WO2024068463A1 - Network for exchanging data between network devices with a bypass option - Google Patents

Abstract

The invention relates to a network (10) comprising at least a first, second and third network device (1, 2, 3), each of which is designed in accordance with a network topology used for the network (10). Each individual network device has at least two connection ports (11, 12, 21, 22, 31, 32) so that a first connection port (11) of the first network device (1) is connected to a first connection port (21) of the second network device (2) and a second connection port (22) of the second network device (2) is connected to a first connection port (31) of the third network device (3). The second network device (2) comprises a transmitter and receiver unit (23) and a control unit (27), which is in communicative connection with the transmitter and receiver unit, for controlling the transmission of data. The transmitter and receiver unit (23) is designed to receive data transmitted by the first network device (1), to forward said data to the control unit (27), and to transmit data received by the control unit (27) to the third network device (3). The second network device (2) comprises an actuatable switching device (28) which is located between the first and second connection ports (21, 22) and is designed to galvanically connect said connection ports (21, 22) in the closed state.

Description

1 September 22, 2023

22PH 0156WOP

Network for exchanging data between network devices with bypass option

Description

The present invention relates to a network comprising at least a first, a second and a third network device, each of which is set up in accordance with a network topology used for the network. Each individual network device has at least two connection ports, so that a first connection port of the first network device is connected to a first connection port of the second network device and a second connection port of the second network device is connected to a first connection port of the third network device. The second network device comprises a transmitting and receiving unit and a control unit in communication with the transmitting and receiving unit for controlling a transmission of data, the transmitting and receiving unit for receiving data sent by the first network device and for forwarding this data to the Control unit and is set up to send data received from the control unit to the third network device.

In addition to wireless transmission via WLAN connection, sometimes also using data clouds, bus systems are often used to transmit data within a network that includes a number of network devices. In principle, different bus systems can be used depending on the area of application, to which the majority of the network devices in the network are electrically connected in a generally predetermined network topology in order to enable communication between the network devices. For example, bus systems can be constructed in a so-called daisy chain topology, in which a number of network components are connected in series and can communicate with each other or exchange data via point-to-point connections. In this case, each individual network component has two connection ports, e.g. two Ethernet ports or two Single Pair Ethernet (SPE) ports, although any other protocol can be used instead of Ethernet. Bus systems that are constructed as a daisy-chain topology typically have two transceivers and/or so-called physical layers (PHY), which usually prepare and process the individual signals received via a first connection port and can output them again at a different connection port if required. For example, a first, second and third network device can be connected in series to a bus system constructed as a daisy-chain topology, so that the first network device and the third network device can exchange data via the second network device connected to the bus system in series between them. For example, a signal sent by the first network device can be fed in via a first connection port of the second network device, which is forwarded by a first transceiver of the second network device to a control unit of the second network device. The signal can then be processed in the control unit, transmitted to a second transceiver of the second network device, processed by this and finally output to the third network device via a second connection port of the second network device.

As long as the second network device is switched on and operational, signals or data can be exchanged between the first network device and the third network device via the second network device arranged between them in the bus system. However, if the second network device is not operational, for example due to a defect such as a power failure, the signals or data sent by the first network device can no longer be forwarded to the third network device via the second network device. The exchange of data is therefore interrupted and not possible as long as the second network device is not operational again or has not been replaced by a corresponding functional network device.

Against the background of the aforementioned disadvantages, the present invention at least has the task of maintaining communication or the exchange of data between two network devices within a network even when a third network device arranged between these in the network topology and connected to the network fails or is not operational.

The solution of the present invention is represented by a subject matter having the features of the independent claims. Advantageous refinements and further developments are the subject of the further features of the subclaims.

Accordingly, at least one solution according to the invention relates to a network which comprises at least a first, a second and a third network device, each of which is set up according to a network topology used for the network. Each individual network device has at least two connection ports, so that a first connection port of the first network device is connected to a first connection port of the second network device and a second connection port of the second network device is connected to a first connection port of the third network device. The second network device comprises a transmitting and receiving unit and a control unit, which is in communication connection with the transmitting and receiving unit, for controlling a transmission of data. The transmitting and receiving unit is set up to receive data sent by the first network device, to forward this data to the control unit and to send data received from the control unit to the third network device. The network according to the invention is characterized in that the second network device further comprises a controllable switching device, which is arranged between the first connection port and the second connection port of the second network device, wherein the switching device is set up to provide a galvanic connection between the first connection port and in the closed state the second connection port of the second network device.

The network according to the invention therefore enables data to be exchanged or signals to be passed on between the first network device and the third network device even if the second network device fails or is no longer operational or switched off. This is made possible by the second network device having a connection between the first connection port and the controllable switching device arranged on the second connection port of the second network device. If the switching device is in a closed state so that it is electrically conductive, this creates a galvanic or electrically conductive connection between the first connection port and the second connection port of the second network device. An exchange of data or a forwarding of signals between the first network device and the third network device can thus take place via this galvanic connection between the first and second connection port of the second network device, in particular when the second network device has the task of forwarding data. e.g. due to a defect, can no longer fulfill or if this is not desired.

The first network device and/or the third network device and/or also at least one further network device of the network according to the invention can, for example, be constructed in accordance with the second network device, i.e. a corresponding transmitting and receiving device, control unit and a controllable switching device set up in accordance with the second network device include.

According to a further development of the invention, it is provided that the switching device is self-conducting and in particular comprises at least one semiconductor-based switching element. In addition or alternatively, it is provided that the control unit is designed to cause the switching device to open, in particular by means of a control signal sent to the switching device. The fact that the switching device is self-conducting has the advantage that, in the event that the second network device is no longer operational, it ensures, so to speak, that a galvanic connection exists between the first and the second connection port of the second network device. The second network device can thus be bridged without the switching device having to be controlled for this purpose or requiring a control signal in order to be closed or electrically conductive. A preferred example of such a switching device is a switching device which comprises at least one semiconductor-based switching element. The control unit of the second network device is advantageously designed to set up to cause the switching device to open or to break an electrical connection, for example by sending a control signal to the switching device. If the second network device is switched on and ready for operation, the control unit is set up to cause the switching device to open so that there is no galvanic connection between the first and second connection ports of the second network device and/or the connection is high-impedance. An exchange of data between the first network device and the third network device can then, as described above, take place via the second network device by means of its transmitting and receiving unit and its control unit. However, if the second network device, and thus also its control unit, fails, the control unit can no longer cause the switching device to open due to its inactive state. Consequently, the switching device goes into the self-conducting and thus closed state because it does not receive a corresponding control signal to open from the control unit. The first network device and the third network device are then directly connected to one another via the galvanic connection of the two connection ports of the second network device and can communicate directly with one another, i.e. without forwarding the data to or via the second network device, without the exchange of data between the first network device and the third network device being interrupted due to the inactive state of the second network device.

In a further development of the invention, the second network device can be operated in at least one operating mode for exchanging data between the first network device and the third network device, this operating mode being defined by the switching device being in a closed state. In this operating mode, which can also be referred to as bypass mode, a direct exchange of data between the first network device and the third network device is provided via the galvanic connection between the two connection ports of the second network device. In particular, the second network device can be operable in two operating modes for exchanging data between the first network device and the third network device, the further operating mode is defined by the fact that the switching device is in an open state. In this further operating mode it can be provided that data is exchanged between the first network device and the third network device via the second network device, as described at the beginning. Additionally or alternatively, the network can be set up for the bidirectional exchange of data between the first network device and the third network device. This is particularly advantageous when data is regularly exchanged between the first and third network devices in both directions, that is, with the first and third network devices each as transmitter and also as receiver of data.

According to a further development, the transmitting and receiving unit of the second network device is constructed from several separate transmitting and receiving components, and one transmitting and receiving component is between the first connection port and the control unit of the second network device and between the second connection port and the control unit of the second network device for communication, or the transmitting and receiving unit is constructed from a single transmitting and receiving component, and the switching device has several switching components with which the transmitting and receiving component can be connected either to the first connection port, to the second connection port or to the first and second connection port of the second network device can be connected. Each individual transmitting and receiving component of the transmitting and receiving unit can in particular include a transceiver or a PHY.

According to the invention, the network system can further comprise a bus system, in particular an n-wire bus system designed as a daisy chain topology, to which at least the first, second and third network devices are connected. Such a bus system can preferably be a 2-wire bus system, wherein each of the at least two connection ports of a respective network device has two connection pins. The second network device can further optionally comprise at least one controllable switching element which is arranged in a series circuit with a terminating resistor between all connection pins of at least one of the first connection port and the second connection port of the second network device. In particular, the at least one switching element can be self-locking. Furthermore, the control unit can be set up to cause the at least one switching element to close.

Depending on the bus system, clock frequency and PHY, it may be useful or even necessary for the second network device to include at least one further switching element, so that, for example, for signals to be transmitted at high frequencies, the bus can be terminated using at least this one further switching element. If the control unit determines that termination of the bus or the bus system is necessary, for example by the signals received by the control unit exceeding a predetermined frequency, it can actively cause the at least one switching element to close. If the second network device and thus also its control unit is not operational or inactive, the at least one switching element changes to the self-locking or open state because it does not receive any control signals for closing from the control unit. The terminating resistor or termination resistor connected in series with this switching element is then inactive, so that the bus system can be terminated via the first network device and the third network device.

The present invention further comprises a network device which is set up to operate as a second network device within the network according to the preceding description. Such a network device includes a first connection port and a second connection port and is set up and designed to be connected via the first connection port to a first connection port of a first network device and via the second connection port to a first connection port of a third network device. Corresponding to the second network device, such a network device according to the invention comprises a transmission and Receiving unit and a control unit in communication connection with the transmitting and receiving unit for controlling a transmission of data, the transmitting and receiving unit for receiving data sent by the first network device, for forwarding this data to the control unit and for sending from the control unit received data is set up to the third network device. The network device is characterized in that it further comprises a controllable switching device which is arranged between the first connection port and the second connection port, wherein the switching device is set up to provide a galvanic connection between the first connection port and the second connection port of the network device in the closed state cause.

Furthermore, the present invention comprises a method for operating a network according to the previous description, in particular for exchanging data between the first network device and the third network device, wherein the switching device of the second network device is operated for the direct exchange of data between the first network device and the third network device in an operating mode in which the switching device, in particular all switching components of the switching device, are in a closed state, so that a galvanic connection is effected between the first connection port and the second connection port of the second network device.

Further advantages, features and possible applications of the present invention will become clear from the following description of embodiments thereof and the associated figures. They show:

Figure 1 : a highly simplified sketch of a connection of three

Network devices within a network topology within the scope of the invention,

Figure 2: a block diagram of the second network device from Figure 1 according to the prior art, Figure 3: a block diagram of a network device within a network according to a first embodiment of the invention, and

Figure 4: a block diagram of a network device within a network according to a second embodiment of the invention.

Figure 1 shows a highly simplified sketch of a connection of three network devices 1, 2, 3 within a network topology, as can also be used within the scope of the invention. As can be seen in Figure 1, the network 10 shown comprises, for example, a first, a second and a third network device 1, 2, 3, which are each electrically connected to a bus system 40. The bus system 40 shown can be designed as any n-wire bus system and is constructed as a daisy chain topology in Figure 1, for example, so that point-to-point connections are established between the individual network devices 1, 2, 3 of the network 10 and the network devices 1, 2, 3 are arranged one after the other in a row or chain. For this purpose, each individual network device 1, 2, 3 in the embodiment of Figure 1 comprises two connection ports 11, 12, 21, 22, 31, 32, also called ports or physical connection points, wherein a first connection port 11 of the first network device 1 is connected to a first connection port 21 of the second network device 2 and a second connection port 22 of the second network device 2 is connected to a first connection port 31 of the third network device 3. Even if not shown in Figure 1, further network devices to the left of the first network device 1 and/or to the right of the third network device 3 can be switched on to the network 10 or connected to the bus system 40 in accordance with the network topology used. For example, a further network device can be connected to a second connection port 12 of the first network device 1 and/or a further network device can be connected to a second connection port 32 of the third network device 3.

Figure 2 shows a block diagram of a possible embodiment of the second network device 2 within the network 10 from Figure 1 according to the prior art. As shown in Figure 2, the second network device 2 is connected to the first network device 1 via its first connection port 21 and to the third network device 3 via its second connection port 22, as indicated by the respective arrows. In the example shown, the second network device 2, and correspondingly also the first and third network devices 1, 3, are connected to a 2-wire bus system 40 constructed as a daisy chain topology, so that the connection ports 21, 22 of the second network device 2 each have two connection pins 21 A, 21B or 22A, 22B. A terminating resistor 37, 38, also called a terminating resistor, is arranged between the two connection pins 21A, 21B of the first connection port 21 and between the two connection pins 22A, 22B of the second connection port 22. The second network device 2 has a control unit 27 and two transmitting and receiving components 24, 25, which are each arranged between the control unit 27 and one of the two connection ports 21, 22 of the second network device 2. Signals or data sent by the first network device 1 can be fed into the second network device 2 via the connection pins 21A, 21B of the first connection port 21. There, these signals or data are first received by the transmitting and receiving component 24, then forwarded to the control unit 27 of the second network device 2 and, if necessary, processed by the control unit 27 before being transmitted via the transmitting and receiving component 25 and via the two connection pins 22A , 22B of the second connection port 22 of the second network device 2 are forwarded to the third network device 3.

However, the structure of the network 10 shown in Figure 2 has the disadvantage that if the second network device 2 is not or no longer operational, e.g. due to a defect such as a lack of power supply, no forwarding of signals or no exchange of data can take place between the first and third network devices 1, 3. In other words, if the second network device 2 is not operational, the first and third network devices 1, 3 can no longer communicate with each other and the transmission of signals or data between the first and third network devices 1, 3 is interrupted. An essential core idea of this invention is therefore to eliminate in particular the disadvantage described above. A corresponding first embodiment of the invention relating to a network 10 which comprises a first, second and third network device 1, 2, 3 which are set up according to the network topology used for the network 10, and relating to a network device for operation as a second network device 2 within the network 10 is shown in Figure 3. The network 10 sketched as an example in Figure 3 is designed according to Figure 1, ie the three network devices 1, 2, 3 are each electrically connected to a bus system 40 which is an n-wire bus system or, in the present example in Figure 3, a 2-wire bus system, the bus system being constructed as a daisy chain topology. According to Figure 2, each network device 1, 2, 3 has two connection ports, whereby in Figures 2 and 3 only the first connection port 21 and the second connection port 22 of the second network device 2 can be seen. As already described with regard to Figures 1 and 2, the first connection port 21 of the second network device 2 in Figure 3 is connected to a first connection port of the first network device

1 connected and the second connection port 22 of the second network device 2 connected to a first connection port of the third network device 3, each symbolized in Figure 3 by corresponding arrows. The second network device 2 comprises a transmitting and receiving unit 23, which in the exemplary embodiment in FIG Communication-connected control unit 27 for controlling a transmission of data. The control unit 27 can include, for example, a microcontroller. A first transmitting and receiving component 24 is between the first connection port 21 and the control unit 27 of the second network device

2 is arranged and is to be operated for communication, while a second transmitting and receiving component 25 is arranged between the second connection port 22 and the control unit 27 of the second network device 2 and is to be operated for communication. The first transmitting and receiving component 24 of the transmitting and receiving unit 23 is at least for receiving the data sent by the first network device 1 via the first connection port 21 and for forwarding the data the control unit 27 is set up. The second transmitting and receiving component 25 of the transmitting and receiving unit 23 is set up at least to receive the data sent by the control unit 27 and to forward this data to the third network device 3 via the second connection port 22. The network 10 of Figure 3 can be set up in particular for the bidirectional exchange of data between the first network device 1 and the third network device 3, so that the functionality of the first and second transmitting and receiving components 24, 25 can also be reversed and both transmitting and receiving components 24, 25 are in particular set up to receive data both via the first connection port 21 and via the control unit 27 or both via the second connection port 22 and via the control unit 27 and forward them accordingly. In FIG. 3, the transmitting and receiving components 24, 25 of the transmitting and receiving unit 23 each include, for example, a transceiver, but in a further embodiment they can also include, for example, a PHY.

The essential difference of the embodiment shown in Figure 3 compared to the embodiment shown in Figure 2 is that the second network device 2 further comprises a controllable switching device 28, which is arranged between the first connection port 21 and the second connection port 22 of the second network device 2. The switching device 28 is set up to effect a galvanic connection, ie an electrically conductive connection, between the first connection port 21 and the second connection port 22 of the second network device 2 in the closed state. This makes it possible for data to continue to be transferred between the first and third network devices 1, 3 even in the event that the second network device 2 is inactive or not operational and is therefore not available for forwarding data between the first and third network devices 1, 3 first and third network devices 1, 3 can be exchanged without restrictions and directly, via an electrically conductive connection between the connection ports 21, 22 of the second network device 2, which is caused by the switching device 28 being in the closed state. In addition to the second network device 2, for example, the first network device 1 and/or the third network device 3 and/or at least one further network device of the network 10 according to the invention can also be constructed in accordance with the second network device 2, that is to say a corresponding transmitting and receiving device 23, control unit 27 and a controllable switching device 28 set up in accordance with the second network device 2.

The method according to the invention for operating a network, for example the network 10 shown in Figure 3, in particular for exchanging data between the first network device 1 and the third network device 3, is at least implicitly illustrated in Figure 3. This method provides that the switching device 28 of the second network device 2 for the direct exchange of data between the first network device 1 and the third network device 3 is operated in an operating mode in which the switching device 28 is in a closed state, so that a galvanic connection is created between the first connection port 21 and the second connection port 22 of the second network device 2. This operating mode can also be referred to as bypass mode, since in this operating mode the second network device 2 is bypassed. In particular, the method according to the embodiment shown in Figure 3 further comprises operating the switching device 28 of the second network device 2 in a further operating state in which the switching device 28 is in an open state and data sent by the first network device 1 is received by the transmitting and receiving unit 23, in particular the transmitting and receiving component 24, of the second network device 2 and forwarded to the control unit 27, and data sent by the control unit 27 is received by the transmitting and receiving unit 23, in particular the transmitting and receiving component 25, and sent to the third network device 3.

In the example of Figure 3, in which a 2-wire bus system is used, the switching device 28 accordingly comprises one switching element for each bus line of the 2-wire bus system, ie two switching elements in Figure 3. The respective switching element is between the corresponding connection pins 21A, 22A or 21B, 22B of the first and second connection ports 21, 22 of the bus line assigned to these connection pins 21A, 22 A and 21B, 22B, respectively. Consequently, the switching device 28 is basically always designed in such a way that when using an n-wire bus system it also includes a number of typically at least n switching elements, so that in each between the first and second connection ports 21, 22 or their connection pins 21A, 22A , 21B, 22B guided bus line of the n-wire bus system at least one switching element is arranged or integrated. Depending on the structure, only part of the n-wire bus system could be switchable by the switching device 28, i.e. only m switching elements with m < n could be present. For example, a common reference potential could not be switchable, for example m = n - 1.

The switching device 28 of the second network device 2 in Figure 3 is designed in particular such that it is self-conductive, i.e. that it must be actively caused to open or disconnect an electrical connection. This has the advantage that the switching device 28 always assumes a closed state in the event of a non-operational second network device 2, without the switching device 28 needing to be controlled. This creates an electrically conductive connection between the connection ports 21, 22 of the second network device 2, which enables direct communication between the first and the third network device 1, 3. For example, the switching device 28 can comprise at least one semiconductor-based switching element, with both switching elements of the switching device 28 shown in Figure 3 being designed as semiconductor-based switching elements, for example. In addition to this, or in a further embodiment not shown as an alternative, the control unit 27 of Figure 3 is advantageously set up to cause the switching device 28 to open, in particular by means of a control signal 29 sent to the switching device 28, as shown in Figure 3 by the dashed arrow. If the second network device 2, and thus also its control unit 27, is operational, the control unit 27 in Figure 3 is set up to send a control signal 29 to the switching device 28, which causes the switching device 28 to open or disconnect an electrical connection. If the switching device 28 is in an open state, so that there is no electrically conductive connection between the first connection port 21 and the second connection port 22 or the connection is high-impedance, data can be forwarded from the first network device 1 via the second network device 2 with the involvement of the transmitting and receiving unit 23 or its transmitting and receiving components 24, 25 and the control unit 27 to the third network device 3, as was described with regard to Figure 2. The network 10 can thus be operated as intended and in accordance with the network topology used, with data sent by the network device 1 being transmitted via point-to-point connections to at least the third network device 3. If, on the other hand, the second network device 2 is inactive, e.g. due to a defect or due to the second network device 2 being switched off, the control unit 27 can no longer send a control signal 29 to the switching device 28, whereupon the switching device 28 changes to the self-conducting state. As previously described, a galvanic connection is established between the first and the second connection port 21, 22 of the second network device 2, so that data can continue to be exchanged between the first and the third network device 1, 3, but now directly, ie without the active participation of the second network device 2 in the data transmission.

The second network device 2 of the network 10 can thus be operated in at least one operating mode for exchanging data between the first network device 1 and the third network device 3, this operating mode being defined by the fact that the switching device 28 is in a closed state. This operating mode can also be called bypass mode, since the second network device 2 is bypassed during this operating mode. Nevertheless, if necessary, in this operating state, the second network device 2 can also take part in the communication between the first network device 1 and the third network device 3 via the participation of the transmitting and receiving unit 23, provided that the second network device 2 is operational. Furthermore, the second network device 2 according to FIG. 3 is for exchanging data between the first network device 1 and the Third network device 3 can be operated in two operating modes, the further operating mode being defined by the fact that the switching device 28 is in an open state. As mentioned at the beginning, the network 10 is set up in particular for the bidirectional exchange of data between the first network device 1 and the third network device 3.

Depending on the bus system, clock frequency and PHY, it may be useful or even necessary for at least the second network device 2 to comprise at least one further switching element, so that, for example, when signals with high frequencies are to be transmitted, the bus can be terminated using at least this one further switching element. Therefore, the second network device 2 of the network 10 according to the invention or the network device 2 according to the invention comprises in particular at least one controllable switching element which is arranged in a series circuit with a terminating resistor between all connection pins of at least one of the first and second connection ports of the second network device 2. Preferably, this at least one switching element is self-locking, wherein the control unit is set up to cause the at least one switching element to close. In the embodiment of Figure 3, the second network device 2 comprises, for example, a first controllable switching element 34 connected in series with a first terminating resistor 37, this series connection being arranged between the two connection pins 21A, 21B of the first connection port 21 of the second network device 2, and also a second controllable switching element 35 connected in series with a second terminating resistor 38, this series connection being arranged between the two connection pins 22A, 22B of the second connection port 22 of the second network device 2. The two switching elements 34, 35 in Figure 3 are self-locking, i.e. they must be actively caused to close or establish an electrically conductive connection. In the embodiment of Figure 3, the control unit 27 is set up to cause the two switching elements 34, 35 to close, either simultaneously or independently of one another. In particular, the control unit 27 can send a control signal to the respective switching elements 34, 35, which causes the switching elements 34, 35 to close. If the If the control unit 27 determines, for example, that termination of the bus or bus system 40 is necessary, for example because the signals received by the control unit 27 exceed a predetermined frequency and/or if this is fundamentally necessary to enable reliable operation, it can actively cause the switching elements 34, 35 to close. If, however, the second network device 2 and thus also its control unit 27 are not operational or inactive, the two switching elements 34, 35 go into the self-locking or open state because they do not receive a control signal to close from the control unit 27. The terminating resistor 37, 38 connected in series with a respective switching element 34, 35, also called a termination resistor, is then inactive, so that termination of the bus system 40 can take place via the first network device 1 and the third network device 3.

Figure 4 shows a block diagram of a network device, namely the second network device 2', within a network 10 and for operating the network 10 according to a second embodiment of the invention that is an alternative to Figure 3. According to Figure 4, the second network device 2' has a transmitting and receiving unit 23' which, in contrast to the second network device 2 shown in Figure 3, is made up of only a single transmitting and receiving component 26. This has the advantage, among other things, that costs can be saved due to the lack of a second transmitting and receiving component. In addition, the switching device 28' of the second network device 2' according to Figure 4, in contrast to the switching device 28 from Figure 3, has several, namely two, switching components 28a, 28b, with which the transmitting and receiving component 26 can be connected optionally to the first connection port 21, to the second connection port 22 or to the first and second connection ports 21, 22 of the second network device 2. The term "switching component" in the context of the invention is not to be equated with the term "switching element" used in the context of the invention. While a switching component in the context of the invention can cause the electrical connection of an entire bus, including its up to n bus lines, a switching element in the context of the invention is designed to cause the electrical connection of only a single bus line of a bus to be disconnected. A switching component Thus, within the scope of the invention, for separating the electrical connection of an n-wire bus, it comprises a number of up to n switching elements.

The controllable switching device 28' of the second network device 2' shown in Figure 4 or the switching components 28a, 28b included in it are, as is also the case in Figure 3, arranged between the first connection port 21 and the second connection port 22 of the second network device 2'. Furthermore, the switching device 28' according to Figure 4 is designed to bring about a galvanic or electrically conductive connection between the first connection port 21 and the second connection port 22 of the second network device 2' when closed, whereby in the embodiment of Figure 4 this means that both switching components 28a, 28b must each be in the closed state. The embodiment of the invention shown in Figure 4 therefore also ensures that an exchange of data between the first and third network devices 1, 3 can take place even when the second network device 2' is inactive or not operational.

The first network device 1 and/or the third network device 3 and/or at least one further network device of the network 10 according to the invention can or can be constructed in accordance with the second network device 2 according to FIG. 3 or in accordance with the second network device 2′ according to FIG. 4, i.e. a corresponding transmitting and receiving device 23, 23 ', control unit 27 and a controllable switching device 28 or 28 ' set up in accordance with the second network device 2 or 2'.

Figure 4 illustrates, at least implicitly, the method according to the invention for operating the network 10, in particular for exchanging data between the first network device 1 and the third network device 3. It is provided that the switching device 28' of the second network device 2' for the direct exchange of data between the first network device 1 and the third network device 3 is operated in an operating mode which can be referred to as bypass mode, wherein the switching device 28', namely according to Figure 4 all switching components 28a, 28b of the switching device 28', are in a closed state so that a galvanic connection is established between the first connection port 21 and the second connection port 22 of the second network device 2'.

The switching device 28' or its switching components 28a, 28b are designed according to Figure 4, for example, such that they are self-conducting and therefore have to be actively controlled to open or disconnect the electrical connection. Furthermore, each of the switching components 28a, 28b according to Figure 4 comprises, for example, a semiconductor-based switching element integrated in each of the individual bus lines of the bus system 40. The control unit 27 is, as in Figure 3, designed to cause the switching device 28' to open. However, the control unit 27 according to Figure 4 can cause each of the switching components 28a, 28b to open individually and separately from one another, for example by sending a corresponding control signal 29a, 29b to the respective switching component 28a, 28b.

Thus, the second network device 2' within the network 10 can basically be operated in four operating modes depending on the respective state of the two switching components 28a, 28b. In one of these operating modes, in which both switching components 28a, 28b are in an open state, however, no communication or exchange of data can take place between any two of the three network devices 1, 2', 3. Furthermore, an exchange of data between the first and the third network device 1, 3 can only be made possible in the embodiment shown in Figure 4 if both switching components 28a, 28b are in a closed and thus electrically conductive state at least for the period of data transmission, as is provided in another of the four operating modes of the second network device 2'. In the two further operating modes, only one of the switching components 28a, 28b is in a closed state, while the other of the switching components 28a, 28b is in an open state. Consequently, data can only be exchanged between the second network device 2' and the first network device 1 (switching component 28a closed, switching component 28b opened) or between the second network device 2' and the third network device 3 (switching component 28a opened, Switching component 28b closed). The network 10 outlined in Figure 4 is also set up, in accordance with the network 10 outlined in Figure 3, for the bidirectional exchange of data between the first network device 1 and the third network device 3.

According to an embodiment not shown in the figures, the network 10 according to the invention can also comprise a number of further network devices, each of which is set up in accordance with the network topology used for the network 10 and which can be connected to the network 10 in particular during ongoing operation of the network 10. Thus, in the embodiments of Figures 3 and 4, at least one further network device can be connected to the second connection port 12 of the first network device 1 and/or at least one further network device can be connected to the second connection port 32 of the third network device 3 or can be connected during ongoing operation (see Figure 1 with regard to the network topology). In addition or as an alternative to this, at least the second network device 2, 2', in particular each individual network device of the network 10, can comprise at least three connection ports, even if this is not shown in the figures. The network 10 can also comprise an n-wire bus system with n>3 instead of the predominantly described embodiment of a 2-wire bus system.

In summary, the invention relates to a network with at least three network devices, of which the second network device arranged between the first and the third network device and connected to the network comprises a controllable switching device, and furthermore to such a network device with a controllable switching device and a method for operating the network, wherein an exchange of data between the first and the third network device is maintained even in the event of a failure, e.g. a defect, of the second network device. This is made possible by the fact that the switching device is arranged between two connection ports of the second network device and, in the closed or conductive state, creates a galvanic connection between these connection ports. List of reference symbols

I first network device

2, 2‘ second network device

3 third network device

10 Network

I I first connection port of the first network device

12 second connection port of the first network device

21 first connection port of the second network device

22 second connection port of the second network device

23, 23 ‘ Transmitting and receiving unit

24 Transmitting and receiving components

25 transmitting and receiving components

26 Transmitting and receiving components

27 Control unit

28, 28‘ Switching device

28a switching component

28b switching component

29 control signal

29a control signal

29b Control signal

31 first connection port of the third network device

32 second connection port of the third network device

34 Switching element

35 switching element

36 Switching element

37 Termination resistor

38 Termination resistor

39 Termination resistor

40 bus system

Claims

Patent claims

1. Network (10) comprising at least a first, a second and a third network device (1, 2, 2 ', 3), each of which is set up in accordance with a network topology used for the network (10), each individual network device (1, 2, 2', 3) has at least two connection ports (11, 12, 21, 22, 31, 32), so that a first connection port (11) of the first network device (1) is connected to a first connection port (21) of the second network device (2 , 2') is connected and a second connection port (22) of the second network device (2, 2') is connected to a first connection port (31) of the third network device (3), and wherein the second network device (2, 2') is a Transmitting and receiving unit (23, 23 ') and a control unit (27) which is in communication connection with the transmitting and receiving unit (23, 23') for controlling a transmission of data and the transmitting and receiving unit (23, 23') is set up to receive data sent by the first network device (1), to forward this data to the control unit (27) and to send data received from the control unit (27) to the third network device (3), characterized in that second network device (2, 2') further comprises a controllable switching device (28, 28'), which is arranged between the first connection port (21) and the second connection port (22) of the second network device (2), wherein the switching device (28, 28') is set up to effect a galvanic connection between the first connection port (21) and the second connection port (22) of the second network device (2, 2') in the closed state.

2. Network (10) according to claim 1, wherein the switching device (28, 28 ') is normally conductive and in particular comprises at least one semiconductor-based switching element, and / or the control unit (27) is set up to use the switching device (28, 28'). To cause it to open, in particular by means of a control signal (29) sent to the switching device (28, 28 ').

3. Network (10) according to claim 1 or 2, wherein the second network device (2, 2') is operable in at least one operating mode for exchanging data between the first network device (1) and the third network device (3), wherein this operating mode is defined in that the switching device (28, 28') is in a closed state, wherein the second network device (2) is operable in particular in two operating modes for exchanging data between the first network device (1) and the third network device (3), and the further operating mode is defined in that the switching device (28) is in an open state, and/or the network (10) is set up for bidirectional exchange of data between the first network device (1) and the third network device (3).

4. Network (10) according to one of claims 1 to 3, wherein the transmitting and receiving unit (23) is constructed from a plurality of separate transmitting and receiving components (24, 25), and a transmitting and receiving component (24, 25) is to be operated for communication between the first connection port (21) and the control unit (27) of the second network device (2) and between the second connection port (22) and the control unit (27) of the second network device (2), or wherein the transmitting and receiving unit (23') is constructed from a single transmitting and receiving component (26), and the switching device (28') has a plurality of switching components (28a, 28b) with which the transmitting and receiving component (26) can be selectively connected to the first connection port (21), to the second connection port (22) or to the first and second connection ports (21, 22) of the second network device (2'). can be connected, wherein each individual transmitting and receiving component (24, 25, 26) of the transmitting and receiving unit (23, 23') comprises in particular a transceiver or a PHY.

5. Network (10) according to one of claims 1 to 4, wherein the network (10) comprises a bus system (40), in particular an n-wire bus system designed as a daisy chain topology, to which at least the first, the second and the third network device (1, 2, 2', 3) are connected, wherein the bus system (40) preferably comprises a 2-wire bus system and each of the at least two connection ports (11, 12, 21, 22, 31, 32) of a respective network device (1, 2, 2', 3) has two connection pins (21 A, 21B, 22A, 22B).

6. Network (10) according to one of claims 1 to 5, wherein the second network device (2, 2') further comprises at least one controllable switching element (34, 35, 36) which is arranged in a series connection with a terminating resistor (37, 38, 39) between all connection pins (21A, 21B, 22A, 22B) of at least one of the first and second connection ports (21, 22) of the second network device (2, 2').

7. Network (10) according to claim 6, wherein the at least one switching element (34, 35) is self-locking and wherein the control unit (27) is set up to cause the at least one switching element (34, 35) to close.

8. Network (10) according to one of claims 1 to 7, wherein the network (10) comprises a number of further network devices which can be connected to the network in particular during ongoing operation of the network (10), and/or wherein at least the second network device (2, 2'), in particular each individual network device of the network (10), comprises at least three connection ports.

9. Network device (2, 2') which is configured to operate as a second network device (2, 2') within a network (10) according to one of claims 1-8.

10. Method for operating a network (10) according to one of claims 1-8, in particular for exchanging data between the first network device (1) and third network device (3), wherein the switching device (28, 28 ') of the second network device ( 2, 2') for the direct exchange of data between the first network device (1) and the third network device (1) is operated in an operating mode in which the switching device (28, 28'), in particular all switching components (28a, 28b) the switching device (28 '), is in a closed state, so that a Galvanic connection between the first connection port (21) and the second connection port (22) of the second network device (2, 2 ') is effected.