Systems, apparatuses, and methods are described herein for a communication bus that virtualizes physiological data. Sensors and/or physiological data acquisition devices have different physical connectors which provide physiological data from a patient to a shared interface such as a display or patient monitor. A transfer interface within a mount can receive and interpret data streams associated with one or more physiological data acquisition devices. The transfer interface can prioritize the various data streams associated with the one or more physiological data acquisition devices and generate a single, combined data stream based on the assigned prioritization. The transfer interface can provide the combined data stream for transmission to a patient monitor via an interchangeable transport medium. Another transfer interface can process and/or virtualize the data streams from the physiological data acquisition devices.

A switch device includes: a plurality of communication ports; a switch unit configured to relay a frame, which has been transmitted from a function unit and to which information including an ID of a VLAN and priority information is added, to another function unit via a communication port, according to the priority information; and a duplication unit configured to, when the diagnosis device is connected to another switch device, duplicate the frame to be relayed via a designated communication port, thereby generating a duplicate frame for diagnosis. The duplication unit is able to set the priority information to be added to the duplicate frame for diagnosis, separately from the priority information to be added to the frame as an original. The switch unit outputs the duplicate frame for diagnosis, from a communication port corresponding to the other switch device, according to the priority information set by the duplication unit.

A VP is configured such that an ADS is installable in the VP. The VP includes a base vehicle and a VCIB. The VCIB acts as an interface between the base vehicle and the ADS by CAN communication. The VCIB includes a reception unit, an index value calculation unit, and a transmission unit. The reception unit receives a control request for the base vehicle from the ADS. The index value calculation unit calculates an index value showing a degree of congestion of the CAN communication. The transmission unit transmits the index value to the ADS.

A VP includes a base vehicle and a VCIB. The VCIB includes a reception unit, an index value calculation unit, a transmission unit, and a transmission plan setting unit. The reception unit receives a control request for the base vehicle from an ADS. The index value calculation unit calculates an index value showing a degree of congestion of CAN communication. The transmission unit transmits a control instruction for the base vehicle generated based on the control request to the base vehicle. The transmission plan setting unit sets a transmission plan of the control instruction to the base vehicle. The transmission plan setting unit sets the transmission plan according to a degree of priority of the control instruction in CAN communication and the index value.

Security system for protecting a vehicle electronic system by selectively intervening in the communications path in order to prevent the arrival of malicious messages at ECUs, in particular at the safety critical ECUs. The security system includes a filter which prevents illegal messages sent by any system or device communicating over a vehicle communications bus from reaching their destination. The filter may, at its discretion according to preconfigured rules, send messages as is, block messages, change the content of the messages, request authentication or limit the rate such messages can be delivered, by buffering the messages and sending them only in preconfigured intervals.

A frame is divided, and is then transferred on a communication protocol having a different frame size. Provided is a vehicle control device configured to transfer data through a first communication path for transferring data having a low priority and a second communication path for transferring data having a high priority, the second communication path having a transfer speed different from that of the first communication path. First transfer data transferable on the first communication path has a data size different from that of second transfer data transferrable on the second communication path. The second communication path allows at least two types of transfer data to be transmitted and received thereon. When the first transfer data is divided and is then transferred on the second communication path, the data is transferred by controlling at least one of a division size, the number of divisions, or a transfer timing of the first transfer data based on a timing cycle for transferring the second transfer data, a vacant time having no transfer, and a transfer time of the first transfer data on the second communication path.

Systems and methods for regulating communications in computing systems are provided. For instance, a computing system can include a first processing board including a first processing device and a first control device. The system can further include a second processing board including a second processing device and a second control device. The system can further include a communications interface communicatively coupled to the first processing board. The communications interface includes one or more input/output ports configured to facilitate communication between the avionics system and one or more external devices. The first control device of the first processing board is communicatively coupled to the second control device of the second processing board via a shared bus. The first control device is configured to regulate communications associated with the communications interface.

Various examples relate to a wired local area network (WLAN) including a shared transmission medium. An apparatus includes a beacon counter and an operational mode controller. The beacon counter is operably coupled to a line of a shared transmission medium of a wired local area network. The beacon counter is to count beacon signals on the line and determine a beacon count over a predetermined time period, or a beacon rate of the beacon signals. The operational mode controller is to control the apparatus to take over operation as a master node of the wired local area network based, at least in part, on a maximum bus cycle length of bus cycles on the line and responsive to the beacon count or the beacon rate.

A network node for coupling to a communication bus, the node comprising: a receiver configured to receive messages from the communication bus; and a transmitter configured to transmit first messages having a first message format and configured to transmit diagnosis messages having a second message format on the communication bus for use in determination of communication errors, wherein said transmitter is configured to send said one or more diagnosis messages having one or more of: (i) a predetermined pattern of symbols; (ii) a predetermined sending schedule; (iii) a predetermined line encoding method; (iv) a predetermined bit rate; (v) a predetermined position in one or more of the first messages; (vi) a predetermined signalling frequency that is out of a frequency band used for transmission of the first messages; and (vii) a predetermined signal strength different from the signal strength used to send the first messages.

A system of communicating data over a high availability industrial control system is disclosed. The industrial control system includes a first data producer, a second data producer in communicative connection with the first data producer, a first data consumer, and a second data consumer in communicative connection with the first data consumer. The system further includes the first producer communicating the data over multiple connection paths from the first producer to the first consumer and the second consumer through intermediate modules, and the second producer communicating the data over multiple connection paths from the second producer to the first consumer and the second consumer through intermediate modules. Also disclosed is a method of communicating data over the high availability industrial control system.