LU100282B1 - One-Way Data System (ODS) - Google Patents

Abstract

A one-way data device (ODD) is suggested, comprising a fiber-optic cable (FO), a transmitter terminal (Tx), and a receiver terminal (Rx). The transmitter terminal (Tx) comprises a light source and no light detection sensor, and the receiver terminal (Rx) comprises a light detec- tion sensor and no light source. The transmitter terminal (Tx) and the receiver terminal (Rx) are connected by the fiber-optic cable (FO) such that data can be transmitted from the transmitter terminal (Tx) to the receiver terminal (Rx). Such a device provides a simple and effective means of ensuring that data is transmitted only in one direction. A one-way data system (ODS) is also suggested, comprising a transmitter computer (100) and a receiver computer (110) connected by a one-way data device (ODD). A corresponding method is also provided.

Description

DESCRIPTION

FIELD OF THE INVENTION

The present invention relates to a device for unidirectional data transmission, and a corresponding system and method. These relate to IT infrastructure, especially to connecting an operating technology (OT) network, e.g. at a power plant or factory, with larger, insecure networks such as the internet, while maintaining the isolation of the plant network that is required for security reasons.

DESCRIPTION OF RELATED ART

Important infrastructure installations, such as power stations, usually operate in island mode for security reasons. Consequently, the operating data of each station is only available locally in the respective station control room. However, in the present world of information diversification, it is often considered desirable to make this data available to authorized users for online production plant monitoring, evaluation, reporting and decision making. For this purpose, the operating technology (OT) networks must be connected to wider, less secure networks (such as the internet). In order to maintain the necessary security at the plant, data should be allowed to flow in one direction only, and it should not be possible to send any form of command or data to the OT network. The possible security measures to establish such a connection are to use a suitable protocol in combination with the one of the following solutions: • installation of firewalls; • VPN tunneling; or • deploying one of the available unidirectional solutions in the market.

Each of these solutions has its own disadvantages relative to secure one way data transfer: The technological limitations and requirements of firewalls and/or VPN tunneling do not guarantee one-way (unidirectional) data transfer. Available solutions in the market that claim one-way data communication and physically unidirectional data flow are generally proprietary. Thus, it is not possible to verify that they are truly unidirectional. In addition, the marketed solutions frequently use FTP (file transfer protocol) to transfer data in form of files or folders. This protocol is not well suited to continuous streaming of real-time data.

OBJECT OF THE INVENTION

It is, therefore, an object of the present invention to provide a more secure device, system and method for unidirectional data transmission.

BRIEF SUMMARY OF THE INVENTION

This aim is achieved by the inventions as claimed in the independent claims. Advantageous embodiments are described in the dependent claims, the disclosure of which is hereby incorporated into the description by reference.

Even if no multiple back-referenced claims are drawn, all reasonable combinations of the features in the claims shall be disclosed.

The object of the invention is achieved by a device for unidirectional data transmission, also called “one-way data device” or ODD, comprising a fiber-optic cable, a transmitter terminal, and a receiver terminal. The transmitter terminal comprises a light source and no light detection sensor, and the receiver terminal comprises a light detection sensor and no light source. The transmitter terminal and the receiver terminal are connected by the fiber-optic cable such that data can be transmitted from the transmitter terminal to the receiver terminal.

Since the transmitter terminal contains no light detection sensor, it is physically incapable of receiving information from the cable. In the same way, the receiver terminal is physically incapable of sending information through the cable, since it does not contain a light source. Such a device provides a simple and effective means of ensuring that data is transmitted only in one direction. Security is enhanced, since the device is physically incapable of transmitting data from the receiver terminal to the transmitter terminal.

In a preferred embodiment, the device for unidirectional data transmission is located inside a container, which is secured with a lock. The components are thus protected and, in particular, do not move relative to one another. Failure of the fiber-optic cable consequently becomes very unlikely. It is especially preferred if the container is designed to fit a 19-inch rack.

It is also considered advantageous if the receiver terminal and the transmitter terminal each have a modular connector. A connector of the 8P8C type (commonly referred to as RJ45 Ethernet connector) is preferred. Thus, a standardized connection to other IT or networking devices is provided.

The object of the invention is also achieved by a system for unidirectional data transmission, also called “one-way data system” or ODS, comprising a one-way data device as described above, a transmitter computer, and a receiver computer. The receiver computer is connected to the transmitter computer by the one-way data device.

Such a system can provide a complete solution for connecting e.g. an OT network to e.g. the internet, while ensuring the security of the OT network, since the one-way data system can guarantee that the connection is unidirectional - it is then physically impossible for data to travel from the internet to the OT network through the ODS.

Preferably, the transmitter computer is configured to a) receive or fetch data from a data source, b) write said data from said data source to a spreadsheet file, c) read data from said spreadsheet file, and d) send said data from said spreadsheet file to the device for unidirectional data transmission. The data from said spreadsheet file is sent via the UDP protocol.

The data source could be, for example, a server in an operating technology network at a power plant or factory, typically an OPC (Open Platform Communication) server. An OPC client could, for example, receive data from such a server and write it to a spreadsheet file, preferably in MS Excel format.

Preferably, the receiver computer is configured to a) receive data from the device for unidirectional data transmission via the UDP protocol, b) check said data from the device for unidirectional data transmission for errors, c) generate a notification if an error is found, d) write said data from the device for unidirectional data transmission to a spreadsheet file, preferably in MS Excel format, and e) provide data from said spreadsheet file over a network connection.

The error checking feature is necessary, since UDP does not guarantee error-free delivery of data. The checksums provided by UDP may be used for this purpose. It is preferred, however, to include additional error-checking signals in the data in order to increase data security. If an error in the data is found, the notification could be generated in form of e.g. an email or an SMS to e.g. the relevant system administrator.

In a further embodiment of the system for unidirectional data transmission, the transmitter computer, the receiver computer and the device for unidirectional data transmission are each designed to fit a 19-inch rack.

Security, and especially reliability, is enhanced, if the transmitter computer, the receiver computer and the device for unidirectional data transmission are arranged in a single cabinet; and said cabinet is secured with a lock. Cable failures thus become very unlikely, since the components of the system do not move relative to one another, and the cables are not accessible and thus cannot be tampered with.

The object of the invention is also achieved by a method. In what follows, individual steps of a method will be described in more detail. The steps do not necessarily have to be performed in the order given in the text. Also, further steps not explicitly stated may be part of the method. A method for unidirectional data transmission is therefore suggested, comprising the following steps: a) receiving or fetching data from a data source; b) writing said data to a spreadsheet file; c) reading data from the spreadsheet file; d) converting said data from said spreadsheet file into datagrams; e) transmitting said datagrams to the transmitter terminal of a device for unidirectional data transmission according to any one of claims 1 to 4; wherein the UDP protocol is used; f) transmitting said datagrams from the transmitter terminal to the receiver terminal along the fiber-optic cable of said device for unidirectional data transmission; g) receiving said datagrams from the receiver terminal of said device for unidirectional data transmission; h) performing error checking on the received datagrams; i) generating a notification if an error is found; j) converting said datagrams to spreadsheet data; k) writing said spreadsheet data to a spreadsheet file; and l) providing data from said spreadsheet file over a network connection.

Furthermore, the object of the invention is achieved by - a computer program, wherein the computer program is adapted to perform steps c) to e) of the method described above while said computer program is being executed on a transmitter computer in a one-way data system as described above; and by - a computer program, wherein the computer program is adapted to perform steps g) to k) of the method described above while said computer program is being executed on a receiver computer in a one-way data system as described above.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Other objects and advantages of the present invention may be ascertained from a reading of the specification and appended claims in conjunction with the drawings therein.

For a more complete understanding of the present invention, reference is established to the following description made in connection with accompanying drawings in which:

Fig. 1 shows a schematic diagram of a device for unidirectional data transmission (ODD) as part of a system for unidirectional data transmission (ODS);

Fig. 2 shows a diagram of the data flow through a one-way data system (ODS);

Fig. 3 shows a schematic of a first preferred embodiment of the invention for real time data transfer; and

Fig. 4 shows a schematic of a second preferred embodiment of the invention for re mote file transfer.

DETAILED DESCRIPTION OF THE INVENTION

The configuration of a one-way data device according to the invention is shown in Fig. 1. This device for unidirectional data transmission ODD, the transmitter computer 100 and the receiver computer 110 together form a system for unidirectional data transfer ODS. The one-way data device ODD typically provides modular connectors IN, OUT for connections to these computers.100, 110 via Ethernet cables RJ45. Inside the one-way data device, the input connector IN is connected to a transmitter terminal Tx (e.g. by an Ethernet cable RJ45). The transmitter terminal Tx contains a light source, but no light detection sensor, and is designed to convert the electrical signals from the input into optical signals. These are transmitted along the fiber-optic cable FO to the receiver terminal Rx, which contains a suitable light detection sensor, but no light source. The receiver terminal Rx converts the optical signals received back into electrical signals, which are supplied to the output connector OUT (typically via an Ethernet cable RJ45). The receiver terminal Rx is thus unable to send information back along the fiber-optic cable FO.

The typical data flow through a system for unidirectional data transmission according to the invention is shown in Fig. 2: The data is fetched 200 from a server, or otherwise supplied to the transmitter computer 100. Typically, the data is supplied by an OPC server, e.g. located at a power plant or factory, and fetched by an OPC client installed on the transmitter computer 100. The data from the OPC server is then written 210 to a spreadsheet file, e.g. in MS Excel format. At this stage, the data can be modified by an operator, e.g. in order to add or remove additional signals according to the desired use of the data. Transmitter software on the transmitter computer 100 then reads data from said spreadsheet file, converts the data to UDP datagrams and sends 220 these to the device for unidirectional data transmission ODD. At this stage, signals for data verification and error checking may be added. The data transfer may preferably occur as a continuous stream. After passing through this device, the UDP datagrams are received 230 by receiver software installed on the receiver computer 110. At this stage, the transmitted data is checked for errors and then written 240 to a spreadsheet file, typically in MS Excel format. Users may be allowed to modify tag descriptions etc. as required. If errors are detected, a corresponding notification can be generated, usually in form of an email or SMS, in order to warn a responsible person that the one-way data system is not working correctly. Data from this spreadsheet file is provided 250 by the receiver computer 110, for example by an OPC server installed on the receiver computer that acts - to the outside world - as a substitute for the OPC server at the plant, which is thus protected from outside influences by the one-way data system. A use-case of the system for unidirectional data transmission ODS for real-time data transfer is illustrated schematically in Fig. 3. In this embodiment, an OPC server computer 310 resides on a plant DCS (Distributed Control system) network 300. The server 310 is tasked with fetching and subsequently providing real-time operating, monitoring and control signals of machines connected to the plant network 300. The one-way data system ODS is connected to this server 310. The transmitter computer 100 of the ODS gets the data from the OPC server 310 in real-time using OPC client software and transfers these real-time data into a spreadsheet. In a typical situation, MS Excel or similar software can thus be used as a user interface tool to add or remove any additional signals that may be required. The transmitter software on the transmitter computer 100 continuously checks for changes in the data, obtains any identified data change from the spreadsheet in real-time and pushes these data through the device for unidirectional data transmission ODD to the receiver computer 110 via UDP. The receiver software on the receiver computer 110 receives the transmitted data from the transmitter computer 100 and continuously updates the data into a spreadsheet in realtime, for example in Excel format. An OPC Server installed on the receiver computer 110 receives the real-time data available in the spreadsheet, e.g. through DDE (Dynamic Data Exchange) or a similar interprocess communication method. This OPC server (on the receiver computer 110) is linked to an interface computer 320, which is part of an outside network 330, e.g. a corporate business network. Real-time data from the plant can thus be continuously provided to a remote information system, without exposing the plant network 300 to the less secure network 330. A second use-case of the system for unidirectional data transmission ODS for a remote diagnostic situation is illustrated schematically in Fig. 4. In this embodiment, a diagnostics computer 400 collects diagnostic data, e.g. from machines installed at the plant, from the plant network 300. At scheduled times, the diagnostics computer 400 pushes the data, e.g. in form of files, to the transmitter computer 100 of the system for unidirectional data transmission ODS, e.g. via the plant network 300. The transmitter software installed on the transmitter computer 100 receives these data files from the diagnostics computer 400 and (if applicable) converts and pushes them through the device for unidirectional data transmission ODD to the receiver computer 110 using UDP. The receiver software installed on the receiver computer 110 receives the transmitted data file(s) from the transmitter computer 100 and pushes to the remote service/diagnostic system 420 over the internet 410, e.g. via an ADSL line. The remote service/diagnostics system 420 is thus regularly supplied with diagnostics data from the local diagnostics computer 400 located at the plant, even via the insecure internet 410, without actually exposing the plant network 300 to the internet. Even if the remote service/diagnostics system 420 were to become compromised, it could not send any (potentially dangerous) signals to the plant network.

While the present inventions have been described and illustrated in conjunction with a number of specific embodiments, those skilled in the art will appreciate that variations and modifications may be made without departing from the principles of the inventions as herein illustrated, as described and claimed. The present inventions may be embodied in other specific forms without departing from their spirit or essential characteristics. The described embodiments are considered in all respects to be illustrative and not restrictive. The scope of the inventions is, therefore, indicated by the appended claims, rather than by the foregoing description. All changes which come within the meaning and range of equivalence of the claims are to be embraced within their scope.

Glossary

Datagram A datagram is a basic transfer unit associated with a packet-switched network. Datagrams are typically structured in header and payload sections. Datagrams provide a connectionless communication service across a packet-switched network. The delivery, arrival time, and order of arrival of datagrams need not be guaranteed by the network. The term datagram is often considered synonymous to packet, but datagram is generally reserved for packets of an unreliable service, which cannot notify the sender if delivery fails, while the term packet applies to any packet, reliable or not (according to https://en.wikipedia.org/wiki/Datagram).

DCS A distributed control system (DCS) is a computerized control system for a process or plant, in which autonomous controllers are distributed throughout the system, but there is central operator supervisory control. This is in contrast to non-distributed control systems that use centralized controllers; either discrete controllers located at a central control room or within a central computer. The DCS concept increases reliability and reduces installation costs by localizing control functions near the process plant, but enables monitoring and supervisory control of the process remotely (according to https://en.wikipedia.org/wiki/Distributed_control_system).

DDE

Dynamic Data Exchange (DDE) is a method of interprocess communication under Microsoft Windows or OS/2. It allows one program to subscribe to items made available by another program, for example a cell in a Microsoft Excel spreadsheet, and be notified whenever that item changes. DDE was partially superseded by Object Linking and Embedding (OLE), but remains used for simple interprocess communication tasks. (See https://en.wikipedia.org/wiki/Dynamic_Data_Exchange.)

Modular connector (8P8C) A modular connector is an electrical connector that was originally designed for use in telephone wiring, but has since been used for many other purposes. Probably the most well-known applications of modular connectors are for telephone jacks and for Ethernet jacks, both of which are nearly always modular connectors.

The 8 position 8 contact (8P8C) connector is a modular connector commonly used to terminate twisted pair and multi-conductor flat cable. These connectors are commonly used for Ethernet over twisted pair, registered jacks and other telephone applications, RS-232 serial using the EIA/TIA-561 and Yost standards, and other applications involving unshielded twisted pair, shielded twisted pair, and multi-conductor flat cable. 8P8C un-keyed modular connectors are commonly referred to as RJ45 in the context of Ethernet. (See https://en.wikipedia.org/wiki/Modular_connector.)

OPC

Open Platform Communication (OPC, formerly known as OLE for Process Control) is a series of standards and specifications for industrial telecommunication and specifies the communication of real-time data, e.g. at a power plant, between various control devices, e.g. from different manufacturers. OPC servers provide standardized methods for any OPC client software to access data from a process control device (such as a distributed control system DCS). Traditionally, any time a software package needed access to data from a device, a custom interface, or driver, had to be written. The purpose of OPC is to define a common interface that is written once and then reused by any (e.g. business, SCADA, HMI, or custom) software packages.

UDP

The User Datagram Protocol (UDP) is formally defined in RFC 768. UDP uses a simple connectionless transmission model with a minimum of protocol mechanism. UDP provides checksums for data integrity, and port numbers for addressing different functions at the source and destination of the datagram. It has no handshaking dialogues, and thus exposes the user's program to any unreliability of the underlying network: there is no guarantee of delivery, ordering, or duplicate protection. UDP is suitable for purposes where error checking and correction are either not necessary or are performed in the application. Time-sensitive applications often use UDP because dropping packets is preferable to waiting for delayed packets, which may not be an option in a real-time system (According to https://en.wikipedia.org/wiki/User_Datagram_Protocol).

References 100 transmitter computer 110 receiver computer 200 fetch data from server 210 write data to file

220 send data from file to ODD

230 receive and check data from ODD 240 write data to file 250 provide data from file 300 plant network 310 plant OPC server 320 interface computer 330 outside network 400 diagnostics computer 410 internet 420 remote service/diagnostic system FO fiber-optic cable IN, OUT modular connectors ODD device for unidirectional data transmission ODS system for unidirectional data transmission RJ45 Ethernet cable

Rx receiver terminal

Tx transmitter terminal

Claims (12)

Claims: A device for unidirectional data transmission (ODD), comprising: a) a fiber optic cable (FO), b) a transmitter terminal (Tx) and c) a receiver port (Rx); d) wherein the transmitter terminal (Tx) comprises a light source and not a light detection sensor; e) wherein the receiving port (Rx) comprises a light detection sensor and no light sources; and f) wherein the transmitter terminal (Tx) and the receiver terminal (Rx) are connected by the fiber optic cable (FO) such that data can be transmitted from the light source of the transmitter terminal (Tx) to the light detection sensor of the receiver terminal (Rx). 2. Apparatus according to claim 1; the device being within a container; and wherein the container is secured with a lock. 3. Apparatus according to claim 2; the container is designed for a 19-inch rack. 4. Device according to one of claims 1 to 3; wherein the receiver terminal (Rx) and the transmitter terminal (Tx) each have a modular connection (input, output). A system for unidirectional data transfer (ODS), comprising: an apparatus (ODD) according to any one of claims 1 to 4, a sender computer (100) and a receiving computer (110); wherein the receiving computer (110) is connected to the transmitting computer (100) by the device (ODD) according to any one of claims 1 to 4. 6. System according to claim 5; wherein the sender computer (100) is configured to: a) receive or retrieve data from a data source (310; 400); b) transfer data from the data source (310; 400) to a spreadsheet; c) read data from this spreadsheet; and d) sending this data from the spreadsheet file to the unidirectional data transfer (ODD) device; where the data is sent from the spreadsheet file via the UDP protocol. 7. System according to claim 5 or 6; wherein the receiver computer (110) is configured to: a) receive data from the unidirectional data transfer (ODD) device via the UDP protocol: b) check this data for errors from the device for unidirectional data transfer (ODD); c) generate a notification if an error is found; (d) transferring these data from the device for unidirectional data transmission to a spreadsheet; and e) to provide this data from this spreadsheet via a network connection. 8. System according to any one of claims 5 to 7; wherein the transmitter computer (100), the receiver computer (110) and the unidirectional data transfer device (ODD) are each designed for a 19-inch rack. 9. System according to one of claims 5 to 8; wherein the sender computer (100), the receiving computer (110) and the unidirectional data transfer device (ODD) are arranged in a single cabinet; and wherein the housing is secured with a lock. 10. Method for unidirectional data transmission; comprising the steps of: a) receiving or retrieving (200) data from a data source; b) transmitting (210) that data into a spreadsheet; c) reading data from the spreadsheet; d) converting this data from this spreadsheet to datagrams; e) transmitting (220) these datagrams to the transmitter terminal of a device for unidirectional data transmission (ODD) according to one of claims 1 to 4; using the UDP protocol; f) transmitting these datagrams from the transmitter terminal to the receiver terminal over the fiber optic cable of the unidirectional data transfer (ODD) device; g) receiving (230) these datagrams from the receiving terminal of the unidirectional data transmission device; h) performing an error check (230) of the received datagrams; i) generate a notification if an error is found; j) conversion of these datagrams into spreadsheet data; k) transmitting (240) said spreadsheet data to a spreadsheet; and l) provide (250) data from said spreadsheet file via a network connection. A computer program, wherein the computer program is adapted to carry out steps c) to e) of the method according to claim 10, while this computer program is executed on a sender computer (100) in a system (ODS) according to one of claims 5 to 9. A computer program, wherein the computer program is adapted to execute steps g) to k) of the method according to claim 10, while this computer program is executed on a receiver computer (110) in a system (ODS) according to one of claims 5 to 9. google translate for business: translator toolkit website translator