An example Smart Candle Platform is configured to includes a candle fixture that comprises an outer shell having an opening, a mid-frame, and a base, and a fuel bottle configured to hold a fuel material and is removably coupled to the candle fixture. The fuel bottle is positioned at least partially within a hollow interior of the mid-frame of the candle fixture and accommodated by the base. The fuel bottle further comprises a wick that extends through an opening of the outer shell, and the candle fixture includes an ignitor configured to ignite the fuel material via the wick to produce a living flame. The candle fixture further includes an inner cover having one or more reinforcement ribs configured to provide structural support for the one or more ignitors.

A building automation system and method is provided for isolating device communications in a BACnet/IP building automation network. The system may comprise at least one processor in a BACnet device configured via executable instructions included in at least one memory to communicate UDP messages for field devices onto an Ethernet network for receipt by at least one other BACnet device on the Ethernet network. The at least one processor may be configured to receive and store in a memory a configurable local subnet, a BACnet/IP UDP port, and a local UDP port. The at least one processor may also be configured to determine a UDP message that is to be broadcast only on the local subnet. In addition, the at least one processor may be responsive to the determination, to broadcast the UDP message to BACnet devices on the same local subnet using the local UDP port stored in the memory.

An interface module for coupling data buses to first signal line ports, to which signal lines of at least one first data bus are connectable, and second signal line ports, to which signal lines of at least one second data bus are connectable, has at least one connecting device for making at least one connection between one of the first signal line ports and one of the second signal line ports. In this case, the first signal line port connected to the second signal line port is alternately connectable to at least one other second signal line port and/or the second signal line port connected to the first signal line port is alternately connectable to at least one other first signal line port. A related system has at least one such interface module and at least one apparatus that has the at least one first data bus and/or at the least one second data bus.

The present disclosure relates to a method for transmitting data packets from a transmitting device to a receiving device in a motor vehicle, the data packets being transmitted via a gateway device and, for this purpose, the gateway device receiving the data packets from the transmitting device and forwarding them to the receiving device. The invention provides that the data packets of the transmitting device are each addressed to an IP address and the gateway device in the data packets respectively replaces a first packet part, by which a connection layer of an Ethernet data connection is implemented, with a corresponding packet part of the bus protocol and, in a second packet part, by which a network layer with the IP address is implemented, retains the IP address and forwards the data packets with the IP address located in the second packet part to the receiving device.

A vehicle network system is disclosed. The vehicle network system includes a first controller area network (CAN) bus including a first node and a first secure transceiver and a second CAN bus including a second node and a second secure transceiver, a gateway to enable transmission of a CAN message from the first node to the second node. The vehicle network system also includes an auxiliary communication link to transmit an auxiliary data derived from the CAN message from the first secure transceiver to the second secure transceiver.

A communicating entities include one master entity, configured for communicating according to a first protocol at least, and a plurality of slave entities. The slave entities include a first group of slave entities able to support communications according to said first protocol and unable to support communications according to a second protocol, and a second group of slave entities able to support communications according to at least said second protocol. The first protocol is implemented by a token passing with communication data from the master entity to successively each neighbour slave entity, until the token reaches again the master entity, defining thus a first cycle according to the first protocol. The second protocol is implemented by passing a data frame including data intended to entities of said second group, one current entity of said second group, when receiving said data frame.

A fieldbus network is described, which has at least one device as well as a connecting apparatus, wherein the connecting apparatus is designed to transfer data from the fieldbus network into a cloud. Installed in at least one of the devices is a derived class, which is derived from a predetermined head class, wherein head attributes are established by the predetermined head class and additional device specific attributes are established by the derived class, wherein the at least one of the devices is designed based on the derived class to produce a data object for the data transfer to the cloud. The connecting apparatus is designed to receive the data object of the device, to convert at least a part of the data contained in the data object into a format of an interface of the cloud and to write the data into the cloud.

A system comprises a plurality of nodes connected in a peer-to-peer network via a communication interface. At least one node of the plurality of nodes comprises a transceiver, at least two connectors, at least one termination resistance module coupled to the transceiver, the at least one termination resistance module providing termination resistance within the node, a first detection circuit coupled to a first connector of the at least two connectors, and a second detection circuit coupled to a second connector of the at least two connectors. The first and second detection circuits are configured to detect that the node is coupled to one or more other nodes in the peer-to-peer network, and automatically adjust the termination resistance based on the detecting.

A Management Component Transport Protocol platform management subsystem includes an internal bridge, a first segment group, and a second segment group. The first segment group is coupled to the internal bridge. The second segment group is coupled to the internal bridge and the first segment group. The first segment group has a first plurality of Peripheral Component Interconnect Express (PCIe)-based buses. The second segment group has a second plurality of PCIe-based buses, wherein based on an identification (ID)-routed packet from the first segment group to the second segment group, the internal bridge routes the ID-routed packet to the second segment group.

A Smart Candle Platform may be configured to produce candle light using a natural wax candle as its fuel source or any other fuel source capable of producing light, including liquid fuels if so configured. The outer shell, inner cover, top cover and base provides a beautiful exterior shell which does not melt but emulates the look of a traditional pillar candle. The outer shell may be changeable/replaceable allowing for style and or seasonal changes. A Smart Candle Platform having multiple interactive systems and sensors for production of natural light via a safe, controllable device which may communicate with other similar configured devices or smart devices having application software embedded therein i.e. a smart phone having an app. is disclosed. The Smart Candle Platform may be configured to allow for auto-extinguishment. The Smart Candle Platform may be configured to allow for the addition of smells or scents.