EP3853703A1 - Method for measuring a physical measurement variable, and measuring system for carrying out the method - Google Patents

Abstract

The invention relates to a method (V) for measuring a physical measurement variable (M) using method parameters of a measuring system (S), said parameters comprising multiple measuring units (1) which are required for measuring the physical measurement variable (M). The method parameters have the steps at least detecting (2) the physical measurement variable (M) as a measurement signal, at least analyzing (3) the measurement signal in order to form a measurement value, at least displaying (4) the measurement signal or measurement value, and at least further processing (5) the measurement signal or measurement value; comprising a computer program product (C) for setting and monitoring method parameters; wherein each method parameter is reproduced on a graphical user surface (GUI) in a window assigned to the method parameter. Each window can be folded in, a folded-in window (1x1 to 5x5) using precisely the space on the graphical user surface (GUI) to reproduce the assigned method parameter in short form, and each window can be folded out, a folded-out window (111 to 135, 411 to 425) using precisely the space on the graphical user surface (GUI) to reproduce the assigned method parameter in long form.

Description

 Method for measuring a physical quantity and measuring system for carrying out the method

Technical field

 The invention relates to a method for measuring a physical measured variable and a measuring system for carrying out the method according to the preambles of the independent claims.

State of the art

A physical measurement quantity is measured with a measurement unit. The physical measurand can be a force, a pressure, a mass, a temperature, etc. In general, several process steps that are separate from one another in terms of time and space are necessary for this. For example, a pressure is measured in a measuring room. For this purpose, a piezoelectric pressure sensor arranged in the measuring room detects the pressure and generates an electrical charge quantity proportional to the detected pressure. The amount of electrical charge is transmitted via a signal cable as a measurement signal to an evaluation unit that is spatially distant from the measurement room. There, the measurement signal is evaluated for a measurement value. Such a measuring unit thus has several transmission elements such as sensor, measuring cable and evaluation unit, which transmission elements form a measuring chain. Directly adjacent transmission links in the measuring chain have a cause-effect relationship with each other when measuring the physical measurand. Often, several measuring units together form a measuring system. For example, a cylinder pressure of eighteen cylinders of a ship's engine is permanently measured over a period of several weeks as the physical measured variable. The cylinder pressure is several 100 bar, a cylinder temperature is several 100 ° C. In this example, the measuring system has eighteen measuring units. Each measuring unit has a piezoelectric pressure sensor and a thermocouple for a cylinder, which detect the cylinder pressure and the cylinder temperature. A measuring frequency is 10 kHz. Each measuring unit has a measuring cable in order to transmit measuring signals to an evaluation unit. The evaluation unit in turn has 36 measuring channels for cylinder-specific reading of the measuring signals. The evaluation unit electrically amplifies the measurement signals and displays electrically amplified measurement signals as measured values and stores the measured values.

The measuring system thus has many process parameters such as the measuring units, the acquisition of the physical measurement variable, the evaluation of the measurement signal for a measurement value, etc. Most process parameters of the measurement system must be set and all process parameters of the measurement system must be monitored. So who has to set which piezoelectric pressure sensor and which thermocouple are arranged on which cylinder, or which measuring cable is connected to which measuring channel of the evaluation unit, etc. It is also monitored whether the measured cylinder pressure and the measured cylinder temperature are specific to the ship's engine Comply with limit values and an alarm is given if there is a deviation. Measurements must also be started and stopped, and process parameters changed, for example if a measuring cable is defective and needs to be replaced. For this purpose, the measuring system has a computer program product for setting and monitoring process parameters. The computer program product can be operated via a graphical user interface (GUI). A user of the measuring system can operate and monitor the measuring system via the graphical user interface and start and stop measurements. The graphical user interface has windows. Information about the measuring system is output in the windows. Control signals for setting and monitoring process parameters and for starting and stopping measurements can also be entered in the windows.

Due to the large variety and the large number of process parameters, the computer program product also has a large number of windows. This large number of windows is often hierarchically nested, which makes it difficult to understand and understand the graphical user interface. For example, information about a number of the measurement channels for reading the measurement signals is output in a fourth uppermost window of a window stack. The fourth uppermost window is hidden behind three of the windows of the window stack. The fourth uppermost window is only visible in the graphical user interface after successively opening the three windows above the window stack. Before outputting the information, three windows above the window stack must first be opened or moved. Such a graphical user interface is tedious to use. A first object of the present invention is to provide a method for measuring a physical measured variable, which method uses a computer program product for setting and monitoring process parameters, which computer program product is easy to use and is clear and understandable via a graphical user interface. The invention has the further object to provide a measuring system for performing the method.

Presentation of the invention

[0007] These tasks are solved by the features of the independent claims.

[0008] The invention relates to a method for measuring at least one physical measured variable; Using process parameters of a measuring system, which process parameters comprise several measurement units required for the measurement of the physical measurement variable, which process parameters include the process steps of at least one detection of the physical measurement variable as a measurement signal, of at least one evaluation of the measurement signal for one measurement value, of at least a representation of the measurement signal or measurement value and of at least one further processing of the measurement signal or measurement value; and with a computer program product for setting and monitoring the process parameters; wherein each process parameter is displayed in a window associated with it on a graphical user interface; each window can be collapsed, a collapsed window uses exactly the space on the graphical user Interface to give the assigned process parameter in short form; and wherein each window can be opened, an opened window uses exactly the space on the graphical user interface in order to reproduce the associated process parameter in long form.

By deliberately folding and unfolding windows assigned to the process parameters on the graphical user interface, space is gained in order to display information in a clearly and understandably manner. For example, all process parameters are shown in the windows assigned to them. When the windows are folded in, the process parameters are shown in short form; when the windows are open, the process parameters are shown in long form. Depending on the desired information content, a user can open and close windows from the measuring system.

The invention also relates to a measuring system for carrying out the method, the method parameters being divided into categories, a first category of method parameters comprises a plurality of measuring units required for measuring the physical measurement variable, a second category comprises at least one recording of the physical measurement size as a measurement signal, a third type includes at least one evaluation of the measurement signal for a measurement value, a fourth type includes at least one representation of the measurement signal or measurement value, and a fifth type includes at least one further processing of the measurement signal or measurement value; where each de genus has a unique index number; and wherein the computer program product on the graphical user interface in at least two columns shows the windows of process parameters that have the same index number.

Such a genus-specific reproduction of United process parameters is clear and understandable. Before preferably, it is possible in a simple manner by activating and deactivating a column to control the information content shown in the windows in a genre-specific manner. The windows are collapsed in a deactivated column and the process parameters are shown in short form, in an activated column the windows are expanded and the process parameters are displayed in long form. Depending on the desired information content, a user can activate and deactivate columns from the measuring system.

Brief description of the drawings

 In the following the invention is explained in more detail by way of example with reference to the figures. Show it

Fig. 1 is a block diagram with a process parameters

 Measuring system;

FIG. 2 shows a schematic view of an electronic computing unit for executing a computer program product for setting and monitoring process parameters of the measuring system according to FIG. 1;

3 shows a schematic view of a first exemplary embodiment of a graphical user interface of a computer program product for setting development and monitoring of process parameters of the measuring system according to FIG. 1;

FIG. 4 shows a schematic view of a still deactivated first column of the embodiment of a graphical user interface according to FIG. 3;

Fig. 5 is a schematic view of the activated first

 Column of the embodiment of a graphical user interface according to FIG. 4;

Fig. 6 shows a schematic view of a still deactivated one

 Window of the activated first column of the embodiment of a graphical user interface according to FIG. 5;

Fig. 7 is a schematic view of the activated window of the activated first column of the embodiment of a graphical user interface according to Fig. 6;

Fig. a schematic view of a still deactivated fourth column of the embodiment of a graphical user interface according to FIG. 7;

Fig. 9 is a schematic view of the activated fourth

 Column of the embodiment of a graphical user interface according to FIG. 8; and

10 is a schematic view of a second exemplary embodiment of a graphical user interface of a computer program product for setting and monitoring of process parameters of the measuring system according to FIG. 1.

Ways of Carrying Out the Invention

1 shows process parameters of a measuring system S. The measuring system S is used to measure at least one physical measurement variable M. The physical measurement quantity M can be a force, a pressure, a mass, a temperature, etc.

his. The process parameters are divided into several genera.

A first class of method parameters comprises at least one measuring unit 1 required for the measurement of the physical measurement quantity M. Each measuring unit 1 has several transmission elements such as at least one sensor, at least one measuring cable and at least one evaluation unit. A measuring unit 1 measures at least one physical measurement variable M, but it can also measure more than one physical measurement variable M. The measuring unit 1 and its transmission elements are also called the measurement setup.

A second, third, fourth and fifth type of method parameters comprises method steps of a method V. Thus, a second type of method parameters includes the method step of at least one acquisition 2 of a physical measurement quantity M as a measurement signal. A third class of method parameters comprises the method step of at least one evaluation 3 from the measurement signal to at least one measurement value. The evaluation 3 is also called data processing. A fourth genre of process parameters tern comprises the method step of at least one representation 4 of the measurement signal or measurement value. The representation 4 of the measurement signal or measurement value can take place in tabular form, in graphical form, etc. And a fifth class of process parameters comprises the method step of at least one further processing 5 of the measurement signal or measurement value. The further processing 5 of the measurement signal or measurement value can be used as a trigger signal for a follow-up process such as a good part / bad part determination in an injection molding process, a data transmission to a spatially distant memory location, a data transmission to a spatially distant data processor, etc.

Fig. 2 shows a schematic view of an electronic computing unit R for executing a computer program product C of the measuring system S. The electronic computing unit R has as components at least one data memory DS, at least one data processor DP, at least one data input unit DE, at least a data output unit DA and at least one data bus DB. Any data is exchanged between the components via the data bus DB.

Data input unit DE and data output unit DA can be separate components such as a keyboard, a computer mouse, a screen, a serial interface, etc., but they can also be integrated in a component such as a touch screen. The data output unit DA has at least one screen or touch screen with a graphical user interface GUI. Thus, at least one computer program product C stored as data in the data memory DS can be loaded as data via the data bus DB from the data memory DS into the data processor DP. The loaded computer program product C is executed by the data processor DP.

The computer program product C can enter data from at least one measurement signal and data from at least one measurement value via the data bus DB from a data input unit DE such as a serial interface. The computer program product C can therefore carry out the evaluation 3 from the measurement signal to a measurement value, it can also display 4 from the measurement signal and from the measurement value, and it can carry out further processing 5 from the measurement signal or measurement value. The evaluation 3 from the measurement signal to a measurement value, the representation 4 of the measurement signal and the measurement value and the further processing 5 of the measurement signal and the measurement value can also be carried out in a spatially separate evaluation unit.

The process parameters are stored as data in the data memory DS and can be called up from the data memory DS.

- The genera are indexed. Each genus preferably has a unique index number. The index number of the first class is I, the index number of the second class is II, the index number of the third class is III, the index number of the fourth class is IV and the index number of the fifth class is V. The index number is one Property of the process parameters and will with the data of the process parameters in the data memory DS ge stores and is retrievable from the data memory DS.

- The process parameters of a measuring unit 1 are linked to each other. Each measuring unit 1 preferably has a unique identification number, via which identification number the method parameters are linked to one another. The identification number of a first measurement unit is i, the identification number of a second measurement unit is ii, the identification number of a third measurement unit is iii, the identification number of a fourth measurement unit is iv, and the identification number of a fifth measurement unit is v, etc. For example the identification number is a property of the process parameters and is stored with the data of the process parameters in the data memory DS and can be called up from the data memory DS. The process parameters of a measuring unit 1 can be linked from left to right or from right to left. When the process parameters of a measuring unit 1 are linked from left to right, two or more process parameters are linked together in a causal and temporal sequence of the process steps acquisition 2, evaluation 3, display 4 and further processing 5. In contrast, when the process parameters of a measuring unit 1 are linked from right to left, two or more process parameters are linked to one another in a non-causal and non-temporal sequence of process steps, for example a representation 4 is linked to an evaluation 3 which was carried out earlier. The computer program product C can input data from process parameters of the measuring system S. The computer program product C can in the data memory DS as data stored process parameters via the data bus DB from the data memory DS in the data processor DP.

The computer program product C can set and monitor process parameters of the measuring system S. A setting of a process parameter means a change in state of the process parameter. For example, a measurement is started or ended by entering a control signal for the step 2 of the physical measurement quantity M. Monitoring of a process parameter means a representation 4 of the time course of the process parameter. For example, a measurement signal or a measurement value is shown in detail, in which a time course of the measurement signal or measurement value is shown graphically. The computer program product C can transmit data of a control signal via the data structure DB to the data output unit DA like a serial interface. From there, the data of the control signal are transmitted to a measuring unit 1, such as a sensor or an evaluation unit.

The computer program product C outputs information on the measurement system S on the graphical user interface GUI. For this purpose, the graphical user interface GUI has columns with windows. The computer program product C can transmit data of information to the graphical user interface GUI via the data bus DB and output it as information in the columns with windows. The computer program product C can be operated via the graphical user interface GUI. Operating the computer program product C means entering control signals. Control signals for setting and monitoring process parameters can be entered in the columns with windows. For example, the data input unit DE can be a computer mouse which moves a cursor U on the graphical user interface GUI. By moving the cursor U on the graphical user interface GUI, a column with windows or a window is selected. By activating a selected column with windows or a selected window over which the cursor is located, a control signal is entered. It can be activated by pressing a button on the computer mouse as soon as the cursor is over a selected column with windows or over a selected window. Data on the movement of the cursor and the activation of the column with windows or the window are transmitted from the data input unit DE via the data bus DB to the data output unit DA of the graphical user interface GUI and the computer program product C. The movement of the cursor and the activation of the selected column with windows or the selected window over which the cursor is located can, however, also be achieved by swiping the dog from the touch screen of a graphical user interface GUI and by pressing the touch screen of the GUI graphical user interface gen.

3 to 10 show two exemplary embodiments of a graphical user interface GUI of the computer program product C for setting and monitoring Process parameters of the measuring system S. The graphical user interface GUI has, for example, five columns 10 to 50, 10 ', 40' with windows. The measuring system S, for example with five measuring units 1, simultaneously carries out five different measurements of physical measured variables M. Each measuring unit 1 can measure at least one physical measurement quantity M at the same time. Each process parameter of each of the measurements is displayed in a window assigned to it on the graphical user interface GUI. Preference is in each column 10 to 50, 10 ', 40' represents the window of process parameters of the same genus. In each column 10 to 50, 10 ', 40', the computer program product C preferably represents the windows of process parameters which have the same index number I to V ha.

Fig. 3 shows a first embodiment of the graphical user interface GUI.

A first column 10 represents method parameters of the first type with five measuring units 1. Each measuring unit 1 has a unique identification number i, ii, iii, iv and v. The first column 20 is deactivated and has five collapsed windows lxl to 1x5. Each folded window lxl to 1x5 represents measuring units 1 in short form one of the five measurements.

- A second column 20 represents process parameters of the second genus with a detection 2 of the physical measurement variables M in five measurements as measurement signals. The second column 20 is deactivated and has five closed windows 2x1 to 2x5. Each folded window 2x1 to 2x5 represents in short form in one of five measurements the acquisition 2 of the physical measurement quantity M to be measured as a measurement signal.

- A third column 30 represents the process parameters of the third type of evaluation 3 from the measurement signal to a measured value for the five measurements. The fifth column 30 is deactivated and has five windows 3x1 to 3x5 that are closed. Each collapsed window 3x1 to 3x5 represents the evaluation 3 for the five measurements in short form from the measurement signal to a measurement value.

- A fourth column 40 represents the process parameters of the fourth type of representation 4 of the measurement signal or measured value for the five measurements. The fourth column 40 is deactivated and has five windows 4 × 1 to 4 × 5 that are folded. Each collapsed window 4x1 to 4x5 represents for the five measurements in short form the representation 4 of the measurement signal or measurement value.

- A fifth column 50 represents process parameters of the fifth type of further processing 5 of the measurement signal or measured value for the five measurements. The fifth column 50 is deactivated and has five windows 5x1 to 5x5 that are closed. Each collapsed window 5x1 to 5x5 represents the further processing 5 of the measurement signal or measurement value for the five measurements in short form.

A deactivated column with the windows folded uses exactly the space on the graphical user interface GUI in order to assign the assigned process parameters in the play folded windows in short form. Preferably, a column with the windows folded uses a minimal paint space of less than 5% of the graphical user interface GUI. A representation in short form of a process parameter is an abstract representation of a process parameter such as a pictogram or a sequence of letters and numbers. For example, a measuring unit 1 with a pressure sensor can be represented in short form as "Type 603C" or "MU-A-Alll-Slot_l". A detection 2 of a physical measurement variable M can be reproduced in short form as "pressure signal 2" or "acceleration signal 5". An evaluation 3 from the measurement signal to a measurement value can be represented in short form as “measurement value 3” or “OK” as an abbreviation for “available”. A representation 4 of a measurement signal or measurement value can be represented in short form as “Graph_l” or “measurement inaccuracy 2” And further processing 5 of a measurement signal or measurement value can be reproduced in short form as “trigger signal 2” or “OK” abbreviation for “data transmission carried out”.

The embodiment of the graphical user interface GUI according to FIG. 3 has five deactivated columns 10 to 50 with 25 windows lxl to 5x5 folded. For example, the 25 collapsed windows lxl to 5x5 use less than 25% of the GUI.

A status message T of the process parameters of the measuring system S can be reproduced in the graphical user interface GUI. The status message T can be activated, it can be activated and deactivated. In the embodiment of the 3, the status message T is switched on.

- The status message T of the measuring units 1 indicates, for example, whether a measurement of a physical measured variable M is currently taking place or not.

The status message T of the acquisition 2 of the physical measurement variables M as measurement signals indicates, for example, whether a physical measurement variable M is currently being acquired as measurement signals or not.

- The status message T of the evaluation 3 from the measurement signal to a measurement value indicates, for example, whether an evaluated measurement value is currently within predefined limit values or not.

- The status message T of representation 4 of the measurement signal or the measurement value indicates, for example, whether a measurement signal or measurement value can currently be displayed or not.

- The status message T of further processing 5 of the measurement signal or measurement value indicates, for example, whether a measurement signal or measurement value is currently being processed or not.

In the embodiment of the graphical user interface GUI according to FIG. 3, the status message T is implemented graphically in the windows 1x5 to 5x5 in traffic light colors white, gray and black.

- In the example, there is currently no measurement for the measuring units 1 with the identification numbers i, ii and iv. ner physical quantity M instead. The windows lxl to 5x1 of the identification number i, the windows 1x2, 2x3 to 5x3 of the identification number ii and the windows 1x4 to 5x4 of the identification number iv are highlighted in white to indicate that no measurements are currently taking place.

- In the example, measurements of a physical measurement quantity M are currently taking place for the measurement units 1 with the identification numbers iii and v. The windows 1x3 to 2x2 of the identification number iii and the windows 1x5 to 2x5 of the identification number v have a gray background to indicate that measurements are currently taking place and that measurement variables M are currently being recorded as measurement signals.

- In the example, an evaluated measured value with the identification number iii is currently within predefined limit values and can be displayed and can continue to be used. The windows 3x2 to 5x2 of identification number iii have a gray background to indicate that the measurement of the physical measurement quantity M is carried out properly here.

- In the example, an evaluated measured value with the identification number v is currently outside of predefined limit values and cannot be displayed either and will not be processed further. The windows 3x5 to 5x5 of the identification number v have a black background to indicate that the measurement of the physical measurement quantity M is not carried out properly here.

With knowledge of the present invention, the person skilled in the art can use other status messages such as the availability of a measurement realize, etc. The person skilled in the art can also reproduce a status message by other graphic means and / or acoustically.

FIG. 4 shows the graphical user interface GUI in the embodiment according to FIG. 3 with a deactivated first column 10. In comparison to FIG. 3, a cursor U has been moved over the first column 10 in FIG. 4. The deactivated fourth column 10 is to be activated, which is characterized by a bold outline of the first column 10.

Fig. 5 shows the graphical user interface GUI in the form of FIG. 4 with the activated first column 10 '. The activation of the first column 10 'is characterized by a bold solid outline of the first column 10'. An activated first column 10 'represents the measuring units 1 required for the five measurements. By activating the first column 10', the windows 111 to 135 of the first column 10 'are opened. For example, the activated first column 10 'has three sub-columns with windows 111 to 115 opened for sensors, with windows 121 to 125 opened for measuring cables and with windows 131 to 135 opened for evaluation units.

An activated column with opened windows uses exactly the space on the graphical user interface GUI to display the assigned process parameters in long form. An activated column with opened windows preferably uses a maximum space of more than 50% of the graphical user interface GUI. A rendition in the long form of a process parameter is a detailed representation. Thus, a measuring unit 1 with a pressure sensor and a thermocouple in long form an extract from a data sheet of the pressure sensor with a detailed description of the interfaces and a description of the measured physical quantities "cylinder pressure 3", "cylinder temperature 3" can be reproduced. An acquisition 2 of a physical measurement quantity M can be reproduced in long form as “maximum pressure signal 2 = 218bar” or “acceleration signal 5 = 1.5g”. An evaluation 3 from the measurement signal to a measurement value can be reproduced in long form as "measurement inaccuracy 2 = 5.3%" or as a statement "measurement value 3 is within the set limit values", etc. A representation 4 of a measurement signal or measurement value can be reproduced in long form as a graphical representation of the time course of a “pressure signal 2”. And further processing 5 of a measurement signal or measurement value can be displayed in long form as a statement “transmitted data volume = 9.2 MB / s "are reproduced.

Knowing the present invention, it is understandable for the person skilled in the art that a deactivated column is deactivated analogously to the activation of a deactivated column. An activated column is deactivated by moving a cursor U and windows of the deactivated column are collapsed.

FIG. 6 shows the graphical user interface GUI in the embodiment according to FIG. 5 with a still deactivated window 123 of the activated first column 10 '. In comparison to FIG. 5, a cursor U has been moved in FIG. 6 over the deactivated window 123. The deactivated window 123 is to be activated, which is indicated by a bold outline in the window 123.

FIG. 7 shows the graphical user interface GUI in the embodiment according to FIG. 6 with an activated window 123 of the activated first column 10 '. The activation from window 123 is marked by a bold outline from window 123. By activating the window 123, the windows 113, 123 and 133 are in the first column 10 ', the window 2x1 in the second column 20, the window 3x1 in the third column 30, the window 4x1 in the fourth column 40 and the window Marked 5x1 in the fifth column 50. Windows 113, 123, 133, 2x1, 3x1, 4x1 and 5x1 are marked by gray hatching. The marking can be easily recognized by the measurement system S on the graphical user interface GUI. The marking indicates that these process parameters belong to one and the same measuring unit 1. The computer program product C preferably marks out all windows of process parameters which have the same measuring unit 1 as the process parameter from the activated window 123 and thus have the same identification number iii as the process parameter from the activated window 123. Window 113 in long form represents the sensor used by measuring unit 1. Window 123 in long form represents the measuring cable used by measuring unit 1. Window 133 represents in long form the evaluation unit used by measuring unit 1. For measuring unit 1 The window 2x1 in short form represents the process step of the acquisition 2 of the physical measurement quantity M as a measurement signal. For the measuring unit 1, the window 3x1 in a short form represents the process step of the evaluation 3 of For the measuring unit 1, the window 4x1 briefly represents the procedural step of representation 4 of the measuring signal or measured value. For measuring unit 1, the window 5x1 briefly represents the procedural step of further processing 5 of the measuring signal or measured value.

FIG. 8 shows the graphical user interface GUI in the embodiment according to FIG. 7 with a fourth column 40 which is still deactivated. In comparison to FIG. 7, a cursor U has been moved over the fourth column 40 in FIG. 8. The fourth column 40, which is still deactivated, is to be activated, which is indicated by a bold outline of the fourth column 40.

FIG. 9 shows the graphical user interface GUI in the embodiment according to FIG. 8 with the activated fourth column 40 '. The activation of the fourth column 40 'is identified by a bold solid outline of the fourth column 40'. An activated fourth column 40 'represents the representation 4 of a measurement signal or measurement value of the five measurements. By activating the fourth column 40', windows 411 to 425 of the fourth column 40 'are opened. By activating the fourth column 40 ', not only are the windows 111 to 135 of the first activated column 10' folded, but also the first column 10 is deactivated. For example, the activated fourth column 40 'has two sub-columns with opened windows 411 to 415 for a detailed reproduction of the measurement signal or measurement value, and with opened windows 421 to 425 for a graphical see reproduction of the time course of the measurement signal or measurement value.

Fig. 10 shows a second embodiment of the graphical user interface GUI. The embodiment of FIG. 10 largely corresponds to that of FIG. 3, so that reference is made to the description thereof in the following only differences between these two embodiments are explained.

Thus, the graphical user interface GUI according to FIG. 10 has a first column 10 with windows lxl to 1x5, which windows lxl to 1x5 have a fine structure lxlxl to 1x5x4. The fine structure shows the process parameters of the measuring unit 1 required for the measurement of the physical measurement variable in a differentiated short form, despite the minimal space of the windows folded. A representation in a differentiated short form of the measuring unit 1 is an abstract representation of the measuring unit 1 by means of a pictogram or a sequence of letters and numbers, with additional information such as the reproduction of different measuring channels or of different measuring ranges of the measuring unit 1.

- In the example, a measuring unit 1 with the identification number i, v with a force sensor and three measuring channels per force sensor is represented by the fine structure lxlxl to 1x1x4 and 1x5x1 to 1x5x4. A first fine structure lxlxl, 1x5x1 represents the force sensor in short form as "Type 9047C", "Type 9047C". Another fine structure 1x1x2 to 1x1x4, 1x5x2 to 1x5x4 shows three measuring channels of each force sensor in short form as "Channel X", "Channel Y" and "Channel Z".

- In the example, a measuring unit 1 with the identification number ii, iv with a thermocouple and one measuring channel per thermocouple is represented by the fine structure 1x2x1 and 1x2x2 and 1x4x1 and 1x4x2. A first fine structure 1x2x1, 1x4x1 shows the thermocouple in short form as "Type K". Another fine structure 1x2x1, 1x4x2 shows the measuring channel for each thermocouple in short form as "Channel K".

- In the example, a measuring unit 1 with the identification number iii with a pressure sensor and two measuring ranges is represented by the fine structure 1x3x1 to 1x3x3. A first fine structure 1x3x1 shows the force sensor in short form as "Type 603C". Another fine structure 1x3x2 to 1x3x3 shows two measuring ranges of the pressure sensor in short form as "Area 1" and "Area 2".

With knowledge of the present invention, the person skilled in the art can reproduce all or all of the process parameters in their assigned windows with a fine structure.

[0041] Also, no status message T is activated in the graphical user interface GUI according to FIG. 10. Reference list

1 measuring unit

 2 Acquisition of the measurement signal

 3 Evaluation of the measurement signal

 4 Representation of the measurement signal or measurement value

5 Further processing of the measurement signal or

 Reading

 10 to 50 columns

10 ', 40' activated column

lxl to 5x5 folded window

lxlxl to 1x5x4 fine structure

111 to 135 open window

411 to 425 open window

C computer program product

 DA data output unit

 DB data bus

 DE data entry unit

 DP data processor

 DS data storage

 GUI graphical user interface

i to v identification number

 I to V index number

 M physical quantity

 R electronic computing unit

 S measuring system

 T status notification

 U cursor

 V procedure

Claims

Claims

1. Method (V) for measuring at least one physical

Measurand (M); using process parameters of a measuring system (S), which process parameters comprise several measuring units (1) required for the measurement of the physical measurement quantity (M), which process parameters include the process steps of at least one acquisition (2) of the physical measurement quantity (M) as a measurement signal, comprise at least one evaluation (3) of the measurement signal for a measurement value, of at least one representation (4) of the measurement signal or measurement value and of at least one further processing (5) of the measurement signal or measurement value; and with a computer program product (C) for setting and monitoring process parameters; characterized in that each process parameter is displayed in a window assigned to it on a graphical user interface (GUI); that each window can be collapsed, a collapsed window (lxl to 5x5) uses exactly the space on the graphical user interface (GUI) to give the assigned process parameters in short form; and that each window can be opened, an opened window (111 to 135, 411 to 425) uses exactly the space on the graphical user interface (GUI) to display the assigned process parameters in long form.

2. The method (V) according to claim 1, characterized in that a plurality of physical measurement variables (M) are measured simultaneously; and that all process parameters of the measurements in the process parameters assigned windows be displayed on a graphical user interface (GUI).

3. The method (V) according to one of claims 1 or 2, characterized in that windows with assigned method parameters in columns (10 to 50, 10 ') reproduce who and that the columns (10 to 50, 10', 40th ') can be activated and deactivated, with windows (lxl to 5x5) of a deactivated column (10 to 50) being folded; and windows (111 to 135, 411 to 425) of an activated one

Column (10 ', 40') can be opened.

4. The method (V) according to claim 3, characterized in that a deactivated column (10 to 50) is selected by moving a cursor (U) via a data input unit (DE); and that a selected deactivated column (10 to 50) is activated by pressing a key of the data input unit (DE).

5. The method (V) according to any one of claims 3 or 4, characterized in that an activated column (10 ', 40') is selected by moving a cursor (U) over a data input unit (DE); and that a selected activated column (10 ', 40') is deactivated by pressing a key of the data input unit (DE).

6. The method (V) according to one of claims 1 to 5, characterized in that the method parameters are divided into categories, a first category of method parameters comprising a plurality of measurement units (1) required for measuring the physical measurement variable (M), one second genus at least one record (2) of the physical mical measurement variable (M) as a measurement signal, a third type comprises at least one evaluation (3) of the measurement signal for a measurement value, a fourth type comprises at least one representation (4) of the measurement signal or measurement value, and a fifth type includes at least one further processing (5) from Includes measurement signal or measurement value; and that in each column (10 to 50, 10 ', 40') windows of process parameters of one and the same genus are shown.

7. The method (V) according to any one of claims 1 to 6, characterized in that windows with associated method parameters can be activated and deactivated; that process parameters of one and the same measuring unit (1) are linked to one another; and that by activating a deactivated window, windows of process parameters associated with the process parameter of the activated window are marked.

8. The method (V) according to claim 7, characterized in that a deactivated window is selected by moving a cursor (U) via a data input unit (DE); and that a selected deactivated window is activated by pressing a key of the data input unit (DE).

9. The method (V) according to one of claims 7 or 8, characterized in that an activated window is selected by moving a cursor (U) via a data input unit (DE); and that a selected activated window is deactivated by pressing a key of the data input unit (DE).

10. The method (V) according to any one of claims 1 to 9, characterized in that a minimal space of less than 5% of the graphical user interface (GUI) is used when reproducing a procedural parameter in short form.

11. The method (V) according to any one of claims 1 to 10, characterized in that a maximum space of more than 50% of the graphical user interface (GUI) is used when playing back a process parameter in long form.

12. The method (V) according to any one of claims 1 to 11, characterized in that a method parameter in a collapsed window (lxl to 1x5) assigned to it is reproduced with a fine structure (lxlxl to 1x5x4).

13. The method (V) according to any one of claims 1 to 12, characterized in that a status message (T) of the process parameters of the measuring system (S) in the graphical user interface (GUI) is displayed in the folded windows (lxl to 5x5).

14. Measuring system (S) for carrying out the method (V) according to one of claims 1 to 13, characterized in that the method parameters are divided into categories, where in a first category of method parameters several are required for the measurement of the physical measured variable (M) Measuring units (1), a second type includes at least one detection (2) of the physical measurement (M) as a measurement signal, a third type includes at least one evaluation (3) of the measurement signal for a measured value, a fourth type at least one representation (4) comprises the measurement signal or measurement value, and a fifth gate device comprises at least one further processing (5) of the measurement signal or measurement value; that each genus has a unique index number (I to V); and that the computer program product (C) on the graphical user interface (GUI) in at least two columns (10 to 50, 10 ', 40')

Displays window of process parameters that have the same index number (I to V).

15. Measuring system (S) according to claim 14, characterized in that method parameters of one and the same measuring unit (1) have a unique identification number (i to v); and that when a deactivated window is activated, the computer program product (C) on the graphical user interface (GUI) marks windows of process parameters which have the same identification number (i to v) as the process parameter assigned to the activated window.