EP4260015A1 - Method for detecting erroneous measurement signal outputs from a field device, detection system and field device - Google Patents

Abstract

The invention relates to a method for detecting erroneous measurement signal outputs from a field device (1), comprising the steps of: outputting a measured value by way of the field device (1) as a first measurement signal, outputting the measured value by way of the field device (1) as a second measurement signal, receiving the first measurement signal and the second measurement signal or values derived therefrom by way of a detection system (3), ascertaining a measurement signal difference between the first measurement signal and the second measurement signal by way of the detection system (3) and checking, by way of the detection system (3), whether there is an error situation in light of the measurement signal difference and optionally in light of at least one further error condition. The invention additionally relates to a detection system (3) that can be used to carry out the method described above. According to a further aspect of the invention, a field device (1) is proposed that is suitable for carrying out the method described above.

Description

Method for detecting erroneous measurement signal outputs from a field device, detection system and field device

The invention relates to a method for detecting erroneous measurement signal outputs from a field device. The invention also relates to a detection system for detecting erroneous measurement signal outputs from a field device. The invention also relates to a field device.

Various technical devices that are directly related to a production process are subsumed under the term field device. "Field" refers to the area outside of control rooms. Field devices can therefore be actuators, sensors and measuring transducers in particular.

In process automation technology, field devices are often used that are used to record and/or influence process variables. Examples of such field devices are filling level measuring devices, limit level measuring devices and pressure measuring devices with sensors that record the corresponding process variables filling level, limit level or pressure. Typical application scenarios for such field devices include areas such as flood forecasting, inventory management or other distributed measuring tasks. Known field devices of the aforementioned type make it possible to transmit measured values, so that a higher-level unit triggers a predetermined action based on the measured value determined. For example, based on the measured value of a fill level measuring device, an inlet can be closed or an outlet can be opened if a limit value is exceeded.

Field devices are to be placed directly at the measuring point. Your energy supply is usually wired. For example, a measured value can be transmitted as an analog current signal between 4 mA and 20 mA. This type of signal transmission is standardized in DIN IEC 60381-1 (analog signals for regulation and control systems; analog direct current signals). Nevertheless, measured values can also be transmitted as voltage signals. A remote station can receive the analog voltage signals and determine measured values from them.

The wired analogue transmission of measured values is very simple and has other advantages. For example, a two-wire system A field device can be supplied with energy, but the two-wire system can also be used to transmit measured values at the same time. However, if an error occurs during the transmission of the measured values, this can have serious consequences. Many faults cannot be detected remotely due to the analogue connection of the field device. This applies in particular to deviations in measured values.

The publication EP 1 864 268 B1 describes an interface of a field device to a two-wire system. The interface regulates an output current. The interface is equipped with a checking circuit to detect output errors. The checking circuit measures a current strength in the two-wire system and can thus determine whether the two-wire system is supplied with a desired current strength. If this is not the case, a calibration process can be triggered. In this way, errors can be detected and corrected directly in the field device. However, the field device has a more complex structure due to the necessary checking circuit. It is not possible to check the field device remotely.

The invention is therefore based on the object of specifying a method that allows faulty measurement signal outputs from a field device to be detected remotely. It is a further object of the invention to provide a detection system that enables faulty measurement signal outputs from a field device to be detected remotely. A further object of the invention is to specify a field device whose measurement signal outputs can be checked remotely. The objects are achieved by a method for detecting erroneous measurement signal outputs from a field device according to claim 1, by a detection system according to claim 20 and by a field device according to claim 21.

The subclaims relate to various advantageous developments of the present invention that are independent of one another, the features of which can be freely combined with one another by a person skilled in the art within the scope of what is technically reasonable. This applies in particular beyond the limits of the various claim categories. According to a first aspect of the invention, a method for detecting erroneous measurement signal outputs from a field device is proposed, comprising the steps: outputting a measured value by the field device as a first measurement signal, outputting the measured value by the field device as a second measurement signal, receiving the first measurement signal and the second measurement signal or values derived from it by a detection system, determination of a measurement signal deviation between the first measurement signal and the second measurement signal by the detection system and checking by the detection system whether an error is present, taking into account the measurement signal deviation and optionally taking into account at least one other error condition.

This has the advantage that external error detection is possible. No expensive components need to be installed in the field device itself to read back the first measurement signal. In principle, a large number of field devices can be monitored by means of the detection system. The functional safety of the field device is increased: faulty operating states, for example caused by damage or manipulation of the field device, can be detected.

The first measurement signal and the second measurement signal preferably reflect a measured value determined by a sensor or sensors of the field device. The detection system can receive the first and the second measurement signal directly. However, it is also possible for the detection system to only receive values that are derived from the first measurement signal and/or the second measurement signal. This is the case, for example, when an intermediary receives the first measurement signal, subjects the first measurement signal to analog-to-digital conversion and then forwards the measurement signal, which has thus been digitized, to the detection system in the form of a measurement data packet.

According to the invention, the first and the second measurement signal can be output by means of different communication interfaces of the field device. Alternatively, however, it is also possible for the first measurement signal and the second measurement signal to be output via the same communication interface of the field device. It is essential that due to the double output of the measured value, it can be checked whether it was transmitted correctly. It is advantageous if the first measurement signal is output via a wired interface of the field device and the second measurement signal is output via a radio interface of the field device. Redundancy is thus established by means of radio transmission. For example, Bluetooth, LoRaWAN (Long Range Wide Area Network), NB-IoT (NarrowBand-IoT), LTE-M (Long Term Evolution) or any other radio transmission technology can be used as radio transmission technology. Alternatively, the first measurement signal can be output via a wired interface of the field device and the second measurement signal can also be output via a wired interface of the field device. Redundancy is consequently ensured by means of transmission via two different data cables.

According to an advantageous embodiment of the invention, the first measurement signal is an analog measurement signal and the second measurement signal is a digital measurement signal. According to one variant of the invention, the first measurement signal can be output in an analog, wired manner, and the second measurement signal can be transmitted digitally by radio. According to another variant of the invention, both the first measurement signal and the second measurement signal are transmitted by cable, for example via two separate data cables. In this case, the second measurement signal could be transmitted using a standard such as Ethernet, Profibus or IO-Link, for example. According to a further embodiment of the invention, the first measurement signal and the second measurement signal are transmitted via the same data cable, the first measurement signal being an analog measurement signal and the second measurement signal being a digital measurement signal. According to the invention, this could be implemented by modulating the second measurement signal in digital form onto the first measurement signal in analog form. This is possible, for example, using the fieldbus protocol HART (Highway Addressable Remote Transducer).

When the measurement signal deviation between the analog measurement signal and the digital measurement signal is determined by the detection system, it is preferably checked whether the analog measurement signal and the digital measurement signal correspond to one another. If they don't do this, then this is usually due to the fact that either the analog measurement signal or the digital measurement signal is corrupted. Due to the robustness of the digital signal transmission and the methods for error detection and correction that can be used, it can be assumed that in the event of a deviation between the analog measurement signal and the digital measurement signal in in the majority of cases there is a falsification of the analog measurement signals. The falsification can be based, for example, on a hardware error in the field device, but can also be caused by damage to or a fault in a wired communication link. It goes without saying that in order to determine the measurement signal deviation, the field device does not necessarily have to process the analog measurement signal and the digital measurement signal directly, but can also work with values derived therefrom. When the detection system checks whether an error is present, various criteria can be applied. In particular, not only does a result of the determination of the measurement signal deviation have to be evaluated, but other parameters and/or system states can also be evaluated.

It is preferred if, in order to determine the measurement signal deviation, the analog measurement signal and the digital measurement signal are normalized to a matching unit, so that normalized values result, and a difference is then formed between the normalized values. Standardization is a step that makes the analog measurement signals comparable with the digital measurement signals. For the purpose of standardization, the analog measurement signal and/or the digital measurement signal can be converted into a different unit.

It is advantageous if the determination of the measurement signal deviation includes the following steps: provision of an analogue target measurement value by converting the digital measurement signal into an analogue unit, provision of an analogue actual measurement value based on the analogue measurement signal and calculation of a difference between the analogue target value and the analog actual value. The analog target value is based on the digital measurement signal and indicates, for example, an expected current or an expected voltage. In order to be able to compare the analog target value with the analog measurement signal, the analog actual value must be provided. For this purpose, according to the invention, the detection system can convert the analog measurement signal into a digital format by analog-to-digital conversion. The detection system may already have the analog actual value in digital form because a detection unit arranged between the field device and the detection system recorded the analog measurement signal, converted it accordingly and forwarded it to the detection system in the form of a measurement data package. Now it can be checked whether the analog target value corresponds to the analog Actual value corresponds. To do this, the difference between the analog target value and the analog actual value is formed. According to an advantageous embodiment of the invention, the analog measurement signal can be a current intensity. In this case, it is consequently checked whether a current strength of the analog measurement signal corresponds to a current strength expected on the basis of the digital measurement signal.

However, the previously described comparison of the analog measurement signal with the digital measurement signal can alternatively also be implemented in a different way. According to one possible embodiment of the invention, the analog measurement signal and the digital measurement signal are converted into a measurement value, for example into a pressure measured by the field device. This results in two pressure values. The pressure values can then be compared with one another. However, according to the invention, the analog measurement signal can also be compared with the digital measurement signal by means of other calculation methods.

The method preferably includes the output of a configuration data set of the field device by the field device and the receipt of the configuration data set by the detection system. The configuration data record preferably contains configuration data of the field device. In particular, the configuration data record can contain configuration data that characterize the relationship between the measured value measured by the field device and the analog measurement signal. For this purpose, according to the invention, the configuration data record can contain at least one conversion factor and/or one offset value. For example, the field device could be configured to output a current of 4 mA as the analog measurement signal when measuring a pressure of 1 bar and a current of 20 mA when the pressure is 2 bar. The configuration data record contains information that allows a remote station to calculate, based on a measured current of e.g. 12 mA, that the field device has measured a pressure of 1.5 bar.

It is advantageous if the detection system uses the configuration data set when determining the measurement signal deviation in order to normalize the analog measurement signal and the digital measurement signal to the matching unit. Only by standardizing the measurement signals can they be compared with one another. However, variants of the invention are also possible in which configuration data characterize the ratio of the measured by the field device Measured value related to the analogue measurement signal can be entered manually into the detection system.

According to a particular embodiment of the method according to the invention, a detection unit records the analog measurement signal, the detection unit performing analog-to-digital conversion of the analog measurement signal into a measurement data packet and the detection unit transmitting the measurement data packet to the detection system. The detection unit is preferably a device for controlling the field device and/or for evaluating the measured values recorded by the field device. The detection unit is often arranged spatially close to the field device and can also be used to supply it with energy. The acquisition unit can acquire the analog measurement signal and forward it to the detection system, for example in the form of a measurement data packet that contains the analog measurement signal in digitized form. The detection unit can have a radio interface, for example, in order to be able to communicate with the detection system. According to other embodiments, however, communication with the detection system is also possible in a different way, for example via a communication network such as the Internet. Furthermore, embodiments of the invention are possible in which the detection unit and the detection system are combined with one another. For example, the detection system can be integrated into the detection unit.

According to the invention, it is possible for the acquisition unit to provide the measurement data packet with a time stamp. The time stamp preferably identifies a point in time at which the detection unit received the analog measurement signal. This allows the detection system to check whether the analog measurement signal and the digital measurement signal have been output by the detection system in close proximity to one another.

According to advantageous variants of the method proposed according to the invention, it can be provided that the first measurement signal and the second measurement signal are output by the field device at a time interval from one another. The measurement signals compared with one another were therefore output at different times, for example on different days, but shorter or longer time intervals are also possible. This is permissible in particular when the measured values recorded by the field device do not change very quickly. Change However, if the measured values detected by the field device change relatively quickly, then the first measurement signal and the second measurement signal must have been output by the field device in a sufficiently short period of time. According to the invention, a size of a time window can be specified, from which the first and the second measurement signal may originate, so that they can be compared with one another according to the method according to the invention. If a comparatively large time window is set, then the second measurement signal only needs to be transmitted comparatively seldom via the radio interface. Less energy is therefore required to send the second measurement signals.

In order to be able to check that the measurement signals are not too far apart in time, the field device preferably provides the second measurement signal with a time stamp. This can be implemented in particular when the second measurement signal is a digital measurement signal. According to the invention, it is also possible for the detection system to log times at which the first measurement signal, the second measurement signal or values derived from these arrive at the detection system. Corresponding time intervals can be determined from this.

It is preferred if, when checking whether an error is present, the detection system determines whether a threshold value predefined for the measurement signal deviation is exceeded. If, based on the second measurement signal, it is to be expected, for example, that the field device will output a current of 6 mA as the first measurement signal, and a threshold value of 1 mA is provided, then first measurement signals of 5.1 mA or 6 .5 mA is permissible, but a measuring signal of 7.5 mA is not. Slight deviations in the first measurement signal that do not falsify the measured value too much can thus be ignored.

It is particularly preferred if the detection system takes into account several pairs of first and second measurement signals when checking whether the error is present, the pairs of first and second measurement signals being output by the field device at different times. Consequently, several measurement signal comparisons are carried out, according to advantageous embodiments also over a longer period of time. Results of the measurement signal comparisons can be averaged, for example. Thus, a temporary Disturbance or a short-term deviation of the measurement signals are not necessarily classified as an error.

It is advantageous if, when checking whether the error is present, the detection system measures a period of time since receipt of a last second measurement signal or a value derived therefrom and establishes the error if the measured period of time exceeds a predefined maximum period of time. It is thus checked that second measurement signals or values derived therefrom are not received by the detection system at too great a time interval. If this is not the case, faulty measurement signal outputs from the field device can no longer be identified. According to this embodiment of the invention, this is classified as an error case.

The first measurement signal is preferably a current signal. A current intensity is thus output which represents a measured value measured by the field device. Alternatively, the first measurement signal can be a voltage signal or a signal of some other type.

It is preferred if the field device outputs the first measurement signal via a two-wire system. The two-wire system preferably has a forward conductor and a return conductor. The two-wire system is suitable for powering the field device. Data is also transmitted in analog form via the two-wire system, in this case the first measurement signal. Thus, a simple and compact implementation of both the power supply and device communication is given. This is very advantageous when recording measured values, especially in places that are difficult to access.

The transmission of data via the radio interface of the field device is preferably encrypted. Data transmitted via the radio interface are preferably checked for errors by the detection system by comparing a checksum such as a CRC code or the like. The transmission via the radio interface preferably takes place at regular time intervals. According to the invention, it is also possible for the configuration data set mentioned above to be transmitted to the detection system by means of the radio interface. The second measurement signal is either received directly by the detection system or it reaches it indirectly, possibly by forwarding it via various nodes. In principle, the detection system can be a computer or a network of several computers, in which case the computer or the network of computers can be equipped with communication interfaces of various types. The detection system can be implemented in particular by a cloud system in which software for monitoring field devices runs.

The detection system preferably emits an error signal when the error is detected. The error signal is to be understood as a signal that is used to notify a remote station that the field device may no longer be functional, that communication with the field device may no longer be working, or that some other type of error has occurred. For example, it is possible for the detection system to inform a responsible person about the error by e-mail, by SMS, by means of a push message in an app or in some other way. The person responsible can then take suitable measures to avoid or minimize consequential damage caused by the suspected defective field device.

It is advantageous if the detection system, if there is an error, transmits a command to the field device to put the field device into a safe state. In the case of a field device that outputs the measured values as analog current signals, only values smaller than 3.6 mA or larger than 21 mA are then output, for example, which are not valid measured signals. It is also conceivable to shut down the field device using an external command. According to the invention, it is also possible for the detection system, if there is an error, to transmit a command to the field device to restart the field device. According to the invention, it is also possible for the person responsible to send a command to the field device to set the field device to a safe state, to shut down the field device or to restart the field device.

According to a further aspect of the invention, a detection system for detecting erroneous measurement signal outputs from a field device is proposed, which is set up to carry out the following steps: receiving a first measurement signal, receiving a second measurement signal, determining a measurement signal deviation between the first measurement signal and the second measurement signal and Checking whether there is an error, taking into account the measurement signal deviation and optionally taking into account at least one other error condition. The detection system preferably has a radio interface and is set up to receive the second measurement signals via the radio interface. It is also advantageous if the detection system has a wired interface and is set up to receive the first measurement signals via the wired interface. The radio interface preferably forms part of the detection system. The detection system is preferably implemented by a system of distributed, networked computers. The detection system is preferably suitable for carrying out the method described above and has the necessary features for this.

According to a further aspect of the invention, a field device is proposed which has at least one sensor unit for acquiring a measured value, the field device being set up to output the measured value as a first measurement signal and as a second measurement signal. It is preferred if the field device has a wired interface and a radio interface, the field device being set up to output the first measurement signal via the wired interface and the second measurement signal via the radio interface. Regardless of the type of interface used, the first measurement signal is preferably an analog measurement signal and the second measurement signal is a digital measurement signal. The field device is preferably a filling level measuring device, a limit level measuring device or a pressure measuring device. For example, the sensor unit can be a capacitive pressure measuring cell, but depending on the area of application it can also be a sensor unit of another type. The field device is preferably suitable for carrying out the method described above and has the necessary features for this.

It is advantageous if the field device cannot receive any data via the radio interface or cannot process data received via the radio interface as commands. This prevents the field device from being manipulated by external commands. According to an alternative embodiment of the invention, the radio interface allows data to be received. A field device according to this embodiment is preferably set up in such a way that it can be switched to a safe operating state and/or switched off by means of an external command. Aspects of the invention are explained by way of example with reference to the figures. It shows:

1 shows a schematic representation of a computer topology with a field device, with a detection unit and with a detection system,

2 shows a flow chart of the method according to the invention for the detection of erroneous measurement signal outputs and

3 shows a flow chart that explains the partial steps of the method according to the invention in more detail.

1 shows a schematic representation of a computer topology with a field device 1, with a detection unit 2 and with a detection system 3. The field device 1 has a sensor unit 4, which is a capacitive pressure measuring cell. By means of this, for example, a pressure of a surrounding fluid can be measured. The field device 1 has a wired interface 5 for outputting a measured value. The wired interface 5 allows current signals to be output via a two-wire system 6 . The two-wire system 6 is also used to supply energy to the field device 1 . The field device 1 is connected to the detection unit 2 via the two-wire system 6 . The detection unit 2 supplies the field device 1 with power via the two-wire system 6 . The detection unit 2 reads in first measurement signals, which the field device 1 outputs via the two-wire system 6 . The first measurement signals are analog measurement signals. The detection unit converts the analog measurement signals into a digital form and sends them as measurement data packets to the detection system 3 via a communication network 7. The field device 1 also has a radio interface 8, which outputs second measurement signals. The radio interface 8 sends the second measurement signals as radio signals 9, which reflect the measured value in digital form. The second measurement signals are therefore digital measurement signals. The radio signals 9 are received by a further radio interface 8 which is associated with the detection system 3 . The detection system 3 is a cloud computer network that runs a computer program for monitoring field devices 1 . FIG. 2 shows a flow chart of the method according to the invention for detecting erroneous measurement signal outputs. In a measurement step 10, the field device described above measures a pressure. The pressure is output in an output step 11 via the wired interface of the field device and via the radio interface of the field device as the first or the second measurement signal. The field device outputs the measured value as a current strength via the two-wire system and also sends the measured value in digital form via its radio transmitter. In a receiving step 12, the detection system receives a measurement data packet derived from the first measurement signal and the second measurement signal. The receiving step 12 is preceded by the fact that the detection unit measures the current strength of the first measurement signal, converts it into a digital format, generates the measurement data packet from it and transmits the measurement data packet to the detection system.

In a determination step 13, a measurement signal deviation between the first measurement signal and the second measurement signal is determined. If the first measurement signal does not match the second measurement signal, then there may be an error. The error can be caused by a field device error or by a communication error. In a test step 14, the detection system checks whether an error is present. This is the case, for example, when the measurement signal deviation exceeds a predefined value. However, the detection system also checks whether it regularly receives second measurement signals. If this is no longer the case, then this indicates an error in the field device. In the event of an error, the test step is followed by an information step 15. In the information step, the person responsible is informed by the detection system by means of an e-mail or by means of a push message in an app that the field device is no longer working properly. If there is no error, then in a protocol step 16 the detection system only stores the determined measurement signal deviation.

FIG. 3 shows a flow chart that explains the partial steps of the method according to the invention in more detail. The sub-steps are performed in the determination step described above. In a configuration step 17, the field device transmits a configuration data record of the field device to the detection system via its radio interface. The configuration data set contains information that allows the first measurement signal to be calculated from the second measurement signal. In a normalization step 18, the detection system normalizes the first Measurement signal and the second measurement signal on a matching unit. In the present case, the matching unit is the unit of the first measurement signal, here a current strength in mA. The measurement data packet derived from the first measurement signal and available to the detection system already specifies the current in mA. Thus, only the second measurement signal has to be converted into the unit mA. This is done with the help of the configuration data set. Finally, in a difference step 19, the difference between the normalized measurement signals is formed. A large difference indicates that the analog measurement signal does not correctly reflect the actual measurement value.

Reference List

field device

registration unit

Detection system Sensor unit Wired interface Two-wire system

Communication network radio interface

radio signal

measuring step

Output step Reception step Determination step Verification step

information step

log step

Configuration step Normalization step Difference step

Claims

Method for detecting erroneous measurement signal outputs from a field device (1), comprising the steps:

- output of a measured value by the field device (1) as a first measurement signal,

- output of the measured value by the field device (1) as a second measurement signal,

- Reception of the first measurement signal and the second measurement signal or values derived therefrom by a detection system (3),

- Determination of a measurement signal deviation between the first measurement signal and the second measurement signal by the detection system (3) and

- Checking by the detection system (3) whether an error is present, taking into account the measurement signal deviation and optionally taking into account at least one other error condition. Method according to Claim 1, characterized in that the first measurement signal is output via a wired interface (5) of the field device (1) and the second measurement signal is output via a radio interface (8) of the field device (1). Method according to claim 1 or 2, characterized in that the first measurement signal is an analog measurement signal and that the second measurement signal is a digital measurement signal. Method according to Claim 3, characterized in that to determine the measurement signal deviation, the analog measurement signal and the digital measurement signal are normalized to a matching unit, so that normalized values result, and a difference between the normalized values is then formed. Method according to Claim 3, characterized in that the determination of the measurement signal deviation comprises the following steps:

- Provision of an analogue target measured value by converting the digital measurement signal into an analogue unit,

- Provision of an analog actual measured value based on the analog measurement signal and

- Calculation of a difference between the target analog measured value and the actual analog measured value. Method according to Claim 4, characterized in that the method also comprises the steps of:

- Output of a configuration data record of the field device (1) by the field device (1) and

- Reception of the configuration data set by the detection system (3). Method according to Claim 6, characterized in that the detection system (3) uses the configuration data set when determining the measurement signal deviation in order to normalize the analog measurement signal and the digital measurement signal to the matching unit. Method according to one of Claims 3 to 7, characterized in that a detection unit (2) records the analog measurement signal, the detection unit (2) carrying out analog-to-digital conversion of the analog measurement signal into a measurement data packet and the detection unit (2) Measurement data package transmitted to the detection system (3). Method according to Claim 8, characterized in that the acquisition unit (2) provides the measurement data packet with a time stamp. 18 experienced according to any one of the preceding claims, characterized in that the first measurement signal and the second measurement signal spaced apart in time are output by the field device (1). experienced according to one of the preceding claims, characterized in that the field device (1) provides the second measurement signal with a time stamp. Method according to one of the preceding claims, characterized in that when checking whether an error is present, the detection system (3) determines whether a threshold value predefined for the measurement signal deviation is exceeded. Method according to one of the preceding claims, characterized in that when checking whether the error is present, the detection system (3) takes into account a plurality of pairs of first and second measurement signals, the pairs of the first and second measurement signals being spaced apart in time by the field device (3) have been issued. Method according to one of the preceding claims, characterized in that when checking whether the error is present, the detection system (3) measures a period of time since receipt of a last second measurement signal or a value derived therefrom and determines the error case if the measured period of time exceeds the predefined maximum period of time. Method according to one of the preceding claims, characterized in that the first measurement signal is a current signal. Method according to one of the preceding claims, characterized in that 19 the field device (1) outputs the first measurement signal via a two-wire system (6). experience according to one of the preceding claims, characterized in that the detection system (3) emits an error signal when the error is detected. learn according to one of the preceding claims, characterized in that the detection system (3), if there is an error, transmits a command for moving the field device (1) to a safe state to the field device (1). Method according to one of Claims 1 to 17, characterized in that the detection system (3), if there is an error, transmits a command to restart the field device (1) to the field device (1). Detection system (3) for detecting erroneous measurement signal outputs from a field device (1), the detection system (3) being set up to carry out at least the following steps:

- receipt of a first measurement signal,

- receipt of a second measurement signal,

- Determination of a measurement signal deviation between the first measurement signal and the second measurement signal and

- Checking whether an error is present, taking into account the measurement signal deviation and optionally taking into account at least one other error condition. Field device (1) with at least one sensor unit (4) for detecting a measured value, the field device (1) being set up to output the measured value as a first measurement signal and as a second measurement signal. Field device (1) according to claim 21, characterized in that 20 the field device (1) has a wired interface (5) and a radio interface (8), the field device (1) being set up to transmit the first measurement signal via the wired interface (5) and the second measurement signal via the radio interface (8) to spend Field device (1) according to Claim 22, characterized in that the field device (1) cannot receive any data via the radio interface (8) or cannot process data received via the radio interface (8) as commands.