Systems, methods and apparatus for multiple network addressing modes are disclosed. The method includes selecting one of an automap full mode, an automap-by-type full mode, an automap light mode, an automap-by-type light mode and a manual node commissioning mode for determining and assigning the node addresses for the network devices, determining and assigning the node addresses for the network devices based on the automap full mode, determining and assigning the node addresses for the network devices based on the automap-by-type full mode, determining and assigning the node addresses for newly added network devices to an existing network based on the automap light mode, determining and assigning the node addresses for the newly added network devices to the existing network based on the automap-by-type light mode, and determining and assigning the node addresses for the network devices based on the manual node commissioning mode.

A method for protecting a network against a cyberattack, in which for a message in the network first characteristics of a first transmission of the message are determined and an origin of the message in the network is determined by a comparison of the first characteristics with at least one fingerprint of at least one subscriber or a segment of the network or a transmission route. If a manipulation of the message is detected, a point of attack of the cyberattack in the network is detected and localized in particular on the basis of the origin of the message.

Provided is an in-vehicle gateway device which is capable of performing efficient path selection control when data is transferred to a different network. In an in-vehicle gateway device that performs transfer control of data between a first network and a second network, the second network has a different network form from the first network, and a virtual IP address is allocated to the second network.

A method for bus addressing includes a controller receiving handshaking information from a component of a control system, allocating a communication address to the component through a field bus, and establishing a correlation between a physical address of the component and the communication address.

A vehicle system includes a gateway including a database and configured to transfer messages between a plurality of controllers, each controller connected to one of a plurality of nodes, the gateway further configured to broadcast, to all the nodes, a request message received from a first controller for receipt by a second controller, receive, from a first node, a response message from the second controller for receipt by the first controller, and link, in the database, the first node and the second controller.

It is provided to implement a different number of logical slaves in a field device for use in an AS interface network as a function of the assigned address, which slaves may be addressed using the assigned address in the standard or in the expanded addressing mode. Thus, in a field device, it is possible to provide slaves having different profiles, via which different data types may be exchanged. Furthermore, a method is provided, with which a field device having different slaves is able to be addressed in a simple manner while avoiding double addressing.

The present application relates to an apparatus and method of authenticating and verifying a message frame on a multi-master access bus with message broadcasting. Logic bus identifier, LID, are associated with each one of a several logical groups of nodes out of a plurality of nodes connected to the multi-master access bus. A key is assigned to each logical group. The keys assigned to different logical groups differ from each other. For message authentication, a logic bus identifier, LID is provided and a key associated with the logic bus identifier, LID, is retrieved. A cryptographic hash value, MAC, is generated using the retrieved key and based on at least the logic bus identifier, LID. A message frame is composed, which comprises the logic bus identifier, LID, and the cryptographic hash value, MAC. For message verification, a message frame is received, which comprises at least a logic bus identifier, LID, and a cryptographic hash value, MAC. A key is retrieved, which is associated with the logic bus identifier, LID, extracted from the frame. A cryptographic verification hash value, VAC, is generated using the retrieved key and based on at least the logic bus identifier, LID. The cryptographic verification hash value, VAC, and the cryptographic hash value, MAC, extracted from the frame are compared. The received message frame is forward for further processing as a legitimate message frame.

A user station for a bus system implementing broadband CAN communication includes: a communication control device for creating or reading at least one message for/from at least one further user station of the bus system, in which exclusive, collision-free access of a user station to a bus of the bus system is ensured at least intermittently; and a data interleaving device for interleaving data packets of at least two messages into a single message, so that the data packets are situated in one data segment of the single message. The single message has a shared outer frame header for the data packets in front of the data segment and a shared outer frame end for the data packets after the data segment.

A measuring system for a road construction machine includes a control unit which is operationally connected using a field bus to at least one field device, wherein an exclusive bus address is respectively assignable in the measuring system for each field device connected in the field bus. Furthermore, a method for addressing at least one field device is also provided.

A device including a network interface, a memory, and at least one processor is provided. The memory may include a random access memory (RAM) and nonvolatile memory. The processor may be coupled to the memory and coupled to the network interface and configured to designate an uninitialized section of RAM, generate a network device identifier for the device using data from the uninitialized section of RAM, store the network device identifier in a nonvolatile memory, and assign the network device identifier to the device. The at least one processor may be further configured to generate the network device identifier using the data from the uninitialized section of RAM as a seed for a pseudorandom number generator.