular link between the UE and a first network, establishes a connection with a connected car, wherein the connected car has a second cellular link between the connected car and a second network, evaluates one or more conditions and declares one of the first cellular link or the connection with the connected car a primary network interface for the UE based on, at least, the one or more conditions.

A facility for establishing a wireless connection between first and second devices is described. On the first device, the facility causes a one-time pairing code to be displayed, then wirelessly receives from the second device a wireless connection solicitation having contents. On the first device, in response to the receiving, the facility determines whether the contents reflect the one-time pairing code. In response to determining that the contents reflect the one-time pairing code, on the first device, the facility establishes the wireless connection between the first and second devices.

Systems and methods can support identifying pairings and channel parameters in short-range wireless communications such as bluetooth low energy interfaces. Radio frequency sensors may be positioned within an electromagnetic environment where a master wireless device and a slave wireless device share short-range wireless communications. Signals transmitted between the master wireless device and the slave wireless device can be received by the radio frequency sensors. Inter-arrival times for packets within the received signals may be identified. Statistics of the inter-arrival times can be analyzed to identify connection intervals between the master wireless device and the slave wireless device as well as back-to-back interval exchanged within the connection intervals. Packet header contents may be used to reconcile the estimated timing parameters and time slots. Pairings between the master wireless device and the slave wireless device may be identified and tracked along with communication channel parameters.

Techniques for establishing a bidirectional wireless communication link between two otherwise detachable devices when these devices are physically joined together for use as a physically joined device are provided. An example method includes receiving by a mobile computing device a short-range wireless signal from an RFID reader device; monitoring, by the mobile computing device, an RSSI associated with the signal from the RFID reader device; and establishing, by the mobile computing device, a wireless communication connection to the RFID reader device based on the measured RSSI associated with the signal from the RFID reader device being greater than a threshold RSSI value, wherein the threshold RSSI value is calibrated based on an RSSI value associated with the short-range wireless signal from the RFID reader device measured by the mobile computing device when the mobile computing device is physically joined to RFID reader device for use as a joined device.

An exemplary method for indexing transceivers uses wireless ranging functionality. The method includes determining a ranging distance between at least one transceiver and each other transceiver in a plurality of transceivers, determining a transceiver spatial distribution based on the ranging distance between at least one transceiver and each other transceiver in the plurality of transceivers, and indexing each transceiver by applying the transceiver spatial distribution to a spatial distribution map using an electronic control unit (ECU).

Wireless communications systems and methods related to discovery signaling for sidelink communication are provided. In one aspect, a first user equipment (UE) transmits, to a second UE in a first slot and a first portion of a subband of a shared frequency band, a synchronization communication, where the synchronization communication indicates a location of a discovery signal in a second portion of the subband of the shared frequency band. The first UE also transmits, to the second UE in the first slot and in the second portion of the subband of the shared frequency band, the discovery signal.

According to an example embodiment, an electronic device may include: a communication module comprising communication circuitry configured to exchange data with an external device and at least one processor operationally connected to the communication module and configured to control the electronic device, wherein, through the communication module, the processor may be configured to: receive a scan command from a first main device using a first wireless communication link in a first frequency band, detect at least one external electronic device by performing a scan of a second frequency band based on the scan command, transmit a detection result of the external electronic device to the first main device using the first wireless communication link, receive an establishment command to establish a wireless link with the external electronic device from the first main device using the first wireless communication link, establish the wireless link with the external electronic device using the second frequency band based on the establishment command to establish the wireless link with the external electronic device, and transmit a result of the establishment of the wireless link to the first main device using the first wireless communication link, data may be exchanged between the first main device and the electronic device via the first wireless communication link and data may be exchanged between the external electronic device and the electronic device via the wireless link.

Provided is an electronic device and method for receiving identification information about a mobile device from the mobile device, determining based on the identification information, the mobile device as a peer device for performing an operation of the electronic device along with, or instead of, the electronic device, and determining at least one from among the peer device and the electronic device, the determined at least one performing the operation of the electronic device, based on a condition of the electronic device.

A machine localization system includes a work machine including an extendable implement, a first pressure sensor coupled to the work machine, a second pressure sensor located at a known elevation, and a computing system operably coupled to the work machine, the first pressure sensor, and the second pressure sensor. The computing system is configured to receive a first pressure measurement from the first pressure sensor and a second pressure measurement from the second pressure sensor, determine a maximum operating height of the extendable implement based on a difference between the first pressure measurement and the second pressure measurement, and configure the extendable implement to not exceed the maximum operating height.