Facilitating ad hoc daisy-chaining of dynamically addressable devices having configurable physical layer interfaces together in a serial manner is presented herein. A system can include a group of devices communicatively coupled with respective devices of the group of devices in a daisy-chained manner via physical layer (PHY) interfaces of the respective devices including a group of available communication protocol configurations including a low voltage differential signaling (LVDS) based PHY configuration, a controller area network (CAN) based PHY configuration, and/or a single-ended serial communication PHY configuration including a complementary metal-oxide-semiconductor (CMOS) based interface or a transistor-transistor logic (TTL) based interface. Further, a host device of the system is directly connected, using a single-ended Manchester encoded serial communication interface, to a foremost device of the group of devices and to successive devices of the respective devices, via the foremost device, using the single-ended Manchester encoded serial communication interface.

To provide greater efficiency in connecting and establishing communicational equipment, the communicational system type can be automatically detected and the communicational equipment can configure itself in accordance with the automatically detected communicational type. Additionally, to accommodate dynamic reconfiguration, or changes to the communicational type after an initial configuration, the communicational type can be automatically monitored and the communicationally equipment automatically reconfigured if changes are detected. Different sets of comparator circuitry can be utilized to compare the voltages observed at known inputs to known thresholds of different communicational types to automatically detect the communicational type being utilized by existing equipment to which the newly-connected equipment is communicationally coupled. For efficiency, already existing circuitry for converting electrical voltages into digital data can be leveraged to monitor and automatically detect the communicational type being utilized.

The present disclosure relates to communication networks. Some embodiments may include a communication network with two or more network nodes each comprising: a receiver discerning the signal quality of received signals; a transmitter sending signals at different data rates; and a controllable terminating impedance. A network node transmits the discerned signal quality to one or more additional network nodes, a network node records the signal qualities and corresponding values of the terminating impedances of the respective network nodes. A network node prescribes for additional network nodes a new respective value to set as a terminating impedance. A network node determines new terminating impedance values to optimize the data rate between the various network nodes and the signal quality at each of the network nodes.

An Ethernet physical-layer circuit corresponding to a first port is connected to a first link partner device through the first port and a first Ethernet cable. The Ethernet physical-layer circuit and other physical-layer circuits all employ an output oscillation signal of a crystal oscillator to respectively generate clock waveforms, and they are configured in a master mode when the crosstalk noise is converged and compensated.

A first node operates in a network. The first node sends a polling message to a second node over a link at a first data rate, receiving an acknowledgement message from the second node. Based at least in part on receiving the acknowledgement message, the first node determines the second node is available to receive an information message. Based at least in part on the determining the second node is available to receive the information message, the first node sends the information message to the second node over the link at a second data rate. The second data rate is based at least on an indication of observed behavior of the link and the first data rate is based at least on the second data rate. For example, the first node may determine the first data rate to be a next slowest available data rate than the second data rate.

Various systems and methods for bus-off attack detection are described herein. An electronic device for bus-off attack detection and prevention includes bus-off prevention circuitry coupled to a protected node on a bus, the bus-off prevention circuitry to: detect a transmitted message from the protected node to the bus; detect a bit mismatch of the transmitted message on the bus; suspend further transmissions from the protected node while the bus is analyzed; determine whether the bit mismatch represents a bus fault or an active attack against the protected node; and signal the protected node indicating whether a fault has occurred.

A switch device installed in a vehicle is provided with: a switch unit configured to relay communication data between a plurality of function units installed in the vehicle; a storage unit configured to hold the communication data to be relayed; and a control unit configured to determine a state of the storage unit, and adjust, for each of applications, a throughput of the communication data to be transmitted from the function units, based on a result of the determination.

A control portion (10) of a network equipment (1) attempts, when connected to other equipment, connection by using a predetermined communication parameter through communication portions (11, 12), and in a case that the communication is not established, the control portion (10) executes negotiation and establishes communication with the other equipment by using an agreed communication parameter.

The fully-automatic closed-loop detection method includes: comparing a SCD file of a to-be-tested substation with a device-type data template file, so as to determine whether configuration information about the to-be-tested substation is correct; when the configuration information about the to-be-tested substation is correct, parsing the SCD file of the to-be-tested substation and generating a SSD topological diagram of the to-be-tested substation; and acquiring a testing item from a predetermined testing item library in accordance with the SSD topological diagram of the to-be-tested substation, generating a testing scheme for the to-be-tested substation, performing a testing operation and outputting a testing result.

Facilitating ad hoc daisy-chaining of dynamically addressable devices having configurable physical layer interfaces together in a serial manner is presented herein. A system can include a group of devices communicatively coupled with respective devices of the group of devices in a daisy-chained manner via physical layer (PHY) interfaces of the respective devices including a group of available communication protocol configurations including a low voltage differential signaling (LVDS) based PHY configuration, a controller area network (CAN) based PHY configuration, and/or a single-ended serial communication PHY configuration including a complementary metal-oxide-semiconductor (CMOS) based interface or a transistor-transistor logic (TTL) based interface. Further, a host device of the system is directly connected, using a single-ended Manchester encoded serial communication interface, to a foremost device of the group of devices and to successive devices of the respective devices, via the foremost device, using the single-ended Manchester encoded serial communication interface.