Connected tractor and trailer identifications and the order of hook-up of multiple trailers to a tractor is are determined by identifying trailer VINs using a PLC system and eliminating Bluetooth signals that do not broadcast trailer VINs that match the PLC system. A tractor-based Bluetooth trailer order and a trailer-based Bluetooth trailer order utilizing RSSI value strengths are determined. The trailer order is set if the tractor-based Bluetooth trailer order matches the trailer-based Bluetooth order. If the order does not match, a RSSI value weighting process is used to choose between the tractor-based order and the trailer-based order.

A data transfer method includes that a first device displays a first interface. The first interface includes image information of a first file. When a distance between a Near-Field Communication (NFC) chip of the first device and an electronic tag of a second device is less than a preset threshold, the first device obtains a BLUETOOTH address of the second device. The electronic tag includes device information of the second device, and the device information includes the BLUETOOTH address or a tag identifier (ID) used to obtain the BLUETOOTH address. The first device exchanges a WI-FI connection parameter with the second device through a BLUETOOTH connection corresponding to the BLUETOOTH address. The first device establishes a WI-FI connection to the second device. After the WI-FI connection is established, the first device automatically transfers the first file to the second device through the WI-FI connection.

Described are methods and devices for communication between local networks and global networks. In some examples, a method comprises storing mapping data for multiple hosts in a global network and in a local network. The method further comprises receiving a first data packet from one of the multiple hosts in the local network. The first data packet comprises a first source address being the local network address of the host in the local network, a first destination address being the local network address of the host in the global network and payload data. The method further comprises determining, based on the mapping data, the global network address of the host in the local network and a global network address of the host in the global network, and sending a second data packet over the global network.

The disclosure relates to a wireless peripheral for wireless communication with a master device. Example embodiments disclosed include a wireless peripheral for wireless communication with a master device and comprising a first peripheral device and a second peripheral device, wherein: at least one of the first peripheral device (500a) and the second peripheral device is arranged to communicate with the master device (100) by transmitting and receiving first wireless signals conveying first packets occupying transmit and receive time slots comprising inter-frame space; and the first peripheral device and the second peripheral device are arranged to communicate with each other by transmitting and receiving second wireless signals conveying second packets within said inter-frame space.

In embodiments of efficient network stack for wireless application protocols, a network stack receives an application-layer message in a first wireless application protocol that includes a source address and a destination address, maps the source address to an Internet Protocol version 6 (IPv6) source address, and maps the destination address to an IPv6 source address. The source node transmits the application-layer message to a destination node in a mesh network using a network stack that implements a second wireless application protocol using the IPv6 source address, and maps the destination address to an IPv6 source address.

In an example, a collection of compute resources corresponding to a class of devices is identified with a request and a synthesis routine is performed via a number of destinations corresponding to the class of devices. In an example, a type of compute resource to use with an operation of a request is determined, a device with the type of compute resource determined for the operation of the request is identified; the identified device performs the operation of the request within a bounds of a policy, and a result of the operation is communicated to a remote storage location.

A method (50) of and a server (19) and network node or client devices (3, 5) communicatively interconnected in a network (1) and arranged for over-the-air, OTA, data upgrade or update of client devices. In the event of a timeout (54) at the server (19) waiting for a response or request message from a selected OTA client (5) during an ongoing OTA data upgrade, the OTA server (19) checks whether a network address change (51) of the selected OTA client (5) caused the OTA server to timeout.

A network coordinator device comprises a processor, a memory, a first port to operatively couple the processor to first network that uses media access control (MAC) addresses of a first size, and a second port to operatively couple the processor to second network that uses MAC addresses of a second size. The processor is configured to perform a network bridging protocol to bridge data frames communicated between the first network and the second network, including to translate communications between a device of the first network having the first size MAC address and a device of the second network having the second size MAC address, and adapt a frame format of the first network protocol to a frame format of the second network protocol. The adapting the frame formatting includes fragmenting data frames of the first network protocol when needed using a fragmentation format of the second network protocol.

A home automation (HA) system may include addressable HA devices and a user interface device configured to permit user social networking and generate user social networking data based thereon. The HA system may also include a controller and a memory coupled thereto and configured to store measured user health data and determine user physical activity data based upon the addressable HA devices. The controller and the memory may be configured to generate a user health score based upon the user social networking data, user health data, and user physical activity data and communicate the user health score via the cloud.

Disclosed are systems and methods for adjusting environmental conditions based on automatically and manually generated requests. A commissioned unit comprising at least one IP luminaire (140, 150), transmits a signal comprising one or more identification codes. The signal may be, for example, a coded light signal. An environment control device (160) receives the signal, detects user input indicating one or more preferred environmental conditions, and transmits an environment control request comprising the one or more preferred environmental conditions. An environment manager module (110) receives the environment control request, generates an environment control command using the control request, and transmits the environment control command to one or more commissioned units to alter environmental conditions in a space in accordance with the user input.