WO2008125527A1 - Method for providing reliable status information for measured values in process automation applications - Google Patents

Abstract

The invention relates to a method for providing reliable status information for measured values in process automation applications, wherein in addition to a conventional piece of status information (ST1), a second piece of status information (ST2) is determined in accordance with the quality of the transmission of the measured value.

Description

 description

Method for providing reliable status information for measured values in process automation applications

The invention relates to a method for providing reliable status information for measured values in process automation applications.

In the process automation technology field devices are often in

Process automation applications are used to detect or influence process variables. Various such field devices are manufactured and sold by the Endress + Hauser Group. As a rule, the measured values are transmitted via wired fieldbus systems to control units which serve for process control and generate corresponding control signals for actuators on the basis of current measured values. The transmission of the measured values from the field devices to the control units takes place by means of a telegram in data packets which are specified in accordance with the fieldbus system. As a rule, status information is always transmitted to the control units with the measured value. Due to the status information, a control unit can recognize the quality of the measured value. For fieldbus systems, there are usually three different categories of status information available; good ("good"), uncertain ("uncertain") or bad ("bad"): If the field device works in its specified range and if the measuring signal is to be reliably evaluated, the status information "good" is assigned. If the field device operates outside of the specified ranges or if it is difficult to evaluate the measurement signal, the status information "uncertain" is assigned If the conditions for the evaluation of the measurement signal are poor and a measured value can only be determined with great difficulty, the status information " Bad ".

Previously used wired fieldbus systems allow safe process control on the basis of the status information transmitted with the measured values.

Wired fieldbus systems can also be used as deterministic Networks are called, because in the data transmission between field devices, control units and actuators over the fieldbus cable and the protocols used a defined duration of the signal is guaranteed.

Recently, non-deterministic wireless networks for

Data transmission in process automation applications known. An example of this is the standard currently under discussion for wireless HART (Wireless HART) communication. Examples of wired but non-deterministic networks are TCP / l P-based networks, such as LAN, Internet, etc. Again, data transfer may be delayed. If a control unit processes a measured value that has the status information "good" but has only reached the control unit with a relevant delay, safe process control may no longer be guaranteed because the control signals are generated too late Safe process control is no longer reliable enough.

The object of the invention is therefore to provide a method for providing a reliable status information for measured values in process automation applications, which does not have the above-mentioned disadvantages and in particular enables a secure process control.

This object is achieved by the method features specified in claim 1.

Advantageous further development of the invention are specified in the subclaims.

The essential idea of the invention is to date with

To supplement measured status information transmitted by another additional status information, which is a measure of the quality of data transmission between field devices and control units. If there is a delay in the transmission of a data packet, the second status information is classified accordingly. Due to the transmitted with the measured value two status information is now a safe process control possible.

There are two alternative ways of supplementing

Status information conceivable. Thus, the second status information may be included separately in the data packet, or the first and second status information may be combined into a single overall status information. A measured value classified as "good" can be reclassified in the second alternative due to delays in "uncertain".

Essential for the quality of data transmission in a non-deterministic network is the transmission time of the data packet. The more delays in data transmission, the worse the quality of data transmission. Frequently, a gateway component is provided between a deterministic network (fieldbus) and a non-deterministic network, in which a corresponding adaptation of the physics of the data transmission (physical layer), as well as the protocol adaptation are made. Advantageously, the quality of the data transmission in this gateway component is determined.

In non-deterministic networks may be, for example, a wireless network, but also to a wired network with appropriate timing.

The invention is explained in more detail with reference to an embodiment shown in the drawing.

[0014] In the drawings:

Fig. 1 shows a conventional field bus application in a schematic representation,

FIG. 2 shows a fieldbus application with a radio network, FIG.

Fig. 3 Fieldbus application with a wired but non-deterministic network, e.g. TCP / l P-based,

Fig. 4 field device in a schematic representation, and

Fig. 5 flowchart of the method according to the invention.

In Fig. 1, a typical fieldbus application with a wired deterministic network DN is shown. Four field devices F1, F2, F3 and F4 communicate via a field bus FB with a control unit SE. The Control unit SE is responsible for process control. With the control unit SE also a computer unit RE is connected, which serves for example for visualization of the automation application. On the basis of the current measured values, the control unit SE determines corresponding control signals for the field devices operating as actuators. Due to the wired data transmission and the use of suitable protocols between the field devices and the control unit SE occur here no undefined delays. The fieldbus FB may be, for example, a Profibus PA.

In Fig. 2 is a process automation application with a

Radio network FN shown as non-deterministic network NDN 1. The radio network FN comprises a plurality of field devices F1 to F4 and a gateway component G1. The gateway component G1 is connected via a conventional field bus FB to a control unit SE. The control unit SE corresponds to the control unit SE of FIG. 1 and forms with the field bus FB and the gateway component G1 a deterministic network DN.

The radio network FN may be a network in

MESH technology act. The data transmission paths between the field devices and the gateway component G1 are not fixed. The field device F1 can, for example, communicate directly with the gateway component G1 or, in the extreme case, via the field device F2, F3 and F4. Depending on whether in the data transfer "detours" must be taken into account, the data transmission can be delayed accordingly.

In Fig. 3 is a process automation application with a

TCP / l P-based network TN shown as non-deterministic network NDN2. Again, four field devices F1 to F4 are connected to a gateway component G2 via the network TN. In Fig. 3, the gateway component G2 is also connected to the control unit SE via the fieldbus FB. Together they form the deterministic network DN. The TCP / IP-based network TN is a non-deterministic network because in data transmission Collisions may occur or detours become necessary, or multiple retries (retries) are necessary.

In Fig. 4 is a field device, for example, the field device F1, shown schematically. It has a sensor MA, which serves to detect a process variable. The analog measurement signal delivered by the sensor MA is digitized in an analog-to-digital converter A / D and forwarded to a microcontroller μC. In the microcontroller μC, the measurement signal is processed and converted into a measured value. Via a correspondingly formed communication unit KE, which is likewise connected to the microcontroller .mu.C, the field device F1 can communicate either via the fieldbus FB or via one of the two networks FN or TN. For communication via the fieldbus FB, a fieldbus interface is required, for communication via a radio network a corresponding radio interface or via a TCP / IP P-based network, e.g. an ethernet interface. The method according to the invention is explained in more detail below.

With the aid of the sensor MA, the measurement signal, which depends for example on the pressure, the temperature, the level or the flow, detected and digitized in the analog-to-digital converter A / D. The measuring signal is evaluated in the microcontroller μC and converted into a measured value MW. At the same time, status information, which depends, for example, on the quality of the measurement signal and / or on the operating conditions of the field device, is also generated in the microcontroller .mu.C. For example, if the sensor MA is a radar unit of a level gauge, the quality of the radar echo may be different. Depending on the quality of the radar echo, status information is given. With an optimum radar echo signal, the status ST1 "good" is assigned, with a bad radar echo signal the status ST1 "uncertain" is defined. If the level can not be determined from the radar sounding valley at all or only with a high degree of uncertainty, the status ST1 "bad" is assigned Transfer the communication unit KE to the respective network. The recipient of the data packet is the control unit SE.

For non-deterministic networks, it can become undefined

Delays in data transmission come from data packets. Depending on the quality of the radio connection, it may be necessary to transmit the data packet several times between two components of the network in the same way or via alternative routes. According to the invention, the first status information of the data packet is supplemented by second status information, which depends on the quality of the data transmission of the data packet in the network. This supplement can be done, for example, by a separate additional status information ST2 in the data packet.

If no delays occur, this second status information ST2 is set to undelayed, however, if delays have occurred, it is set to delayed.

In an alternative embodiment of the invention, the first

Status information ST1 combined with the second status information ST2 to a common status information. Thus, a measured value classified as ST1 "good" can be reclassified "uncertain" in a data packet due to delays in data transmission in ST1.

A measure of the quality of the data transmission of a data packet can be, for example, the transmission time of the data packet between two network components.

In the network according to FIG. 2, this would be for a data packet originating from the field device F1, the field device F1 and the gateway G1.

Since all field devices must communicate with the second network via the gateway G1, the gateway G1 is particularly suitable for determining the quality of the data transmission. Also, the gateway has sufficient computing capacity for such a determination. In general, this determination can be made only in those network components that have information about the target time for certain data transmission links.

In particular, at the interface between two networks, it can Delays in forwarding readings come. Also for this reason, the gateway G1 or G2 is particularly suitable for the quality determination. Since the invention is suitable for any non-deterministic networks, it can be used in both radio networks and wired networks such as TCP / IP based networks. Even with wired networks, there may be unpredictable delays in the transmission of data packets with readings.

Claims

claims

1. A method for providing reliable status information for measured values in process automation applications with the following method steps: a) acquiring a measuring signal with the aid of a field device F1, b) determining a measured value from the measuring signal with the aid of the field device F1, c) determining a first status information ST1, d) transfer of the measured value with the first status information ST1 in a data packet from the field device F1 to a network TN, FN of the process automation technology, e) determination of a second status information, the Measure for the quality of the data transmission of the data packet in the network TN, FN is, f) supplement the data packet with the second status information ST2.

2. The method according to claim 1, characterized in that the supplement takes place by recording the second status information ST2 in the data packet.

3. The method according to claim 1, characterized in that the supplementing takes place by the combination of the first and second status information ST1, ST2 to a status information in the data packet.

4. The method according to any one of the preceding claims, characterized in that the quality of the data transmission of the data packet from the transmission time of the data packet between two participants of the network TN, FN depends.

5. The method according to any one of the preceding claims, characterized in that the quality of the data transmission in a gateway component G1, G2, which is arranged between the first network TN, FN and a second network KN, is determined.

6. The method according to claim 5, characterized in that the first Network is a nondeterministic and the second network is a deterministic network.

A method according to claim 6, characterized in that the nondeterministic network is a radio network.

Method according to claim 6, characterized in that the nondeterministic network is wired, e.g. a TCP / IP based network.