A method for modifying a program of an industrial automation component, wherein the program includes a plurality of program elements, where the program is structured in units, a unit includes a group of program elements and can include both published program elements having an interface that can be referenced by the program elements of other units and unpublished program elements, and where a checksum is calculated and is assigned to the unit using the interfaces, such that if at least one program element of the version of the unit stored in the engineering system is modified, then the modified checksum is compared with the previous checksum version present in the automation component, and only the modified unit is transferred if the checksums match such that consistency of the program is maintained and the software updateable more quickly.

A method for modifying a program of an industrial automation component, wherein the program includes a plurality of program elements, where the program is structured in units, a unit includes a group of program elements and can include both published program elements having an interface that can be referenced by the program elements of other units and unpublished program elements, and where a checksum is calculated and is assigned to the unit using the interfaces, such that if at least one program element of the version of the unit stored in the engineering system is modified, then the modified checksum is compared with the previous checksum version present in the automation component, and only the modified unit is transferred if the checksums match such that consistency of the program is maintained and the software updateable more quickly.

A system includes a first module configured to collect automation plant-related data that include at least operating data, and to generate based on the operating data manipulation-proof usage data which are then transmitted to a second module configured to determine at least a part of the manipulation-proof usage data, to form a checksum from the at least one part of the manipulation-proof usage data, to transfer the checksum to at least one node of a distributed ledger network, and to store the manipulation-proof usage data in an area outside the distributed ledger network. A third module participates in the distributed ledger network and is configured to obtain the manipulation-proof usage data from the area and to check the correctness of the manipulation-proof usage data by forming a checksum.

An apparatus, system, and method to manage communications within a network, such as a wireless network and/or at least partially included within a hazardous area, includes creating a master CRC array from master configuration structures, creating a main master CRC value from the master CRC array, receiving a main slave CRC value, and determining if the main master CRC value and the main slave CRC value are different.

A method operates a safety control in an automation network having a master subscriber which carries out the safety control, at least one first slave subscriber which is assigned a first safety integrity level, and at least one second slave subscriber which is assigned a second safety integrity level. The first safety integrity level and the second safety integrity level differ from each other. A first safety code determination method is assigned to the first slave subscriber and a second safety code determination method is assigned to the second slave subscriber. The first safety code determination method and the second safety code determination method differ from each other. The master subscriber and the first slave subscriber use the first safety code determination method for interchanging a safety data block. The master subscriber and the second slave subscriber use the second safety code determination method for interchanging a safety data block.

A method for configuring a failsafe module, which is connected to a field bus coupler of an industrial automation system via a sub-bus in order to transmit security-related data of the module via a field bus, utilizes a number of steps, The type of security protocol that is compatible with the field bus is determined via the field bus coupler, and configuration instructions are transmitted to at least one failsafe module via the field bus coupler in order to enable the module to use the determined type of security protocol. Furthermore, a field bus coupler or a system comprising a field bus coupler and at least one failsafe module is designed to implement the method.

A system includes a first module configured to collect automation plant-related data that include at least operating data, and to generate based on the operating data manipulation-proof usage data which are then transmitted to a second module configured to determine at least a part of the manipulation-proof usage data, to form a checksum from the at least one part of the manipulation-proof usage data, to transfer the checksum to at least one node of a distributed ledger network, and to store the manipulation-proof usage data in an area outside the distributed ledger network. A third module participates in the distributed ledger network and is configured to obtain the manipulation-proof usage data from the area and to check the correctness of the manipulation-proof usage data by forming a checksum.

A method operates a safety control in an automation network having a master subscriber which carries out the safety control, at least one first slave subscriber which is assigned a first safety integrity level, and at least one second slave subscriber which is assigned a second safety integrity level. The first safety integrity level and the second safety integrity level differ from each other. A first safety code determination method is assigned to the first slave subscriber and a second safety code determination method is assigned to the second slave subscriber. The first safety code determination method and the second safety code determination method differ from each other. The master subscriber and the first slave subscriber use the first safety code determination method for interchanging a safety data block. The master subscriber and the second slave subscriber use the second safety code determination method for interchanging a safety data block.

A data transmission system comprising an Automotive Sensor Network System (ASNS) connected to a plurality of source locations via a common bus, wherein the ASNS is configured to ascertain the source from which the data-frames and first package checksum are received and based on the ascertainment of the source, appropriate decoding methods are used to calculate the ASNS location data-frame checksums and the ASNS location package checksums. A higher order redundancy check is done over a series of data-frames to detect errors in the reception caused by temporary high interference that may exist in the transmission path.