Systems and methods for configuring the operation of recording devices that may be removably mounted to a mount. A mount may provide a unique identifier. The unique identifier may be used to select a configuration profile for configuring the operation of the recording device coupled to the mount. A recording device that is moved from one mount to another may receive a different profile in accordance with the identifier of the new mount to control the operation of the recording device while mounted to the new mount. A server may store, retrieve, and provide profiles to recording devices.

Ethernet link extension methods and devices provide, in one illustrative embodiment, an Ethernet link extender with physical medium attachment (PMA) circuits each having a transmitter and receiver that communicate with a respective node in a sequence of communication phases. The sequence includes at least an auto-negotiation phase and a subsequent training phase, the phases occurring simultaneously for both PMA circuits. In the auto-negotiation phase, the PMA circuits operate in a pass-through mode, rendering the extender transparent to the two nodes. In the training phase, the PMA circuits operate independently, sending training frames to their respective nodes based in part on received back-channel information and locally-determined training status information. The training phases may be prolonged if needed to provide a simultaneous transition to a frame-forwarding phase of the sequence.

This application provides an example delay measurement method and an example network device. The method includes receiving, by a first network device, a first service flow. The method also includes determining, by the first network device, a first delay value based on a first measurement code block in the first service flow. The first delay value is a time difference between a first moment at which the first measurement code block is detected in the first network device and a second moment at which the first measurement code block is detected in the first network device.

A method and apparatus for determining a port rate determines a channel transmission rate of an SAS port including N physical channels. The method includes: determining M different negotiated rates of the N physical channels; separately determining M total port bandwidths corresponding to the M different negotiated rates; and determining a negotiated rate corresponding to a largest total port bandwidth in the M total port bandwidths as a channel transmission rate of the port. A lowest negotiated rate is no longer used as the channel transmission rate of the port, but the negotiated rate corresponding to the largest total port bandwidth is determined as the channel transmission rate of the port.

In a method for establishing a communication link between a first network interface device and a second network interface device comprises, the second network interface device receives a training signal transmitted by the first network interface device. The training signal is for timing synchronization between the second network interface device and the first network interface device. The second network interface device determines, based on at least one physical characteristic of the training signal, a physical layer (PHY) parameter of the first network interface device. A controller of the second network interface device configures one or more components of the second network interface device to operate in a mode that corresponds to the determined PHY operating parameter of the first network interface device.

The invention relates to a method for operating an agricultural machine having a tractor (1) and an implement (2) hitched to the tractor (1), the method comprising connecting a control device (12) provided on the tractor (1) to a data bus (6), wherein the control device (12) is configured to process data indicative for a plurality of implement operation parameters assigned parameter identifiers P1 to Pn (n 2); connecting a control unit (9b) provided on the implement to the data bus (6), wherein the control unit (9b) is assigned to at least one functional element of the implement (2); and establishing data communication between the control device (12) and the control unit (9b) through the data bus (6), comprising, in response to connecting the control unit (9b) to the data bus (6), transmitting a response data message from the control unit (9b) to the control device, the response data message indicating the control unit (9b) being configured to provide present parameter values for only a subset of implement operation parameters assigned parameter identifiers P1 to Pm (m<n), but not for a subset of remaining implement operation parameters assigned parameter identifiers Pm+1 to Pn. Further, in response to receiving the response data message in the control device, future data collecting messages transmitted from the control device (12) to the control unit (9b) are limited to requesting present parameter values for the subset of implement operation parameters assigned parameter identifiers P1 to Pm only, and the future data collecting messages transmitted to the control unit (9b) are prevented from requesting present parameter values for the subset of the remaining implement operation parameters assigned parameter identifiers Pm+1 to Pn. Furthermore, an agricultural machine having a tractor (1) and an implement (2) hitched to the tractor (1) is provided.

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.

An Ethernet Physical layer (PHY) device includes a PHY interface and PHY circuitry. The PHY interface is configured to connect to a physical link. The PHY circuitry is configured to generate layer-1 frames that carry data for transmission to a peer Ethernet PHY device, to insert among the layer-1 frames one or more management frames that are separate from the layer-1 frames and that are configured to control a General-Purpose Input-Output (GPIO) port associated with the peer Ethernet PHY device, to transmit the layer-1 frames and the inserted management frames, via the PHY interface, to the peer Ethernet PHY device over the physical link, for controlling one or more operations of the GPIO port associated with the peer Ethernet PHY device, and to receive, via the PHY interface, one or more verifications acknowledging that the one or more management frames were received successfully at the peer Ethernet PHY device.

Disclosed are a vehicle diagnostic communication apparatus, a system including the same and a method thereof. The vehicle diagnostic communication apparatus may include a processor configured to automatically calculate a diagnostic time based on an controller-specific response time and vehicle network information when communicating with a vehicle, and storage configured to store the controller-specific response time and the vehicle network information.

An Ethernet Physical layer (PHY) device includes a PHY interface and PHY circuitry. The PHY interface is configured to connect to a physical link. The PHY circuitry is configured to generate layer-1 frames that carry data for transmission to a peer Ethernet PHY device, to insert among the layer-1 frames one or more management frames that are separate from, the layer-1 frames and that are configured to control a General-Purpose Input-Output (GPIO) port associated with the peer Ethernet PHY device, to transmit the layer-1 frames and the inserted management frames, via the PHY interface, to the peer Ethernet PHY device over the physical link, for controlling one or more operations of the GPIO port associated with the peer Ethernet PHY device, and to receive, via the PHY interface, one or more verifications acknowledging that the one or more management frames were received successfully at the peer Ethernet PHY device.