Abstract: The invention relates to a method for transmitting messages in a computer network, and to a computer network of this type. The computer network comprises computing nodes (101-105), said computing nodes (101-105) being interconnected via at least one star coupler (201) and/or at least one multi-hop network (1000), wherein each computing node (101-105) is connected via at least one communication line (110) to the at least one star coupler (201) and/or the at least one multi-hop network (1000), and wherein the computing nodes (101-105) exchange Ethernet messages with one another and with the at least one star coupler (201) and/or the at least one multi-hop network (1000).

Abstract: An information exchange between at least two processes (FEED_PROC-1, FEED_PROC-2, CONSUME_PROC-1) communicating with each other using at least one queue (QUEUE-001) uses a placement plan for determining the order in which messages are placed into the queue. The information feeding processes (FEED_PROC-1, FEED_PROC-2) place pieces of information (MESG-001, MESG-002) into the queue (QUEUE-001), from where an information consuming process (CONSUME_PROC-1) sequentially consumes the pieces of information. The placement plan describes, for at least one possible value of identifying information contained in each of the pieces of information, a respective position (POS-001, POS-002) in the queue (QUEUE-001), such that the pieces of information (MESG-001, MESCG-002) or respective references thereto are placed into the queue according to positions in the queue (QUEUE-001) corresponding to the respective values of the identifying information in the pieces of information.

Abstract: A method is provided to detect and handle failures in the communication in a network, including a sender (201, 203) and a receiver (202, 501, 502, 503), where communication between the sender and the receiver is message-oriented. The method includes: (a) the sender sending a message (M101, M101-C, M102-C) to the receiver; (b) the sender monitoring the transmission process of the message inside the sender and/or monitoring the message; (c) the sender executing a correctness check of (i) the message, e.g., its contents, and/or (ii) the transmission process of the message inside the sender; and (d) after the correctness check(s) has/have been completed, the sender informs the receiver of the result of the correctness check(s), wherein (e) the receiver of the message marks the message as being faulty and/or discards the message if the result of a correctness check indicates that the message and/or transmission process is faulty.

Abstract: The invention relates to a method for the redundant transmission of messages in a distributed real-time system, wherein the real-time system comprises two or more computing nodes (101-108) and one or more star couplers (201-209), wherein the computing nodes (101-108) are connected to the star couplers (201-209) by means of bidirectional communication lines (301, 302, 303) and the star couplers (201-209) are interconnected by bidirectional communication lines (310), and wherein the star couplers (201-209) connected by the communication lines (310) form a network infrastructure (200), wherein one or more star couplers (201-209) of the network infrastructure (200) perform one or more activity rasters (1000), wherein an activity raster (1000) consists of alternating active phases (502) and rest phases (501), and wherein any message sent in the network infrastructure is assigned to precisely one activity raster (1000).

Abstract: The invention relates to a method for transmitting messages in a computer network, and to a computer network of this type. The computer network comprises computing nodes (101-105), said computing nodes (101-105) being interconnected via at least one star coupler (201) and/or at least one multi-hop network (1000), wherein each computing node (101-105) is connected via at least one communication line (110) to the at least one star coupler (201) and/or the at least one multi-hop network (1000), and wherein the computing nodes (101-105) exchange Ethernet messages with one another and with the at least one star coupler (201) and/or the at least one multi-hop network (1000).

Abstract: In a network based on IEEE 1588, comprising a plurality of nodes (201, 501) and a plurality of connections where each connection connects at least two nodes to allow communication between nodes including the exchange of messages according to a network protocol, the synchronization of IEEE 1588 is improved by allowing multiple grandmaster clocks (701) to operate simultaneously in the system. Thus, the re-election protocol of IEEE 1588 is made obsolete. For this, a multitude of nodes form a subsystem implementing a high-availability grand master clock (301) according to the IEEE 1588 Standard, wherein the subsystem is configured to tolerate the failure of at least one of said nodes forming said subsystem. Bi-directional communication link (401) are configured for physically connecting a IEEE 1588 Master clocks (201) and/or IEEE 1588 Slave clocks (201) to the subsystem implementing a high-availability grand master clock (301).

Abstract: A communication switch comprises a plurality of ports and a processing unit configured to identify source ports and destination ports from the plurality of ports on a per virtual link basis. Each virtual link comprises one or more source ports via which frames are received from one or more source nodes and one or more destination ports via which received frames are forwarded to one or more destination nodes. For at least one virtual link, the processing unit is configured to accept more than one of the plurality of ports as source ports.

Abstract: The invention relates to a method for the redundant transmission of messages in a distributed real-time system, wherein the real-time system comprises two or more computing nodes (101-108) and one or more star couplers (201-209), wherein the computing nodes (101-108) are connected to the star couplers (201-209) by means of bidirectional communication lines (301, 302, 303) and the star couplers (201-209) are interconnected by bidirectional communication lines (310), and wherein the star couplers (201-209) connected by the communication lines (310) form a network infrastructure (200), wherein one or more star couplers (201-209) of the network infrastructure (200) perform one or more activity rasters (1000), wherein an activity raster (1000) consists of alternating active phases (502) and rest phases (501), and wherein any message sent in the network infrastructure is assigned to precisely one activity raster (1000).

Abstract: The invention relates to a method for making an electrolytic battery which is preferably used in movable facilities such as cars, boats and planes. The method comprises the following steps: inserting of intermixing plates 5a? into the battery case 1, one each at two sides thereof which are opposite to each other, inserting of the set of electrodes 2 between the two intermixing plates 5a? positioned in the battery case 1 and connecting of the two intermixing plates 5a? straightened out vertically with the bridging plate 5b? comprising a drain surface, which is slightly inclined towards the center thereof, and an opening provided approximately in the center thereof to enable electrolyte to flow back into the batter case.

Abstract: The aim of the present invention is that of establishing a fault-tolerant global time in a fault-tolerant communication system of a distributed real-time system. For this purpose, a fault-tolerant message switching unit is provided, which is composed of four independent switching units. These four independent switching units jointly establish a fault-tolerant time. The terminal systems are connected to a fault-tolerant message switching unit via two independent fail-silent communication channels, so that the clock synchronization and network connections are preserved, even if a part of the fault-tolerant switching unit or of a communication channel fails.

Abstract: The invention relates to a method for distributing event-triggered (ET) and time-triggered (TT) messages in a distributed real-time system by means of a distributor unit that comprises a low-level relay unit (LLVME) and a high-level relay unit (HLVME), wherein communication ports of the distributor unit to other relay units and/or end systems of the real-time systems are attached to the LLVME. The invention further relates to such a distributor unit and to a real-time system comprising such a distributor unit.

Abstract: A method for start-up of a network, including a number of nodes, which are connected via channels. The nodes exchange information in the form of messages via the channels. The transition phase of a synchronizing node from its initial phase to a synchronized phase is separated in a first integration phase and a second subsequent cold-start phase. A synchronizing node in the integration phase listens to messages being sent from nodes in the synchronized phase and only reacts to an integration message (i-frame) if the integration message is a valid message. Furthermore, a synchronizing node, wherein integration of the synchronizing node to a set of already synchronized nodes was not successful after a specifiable period, changes into the cold-start phase, in which a cold-start procedure of the node is extracted, wherein in the cold-start phase the node does not react to integration messages of a node in the synchronized phase.

Abstract: In a network based on IEEE 1588, comprising a plurality of nodes (201, 501) and a plurality of connections where each connection connects at least two nodes to allow communication between nodes including the exchange of messages according to a network protocol, the synchronization of IEEE 1588 is improved by allowing multiple grandmaster clocks (701) to operate simultaneously in the system. Thus, the re-election protocol of IEEE 1588 is made obsolete. For this, a multitude of nodes form a subsystem implementing a high-availability grand master clock (301) according to the IEEE 1588 Standard, wherein the subsystem is configured to tolerate the failure of at least one of said nodes forming said subsystem. Bi-directional communication link (401) are configured for physically connecting a IEEE 1588 Master clocks (201) and/or IEEE 1588 Slave clocks (201) to the subsystem implementing a high-availability grand master clock (301).

Abstract: The invention relates to a method for making an electrolytic battery which is preferably used in movable facilities such as cars, boats and planes. The method comprises the following steps: inserting of intermixing plates 5a? into the battery case 1, one each at two sides thereof which are opposite to each other, inserting of the set of electrodes 2 between the two intermixing plates 5a? positioned in the battery case 1 and connecting of the two intermixing plates 5a? straightened out vertically with the bridging plate 5b? comprising a drain surface, which is slightly inclined towards the center thereof, and an opening provided approximately in the center thereof to enable electrolyte to flow back into the batter case.

Abstract: A system comprises a plurality of nodes, at least one of the plurality of nodes configured to insert, on a per-virtual link basis, a delay value into a dynamic delay field of a frame corresponding to the respective virtual link, wherein the dynamic delay value represents latency of frames of the respective virtual link. The system also comprises a switch having a plurality of ports, each port coupled to one of the plurality of nodes. The switch is configured to route frames received from the plurality of nodes to one or more of the plurality of nodes. At least one of the plurality of nodes is configured to store frames received from the switch in a buffer and to update the value in the dynamic delay field to reflect the end-to-end system delay.

Abstract: The present invention describes a method for the measurement of the stabilizer additive concentration in electroless metal and metal alloy plating electrolytes comprising a voltammetric measurement. Said method comprises the steps a. conditioning of the working electrode, b. interaction of intermediates on the working electrode, c. measurement of the Faradaic current and d. determining the Faradaic current.

Abstract: The aim of the present invention is that of establishing a fault-tolerant global time in a fault-tolerant communication system of a distributed real-time system. For this purpose, a fault-tolerant message switching unit is provided, which is composed of four independent switching units. These four independent switching units jointly establish a fault-tolerant time. The terminal systems are connected to a fault-tolerant message switching unit via two independent fail-silent communication channels, so that the clock synchronization and network connections are preserved, even if a part of the fault-tolerant switching unit or of a communication channel fails.

Abstract: The goal of the present invention is to improve the useful data efficiency and reliability in the use of commercially available ETHERNET controllers, in a distributed real time computer system, by a number of node computers communicating via one or more communication channels by means of TT ETHERNET messages. To achieve this goal, a distinction is made between the node computer send time (KNSZPKT) and the network send time (NWSZPKT) of a message. The KNSZPKT must wait for the NWSZPKT, so that under all circumstances, the start of the message has arrived in the TT star coupler at the NWSZPKT, interpreted by the clock in the TT star coupler. The TT star coupler is modified, so that a message arriving from a node computer is delayed in an intelligent port of the TT star coupler until the NWSZPKT can send it precisely at the NWSZPKT into the TT network.

Abstract: A system comprises a plurality of nodes, at least one of the plurality of nodes configured to insert, on a per-virtual link basis, a delay value into a dynamic delay field of a frame corresponding to the respective virtual link, wherein the dynamic delay value represents latency of frames of the respective virtual link. The system also comprises a switch having a plurality of ports, each port coupled to one of the plurality of nodes. The switch is configured to route frames received from the plurality of nodes to one or more of the plurality of nodes. At least one of the plurality of nodes is configured to store frames received from the switch in a buffer and to update the value in the dynamic delay field to reflect the end-to-end system delay.

Abstract: A communication system comprises a plurality of nodes and a switch having a plurality of ports, each port coupled to one of the plurality of nodes. At least one of the plurality of nodes is configured to transmit a first unregulated flow of frames associated with a first virtual link to a first port of the plurality of ports of the switch. The switch is configured to regulate the first unregulated flow of frames by buffering frames of the first unregulated flow in a first input queue associated with the first virtual link, applying traffic shaping parameters associated with the first virtual link to the frames in the first input queue associated with the first virtual link, and outputting the first regulated flow of frames to one or more output queues associated with one or more output ports based on the first virtual link.