An Ethernet transceiver is disclosed. The Ethernet transceiver includes transceiver circuitry to couple to one end of an Ethernet link. The transceiver circuitry includes transmit circuitry to transmit high-speed Ethernet data along the Ethernet link at a first data rate and receiver circuitry. The receiver circuitry includes adaptive filter circuitry and correlator circuitry. The receiver circuitry is responsive to an inline signal to operate in a low-power alert mode with the adaptive filter circuitry disabled and to receive alert signals from the Ethernet link simultaneous with transmission of the Ethernet data by the transmit circuitry. The alert signals are detected by the correlator circuitry and include a sequence of alert intervals exhibiting encoded data at a second data rate less than the first data rate.

An Ethernet transceiver is disclosed. The Ethernet transceiver includes transceiver circuitry to couple to one end of an Ethernet link. The transceiver circuitry includes transmit circuitry to transmit high-speed Ethernet data along the Ethernet link at a first data rate and receiver circuitry. The receiver circuitry includes adaptive filter circuitry and correlator circuitry. The receiver circuitry is responsive to an inline signal to operate in a low-power alert mode with the adaptive filter circuitry disabled and to receive alert signals from the Ethernet link simultaneous with transmission of the Ethernet data by the transmit circuitry. The alert signals are detected by the correlator circuitry and include a sequence of alert intervals exhibiting encoded data at a second data rate less than the first data rate.

Edge devices of a network collect data. An edge device may determine whether to process the data using a local data processing model or to send the data to a tier device. The tier device may receive the data from the edge device and determine whether to process the data using a higher tier data processing model of the tier device. If the tier device determines to process the data, then the tier device processes the data using the higher tier data processing model, generates a result based on the processing, and sends the result to an endpoint (e.g., back to the edge device, to another tier device, or to a control device). If the tier device determines not to process the data, then the tier device may send the data on to another tier device for processing by another higher tier model.

Edge devices of a network collect data. An edge device may determine whether to process the data using a local data processing model or to send the data to a tier device. The tier device may receive the data from the edge device and determine whether to process the data using a higher tier data processing model of the tier device. If the tier device determines to process the data, then the tier device processes the data using the higher tier data processing model, generates a result based on the processing, and sends the result to an endpoint (e.g., back to the edge device, to another tier device, or to a control device). If the tier device determines not to process the data, then the tier device may send the data on to another tier device for processing by another higher tier model.

A network interface controller including a data alignment module, a boundary determination module and a checksum module is provided. The data alignment module receives raw data and re-combines the raw data as first valid data, wherein the raw data includes a first layer protocol segment and a second layer protocol segment. The boundary determination module receives the raw data in parallel to the data alignment module and performs a boundary determination operation on the raw data to generate a boundary information indicating a boundary between the first layer protocol segment and the second layer protocol segment. The checksum module is coupled to the data alignment module and configured to disassemble the first valid data as second valid data and calculate a checksum according to the boundary information and the second valid data.

A network interface controller including a data alignment module, a boundary determination module and a checksum module is provided. The data alignment module receives raw data and re-combines the raw data as first valid data, wherein the raw data includes a first layer protocol segment and a second layer protocol segment. The boundary determination module receives the raw data in parallel to the data alignment module and performs a boundary determination operation on the raw data to generate a boundary information indicating a boundary between the first layer protocol segment and the second layer protocol segment. The checksum module is coupled to the data alignment module and configured to disassemble the first valid data as second valid data and calculate a checksum according to the boundary information and the second valid data.

A network interface controller is provided, including a receiving module, a boundary determination module, a first checksum calculation module, and a second checksum calculation module. The receiving module receives a packet having a segment of a first layer protocol and a segment of a second layer protocol. The boundary determination module performs a boundary determination operation on the packet to generate boundary information, wherein the boundary information includes a length of the segment of the second layer protocol and a boundary indication signal. The first checksum calculation module finishes the calculation of a first checksum corresponding to the segment of the first layer protocol after receiving the length of the segment of the second layer protocol. The second checksum calculation module starts to calculate a second checksum corresponding to the segment of the second layer protocol after receiving the boundary indication signal.

A network device for processing various types of requests is proposed. The network device may store segment information of the various types of requests by using different registers, thereby the reliability of the subsequently generated response can be improved while increasing the efficiency of implementing the ARP/NDP offloading.

A gateway, operable in a hierarchical heterogeneous network, includes at least two interfaces of which at least one is connectable to a lower network level, and the communication protocols in the network provide a message for offering a service and a message for searching for a service, receipt of a message coming in from a lower network level in the gateway at an interface for offering a service, and/or an item of information identifying the offered service, is noted in the interface receiving this message or in a management unit assigned thereto, and receipt of a message from a lower network level in the gateway at an interface for searching for a service and/or an item of information identifying the sought service is noted in the interface or management unit, and if the messages relate to the same service, a message for the service availability is sent via the interface.

A gateway, operable in a hierarchical heterogeneous network, includes at least two interfaces of which at least one is connectable to a lower network level, and the communication protocols in the network provide a message for offering a service and a message for searching for a service, receipt of a message coming in from a lower network level in the gateway at an interface for offering a service, and/or an item of information identifying the offered service, is noted in the interface receiving this message or in a management unit assigned thereto, and receipt of a message from a lower network level in the gateway at an interface for searching for a service and/or an item of information identifying the sought service is noted in the interface or management unit, and if the messages relate to the same service, a message for the service availability is sent via the interface.