DE102016106976B4 - Method for determining a model of a technical system - Google Patents

Abstract

Method for determining a model of a technical system, wherein the determination of a range of variations of the input variables / input quantity combinations of the technical system takes place and wherein the model uses input variables / input quantity combinations to determine output variables of the technical system, comprising the following steps: a) specification of input quantity limits, b C) Determining input variables / input variable combinations within the input quantity limits and associated output variables, by setting input variables / input value combinations and measuring output quantities on the technical system, whereby at least one input variable / input variable combination is determined which causes an output variable that is on one D) determination of a first convex hull on the basis of the determined input variables / input variable combinations, where some or a Limit values of the first convex hull, where hyperplanes are present at the boundary points, the hyperplanes including the set of determined input variables / input variable combinations, e) setting of further input variables / input variable combinations and measurement of output variables on the technical system, the further input variables / Input size combinations are within the input size limits, as well as within the first convex hull and / or outside the first convex hull, excluding inputs / input size combinations that are within at least one other convex hull, with each further hull being merely a boundary point of the first convex hull as well as the points of intersection of the hyperplanes present at this only one boundary point with the input size limits and optionally existing intersections of the input quantity limits Gr the at least one further convex hull, wherein the only one boundary point of the first convex hull corresponds to an input quantity / input quantity combination which causes an output quantity that lies on an output limit, f) training of parameters of the model of the technical system based on the determined input variables / Input variable combinations and output variables.

Description

The present invention relates to a method for determining a model of a technical system with the features according to claim 1.

For example, according to Schreiber, A. (2010): "Dynamic engine measurement using different methods and models"; In: Electronic Management of Motor Vehicle Drives: Electronics, Modeling, Control and Diagnostics for Internal Combustion Engines, Gears and Electric Drives; 1. Aufl. Wiesbaden: R. Isermann, pp. 167-199 it is known that the most accurate knowledge of the manipulated variable ranges of an internal combustion engine is a necessary prerequisite for the measurement of the internal combustion engine. In particular, it is known from this that not all possible combinations of manipulated variables are applicable. Rather, there are limits whose exceeding leads to damage or to undesirably high emissions. In any case, based on these limits results in a so-called variation space. To determine the variation space, several methods are described, for example a star-shaped departure in steps, until the respective limit is reached. Also shown is a method for determining the variation space, wherein the permissible manipulated variable combinations obtained in the form of a convex envelope are imaged. Based on this now known variation space can then be made an adaptation of the experimental design used.

Such a procedure is also from Renninger, P., K. v.. Pfeil, D. Hofmann, R. Isermann (2005): "Dynamic Models and Their Application in the Optimization of Commercial Vehicle Engines"; In: 14th Aachen Colloquium - Vehicle and Engine Technology; 1st edition Aachen, p. 1205-1222 known. In particular, it describes that first a basic measurement is carried out to determine limit points. On the basis of these boundary points then the calculation of a convex hull, which describes the space of variation. However, since only a part of the actual variation space was determined with the basic measurement, the measurement of the variation space is continued on the basis of this convex envelope. Starting from the midpoint of each hyperplane of the convex hull, a further determination of boundary points takes place in the direction of the respective normal vector. Based on the boundary points thus determined, a convex hull is formed again. Starting from this convex hull, as described in a next step, a new determination of boundary points takes place, so that the convex hull, which in each step corresponds only to the respective determined variation space, approaches the actual space of variation.

It is known according to the EP 1 150 186 A1 a method for automatically optimizing an output of a multiple input-dependent system, such as an internal combustion engine, while maintaining constraints. This method determines a theoretical value for the output variable and the secondary conditions on the basis of a model function with the input variables as variables and in each case changes one of the input variables within a variation space with a dimension corresponding to the number of input variables in successive individual steps, whereby corresponding values also correspond to the respective input variables for output variable and constraints determined directly on the system and used to correct the model functions until the model function has reached its optimum conditional value for the output variable. In order to arrive at a secure optimal value for the system faster and with less effort, the change of the input variables for the calculation and determination takes place in a first stage in an arbitrary predetermined sequence. In this case, an individual, predetermined step size is not exceeded for each input variable. Furthermore, after processing the predetermined sequence, the combination of input variables is used as the starting point for the second stage, which is closest to the optimum value.

According to the DE 10 2009 059 931 A1 is a method for determining a parameterizable polynomial model for a dependent on an influence variable of an internal combustion engine target size of the internal combustion engine prior art. To allow for improved polynomial modeling, the following steps are provided. 1. Providing a plurality of target single-polynomial models, each designed for a single internal combustion engine. 2. Determine a large number of individual terms that occur in several of the single polynomial models. 3. Determining the polynomial model by means of the plurality of individual terms.

According to US 2014/0 344 320 A1 a method for evaluating the solution of a multi-criteria optimization problem of objective functions is known, wherein the set of optimal solutions of the multi-criteria optimization problem in a model space are represented as a two- or three-dimensional diagram and at least one in a variation space simultaneously the target functions are represented as a function of at least one variation variable and the model space and the variation space are interactively interconnected by marking the variation variable underlying the solution for each selected solution in the model space.

The methods described require extensive upstream measurements of the variation space. As a result of this upstream and extensive process step of stepwise measurement of the variation space, valuable time is needed. A further disadvantage is also that the quality of the resulting parameters of the model to be determined is reduced, since the position of the experimental points is optimized for the experimental space finding.

It is therefore an object of the present invention to make the determination of a model of a technical system less time-consuming and thereby to increase the quality of the resulting parameters of the model determined.

1. a) Vorgabe von Eingangsgrößengrenzen,
2. b) Vorgabe von Ausgangsgrößengrenzen,
3. c) Ermittlung von Eingangsgrößen/Eingangsgrößenkombinationen innerhalb der Eingangsgrößengrenzen und dazugehörigen Ausgangsgrößen, durch Einstellung von Eingangsgrößen/Eingangsgrößenkombinationen und Messung von Ausgangsgrößen am technischen System, wobei zumindest eine Eingangsgröße/Eingangsgrößenkombination ermittelt wird, die eine Ausgangsgröße verursacht, die auf einer Ausgangsgrößengrenze liegt,
4. d) Bestimmung einer ersten konvexen Hülle anhand der ermittelten Eingangsgrößen/Eingangsgrößenkombinationen, wobei einige oder alle Eingangsgrößen/Eingangsgrößenkombinationen Grenzpunkte der ersten konvexen Hülle sind, wobei an den Grenzpunkten Hyperebenen anliegen, wobei die Hyperebenen die Menge der ermittelten Eingangsgrößen/Eingangsgrößenkombinationen einschließen,
5. e) Einstellung von weiteren Eingangsgrößen/Eingangsgrößenkombinationen und Messung von Ausgangsgrößen am technischen System, wobei die weiteren Eingangsgrößen/Eingangsgrößenkombinationen innerhalb der Eingangsgrößengrenzen liegen, sowie innerhalb der ersten konvexen Hülle und/oder außerhalb der ersten konvexen Hülle, unter Ausschluss von Eingangsgrößen/Eingangsgrößenkombinationen, die innerhalb zumindest einer weiteren konvexen Hülle liegen, wobei je weiterer konvexen Hülle lediglich ein Grenzpunkt der ersten konvexen Hülle sowie die Schnittpunkte der an diesem lediglich einen Grenzpunkt anliegenden Hyperebenen mit den Eingangsgrößengrenzen und gegebenenfalls vorhandene Schnittpunkte der Eingangsgrößengrenzen die Grenzpunkte der zumindest einen weiteren konvexen Hülle sind, wobei der lediglich eine Grenzpunkt einer Eingangsgröße/Eingangsgrößenkombination entspricht, die eine Ausgangsgröße verursacht, die auf einer Ausgangsgrößengrenze liegt,
6. f) Training von Parametern des Modells des technischen Systems anhand der ermittelten Eingangsgrößen/Eingangsgrößenkombinationen und Ausgangsgrößen.

This object is achieved according to the invention by means of a method for determining a model of a technical system, whereby the determination of a variation space of the input variables / input quantity combinations of the technical system takes place and wherein output variables of the technical system are determined by means of the model on the basis of input variables / input variable combinations, with the following steps:

1. a) specification of input quantity limits,
2. b) specification of output limits,
3. c) determination of input variables / input variable combinations within the input quantity limits and associated output variables, by setting input variables / input variable combinations and measuring output variables on the technical system, whereby at least one input variable / input variable combination is determined which causes an output variable that lies on an output limit,
4. d) determining a first convex hull on the basis of the determined input variables / input quantity combinations, some or all input variables / input quantity combinations being boundary points of the first convex hull, wherein hyperbranches are present at the boundary points, wherein the hyperplanes include the set of the determined input variables / input variable combinations,
5. e) setting of further input variables / input quantity combinations and measurement of output variables on the technical system, wherein the further input variables / input quantity combinations are within the input size limits, and within the first convex hull and / or outside the first convex hull, excluding input variables / input variable combinations, the lie within at least one further convex hull, wherein each further convex hull is merely a boundary point of the first convex hull and the intersections of the hyperplanes adjoining this only one boundary point with the input size limits and optionally existing intersections of the input size boundaries are the boundary points of the at least one further convex hull, which corresponds to only one limit point of an input quantity / input quantity combination which causes an output quantity which lies on an output quantity limit,
6. f) training of parameters of the model of the technical system based on the determined input variables / input value combinations and output variables.

According to the invention, the determination of a test space / a convex casing takes place on the basis of previously performed measurements in individual steps or at any time. In the process, this convex hull is widened by the described strategy in such a way that a new convex region arises in which the planning of a test point takes place. After measuring this experimental point, the convex hull of all previous measurements is again formed, this is extended with the described strategy, a new point planned and so on. Compared to the prior art, only a minimal initial design plan is measured, in any case eliminates the costly determination of system boundaries in an upstream process step.

According to the invention, therefore, the convex hull is iteratively extended in an online process, so that points outside the convex hull are also planned. When an outside point has been measured, with the position of the point in turn depending on the behavior of the technical system under consideration, a new convex hull is calculated and expanded again. The end result of the expansion of the convex hull according to the invention is a non-measured region, but this indicates the maximum possible variation space at this time, provided that a convex variation space is assumed. Thus, there is an area that will be used for further experimental design, which aims to optimize the evaluable model range (convex hull after the entire survey) and the model quality itself. It is advantageous that, by means of the method according to the invention, a refinement of the model as well as the boundary measurement are combined by expanding the respectively current convex hull and carrying out a planning within the extended area.

According to the invention, therefore, the release of a further area, which is to be used for the experimental design. This results from the combination of the determination of the maximum possible convex envelope size (extension strategy) and the experimental design within this space based on other criteria (eg a distance-based criterion) according to the invention a synergy effect. Ie. the coupling between finding the boundaries of the variation space and selecting suitable experimental points for modeling is resolved.

In summary, there is an extension of the variation space for an experimental design or a maximization of the usable range for a later model evaluation. The result is an increase in acceptance of such methods, since a process step is eliminated.

Further advantageous embodiments of the present invention will become apparent from the following embodiment and the dependent claims.

As is well known, a technical system has inputs and outputs. In particular, the technical system may be an internal combustion engine. The internal combustion engine can be operated according to the Otto principle or the diesel principle. For example, the internal combustion engine has a variable valve control. In particular, the internal combustion engine has both an adjustable intake camshaft and an adjustable exhaust camshaft. Ie. a double variable camshaft spread, so the timing of the inlet and the outlet can be adjusted relative to each other. In any case, this results in two input variables, ie an input variable combination of the technical system, which is here an internal combustion engine, namely the (variable) timing of the intake valves and (variable) timing of the exhaust valves. Changes in these two input variables in turn cause changes in engine output, as is well known. Thus, in particular by a change (at least one) of the two input variables, the residual gas quantity or the residual gas component in a combustion chamber of the internal combustion engine is influenced or changed, or a new input variable combination results. Ie. the residual gas content may be a first output. The term "input variable combination" denotes a combination of two or more input variables. The words "input variable" or "input variables" can correspond to the formulation "input variable combination".

As in 1 indicated by the arrow, the residual gas increases in proportion to the separation of the intake and exhaust valves, ie the later the exhaust valves close and the sooner open the intake valves, the greater the overlap and thus the residual gas content. It is questionable now how much residual gas is expedient in an operating point of the internal combustion engine. For this purpose, for example, a further output variable can be considered, namely the smoothness of the internal combustion engine or the extent of the so-called cyclic fluctuations or the standard deviation of the indicated mean pressure of the internal combustion engine. The aim in the calibration or application of an internal combustion engine, it is known to find optimum settings, in this case, the overlap and thus adjust the residual gas content so that the residual gas content is as high as possible and consequently z. B. the fuel consumption is as low as possible (fuel consumption may be a further output variable) and / or the internal combustion engine as low as possible releases nitrogen oxides (the nitrogen oxide concentration in the exhaust gas may still be a further output variable) and / or the internal combustion engine is not unacceptably many hydrocarbons (the hydrocarbon concentration in the exhaust gas may still be a further output variable), but the smoothness of the internal combustion engine may not be deteriorated so that a predetermined limit is violated. In any case, there is a course of a limit value GW regarding the quiet running of the internal combustion engine, which must not be violated, see 1 , This course of a limit value GW is initially unknown. The aim is to determine a model with which it is possible to describe the influence of these input variables on output variables - in this case smoothness - on the basis of input variables, in this case on the basis of the variable timing of the intake valves and the variable timing of the exhaust valves or the overlap and thus also to determine or disclose the respective limit value GW or the course of the limit value GW. As those skilled in the art know, these considerations also apply to further output variables, ie the fuel consumption or the nitrogen oxide or hydrocarbon concentration in the exhaust gas, ie there is also a (initially unknown and to be modeled) functional relationship between input and output variables or Input variables and the respective limit value GW or the course of the limit value GW.

For a determination of a model that is as accurate as possible (that is, the most suitable parameters of this data model), it may be best to carry out experiments, ie settings of input variables and measurements of output variables on the technical system, over the entire relevant range of input variables or the entire relevant input variable space (also Variation space called) to distribute. In any case, it is not advantageous to determine the position of the test points to be examined in the variation space (ie the combinations of set input variables / input variable combinations and measured output variables), as described in US Pat State of the art described, only with regard to the determination of the input size space / input size range to optimize or align accordingly. According to the bill is taken into account, as will become clear later.

First, input size limits are specified, ie the maximum variation space of the input variables is staked out. As in 1 shown, two input size limits initially arise from the fact that the range of adjustability of an input variable - here the variable timing of the intake valves - by a latest possible timing of the intake valves or a latest possible opening of the intake valves (left vertical line in 1 ) is limited and by an earliest possible timing of the intake valves or the earliest possible opening of the intake valves (right vertical line in 1 ) is limited. Two input size limits continue to result from the fact that the range of adjustability of the second input variable - here the variable timing of the exhaust valves - by an earliest possible timing of the exhaust valves or the earliest possible closing of the exhaust valves (lower horizontal line in 1 ) is limited and by a latest possible timing of the exhaust valves or a possible closing of the exhaust valves (upper horizontal line in 1 ) is limited.

Furthermore, output limits are specified, i. H. in particular minimum and / or maximum values which may not be exceeded or fallen short of as a result of a setting / variation of the input variables. These may be so-called hard or soft limits, see above in the cited prior art. Following the described embodiment, there is an output limiting, in particular, that due to the variation of the timing of the intake and exhaust valves of the limit GW regarding the smoothness may not be violated. Also conceivable here again (alternatively or additionally) is the specification of the relevant limit values GW (as output variable limits) with regard to the fuel consumption and / or the nitrogen oxide or hydrocarbon concentration in the exhaust gas.

According to the invention, in a further step, a determination of input variables within the previously specified input quantity limits, ie a determination of timing of the intake valves and timing of the exhaust valves or combinations thereof and a determination of the associated output variables of the technical system, so here the internal combustion engine. Ie. there is a determination of associated input variables and output variables, wherein the output quantities result just because input variables are set on the technical system and the technical system by its properties or by running physical / chemical processes quasi out of the input variables produces specific output variables, which is generally is known. The setting of the input variables / input variable combinations preferably takes place by means of an automation system.

As in 1 4, initially, a total of four input variables / input variable combinations are determined, within the predefined input variable limits, namely four combinations of intake valve timing and exhaust valve timing, highlighted in FIG 1 through circular rings. In other words, four different overlaps are given. As already described, the determination of these input variables within the input quantity limits as well as the output variables caused thereby or caused by the technical system takes place by setting these four combinations of intake valve timing and exhaust valve timing on the internal combustion engine (especially in conjunction with FIG a suitable test equipment / test bench and known measurement technology) and by measuring the output variables. As already described, for example, the smoothness, the fuel consumption or the concentration of nitrogen oxides / hydrocarbons in the exhaust gas can be such an output variable. In any case, at least one input quantity / input quantity combination is determined which causes an output quantity which lies on a (previously defined) output size limit. As described, only the smoothness can be a possible output that is considered in this regard. As in 1 In this case, even two input variables or two combinations of intake valve timing and exhaust valve timing are detected ( G1 . G3 ), which each cause an output in that the smoothness of the limit GW corresponds, ie the respective output is on an output size limit or on the in 1 shown course of the limit GW regarding the smoothness of the internal combustion engine.

According to the invention, the determination of input variables within the input quantity limits and the determination of the associated output variables, by setting input variables and measuring output variables on the technical system not only / not exclusively means that the determination of the at least one input variable which causes an output variable is based on an output limit is done directly by setting input variables and measurement of output variables on the technical system, so that the technical system or the internal combustion engine actually at a boundary to determine the input that will cause an output that is at an output limit. Rather, this determination can also be made indirectly. This can be done according to the invention in that an adjustment of input variables and measurement of output variables takes place on the technical system / internal combustion engine, but at least one output variable that is located on an output limit is not immediately sought / measured, but first a training (the parameter ) of the model of the technical system on the basis of the (determined) input variables and (uncritical, since the internal combustion engine does not have to be brought to a limit range) output quantities and then on the basis of the model the determination / determination of at least one input variable which causes an output variable which determined by the model) output size limit.

In the further course, on the basis of the input variables / input variable combinations determined as described above, the determination of a variation space is carried out, specifically the determination of a first convex hull. As is known, it is possible to include a convex set - here the set of detected inputs - by hyperplanes that lie on the edge of the convex set. Ie. Some or all of the determined input variables / input quantity combinations may be boundary points of a convex hull. A convex hull is known to be the smallest convex polygon covering the set of all points (here, input sizes / input size combinations).

Suppose it were, as in 1 shown, only four input variables / input size combinations determined, then all the determined input variables / input quantity combinations are limit points of the first convex hull. To limit the in 1 shown convex set of four input variables / input value combinations hyperplanes are used, ie on the four boundary points ( G1 - G4 ) of the convex set are four hyperplanes. As an example, of the four hyperplanes, the first are the two hyperplanes H1 and H2 in 1 highlighted. The first hyperplane H1 is at the border point G1 and at the border point G2 at. The second hyperplane H2 is at the border point G1 and at the border point G3 at. In any case, according to the interaction of the four hyperplanes 1 According to the invention, a convex hull is determined / calculated on the basis of the determined input variables, these input quantities being boundary points of the first convex hull against which hyperplanes lie, so that the hyperplanes include the convex set of determined input variables.

According to the invention, for the further determination of the variation space or for finding further input variables / input variable combinations for the following experimental design, an extension of the first convex hull takes place by input variables which lie outside the currently present first convex hull. Ie. it is explicitly determined outside the first convex hull of the set of input variables previously determined as described above, other input variables. For this purpose, a setting of further input variables and measurement of output variables takes place on the technical system, wherein the further input variables are always within the input size limits, but both within the first convex hull and outside the first convex hull. As already described, the (current) first convex hull is defined by the four ( G1 - G4 ) formed adjacent hyperplanes. As in 1 illustrated by the hatching, all input variables are now used for a further experimental design / extraction of input-output variable combinations for creating a model of the technical system, which lie in the hatched area, ie also outside the previously determined first convex hull.

Ie. It is also possible to determine or determine input variables which lie in the area / space (the envelope, which is likewise convex here, it can also be a concave envelope), which is between the boundary point G1 , the limit point G2 and the point of intersection S2 (which results from the input size limit and the second hyperplane H2 cut) and the input quantity limit (here the right vertical line representing the maximum advance of the intake camshaft) through the hyperplanes H1 and H2 and the further input quantity limit is included. Another point of intersection of this likewise convex hull is the point of intersection E1 the input quantity limits with each other.

Input variables can also be determined in the space / region or within the convex hull whose boundary points are the intersection point E2 the input quantity limits, the limit point G2 and the limit point G4 are.

Input variables can also be in the space / area or within the convex Sheath be determined whose / their limit points of the intersection E3 the input quantity limits, the limit point G4 , the point of intersection S3 (which results from the input size limit and the second hyperplane H2 cut) and the limit point G3 are.

Input variables can also be determined in the space / region or within the convex hull whose boundary points are the intersection point S4 (which results from the input size boundary and a hyperplane intersecting), the intersection S1 (which results from the fact that the input size limit and the first hyperplane H1 cut), the limit point G1 , the limit point G3 as well as the intersection E4 are the input size limits.

According to the invention, however, the two in 1 non-hatched areas / spaces / convex envelopes whose boundary points S1 . S2 and G1 such as S3 . S4 and G3 are excluded from the further determination of input variables and measurement of output variables in the technical system, although these further input variables are within the input size limits or even outside the first convex hull (which by the boundary points G1 - G4 limited / formed), as in the previously described cases.

As per 1 is characterized by the course of the limit value GW of quiet running, the technical system, here the internal combustion engine, then up to and including a limit GW of outputs operable when input variables / input combinations are set, which are part / element of an amount that a convex Sheath is enclosed. It is now concluded that the input variables which cause output variables beyond the limit value GW are only suitable for setting further input variables and measuring output quantities on the technical system if the first convex envelope ( G1 - G4 ) around another (here) convex envelope ( G3 . S4 . E4 . S1 . G1 ), but according to the invention just the setting variables are excluded, which cause output variables beyond the limit value GW, which are part / element of an amount which is bounded by a convex envelope ( S1 . S2 . G1 and S3 . G3 . S4 ) is included.

In practice, there is an exclusion of input variables which are within a further convex envelope ( S1 . S2 . G1 and S3 . G3 . S4 ), see 1, d , H. there are two such other convex hulls here. Of course, depending on the application, there may be more than two such further convex hulls.

These further convex hulls have the following limit points. The limit point G1 the previously determined first convex hull is also a boundary point of the one convex hull (in 1 right, not hatched), which comprises (in the further step of the procedure) input variables to be excluded. In this way, the reference is made to the (respective) output limit because the first boundary point G1 corresponds to the previously determined first convex hull of an input / input quantity combination causing an output that is on an output limit. In any case, it is important that only one boundary point of the (previously determined) first convex hull is also a boundary point of one convex hull, which includes / excludes further input variables and not two or more boundary points of the (previously determined) first convex hull , So not the two limit points G1 and G3 according to 1 Part of the one convex hull, which includes in the further course to be excluded input variables, but only the limit point G1 , Another boundary point of a convex hull (in 1 right, not hatched), which comprises (in the further step of the procedure) input variables to be excluded, is the point of intersection S1 which is formed by the fact that at this only one limit point G1 adjacent hyperplane H1 and intersect the right input limit. Another boundary point of a convex hull (in 1 right, not hatched), which comprises (in the further step of the procedure) input variables to be excluded, is the point of intersection S2 which is formed by the fact that at this only one limit point G1 adjacent hyperplane H2 and intersect the right input limit. Anyway, it's through the hyperplane H1 between the boundary point G1 and the point of intersection S1 , the input size limit between the intersection S1 and the point of intersection S2 and through the hyperplane H2 between the intersection S2 and the limit point G1 this one convex hull (in 1 right, not hatched).

In this way, the second convex hull (in 1 left, not hatched), which comprises (in the further step of the method) input variables to be excluded.

It is also conceivable that these further convex hulls continue to have boundary points that are intersections of input size limits with each other. If not in 1 shown, the case could be that the intersection S1 moves to the left, that is to the left of the intersection E4 is the input size limits, so that the above-described one convex hull, which has to be excluded input variables, not only three, but four boundary points, namely in addition to the intersection E4 the input quantity limits with each other.

If, as shown, input variables and associated output variables are determined, the input quantities being part / elements of the quantity which according to the invention has been expanded within the input quantity limits, ie excluding defined input variables, then a training of the parameters of the model of the technical system is based on this (determined ) Inputs and outputs performed as generally known.

Preferably, the inventive method for determining a model of a technical system is performed stepwise, d. H. the first convex hull is iteratively extended.

As described, an adjustment of further input variables / input variable combinations and measurement of output variables takes place according to the invention in the technical system.

In this case, at least one input variable / input variable combination is again determined which causes an output variable which lies on an output limit.

Based on the first convex hull, the determination of an expanded convex hull is then performed on the basis of the now determined input variables / input quantity combinations, again some or all now determined input quantities / input quantity combinations being boundary points of the extended convex hull and in turn abutting the boundary points hyperplanes and the hyperplanes the set the now determined input variables / input size combinations include.

In any case, a new setting of further input variables / input quantity combinations and measurement of output variables takes place on the technical system, wherein the further input variables / input quantity combinations are within the input size limits, and within the extended convex hull and / or outside the extended convex hull, excluding input variables / input variable combinations which lie within at least one further convex hull, wherein each further convex hull is merely a boundary point of the widened convex hull and the intersections of the hyperplanes adjoining this only one boundary point with the input size limits and possibly existing intersections of the input size limits are boundary points of the at least one further convex hull , wherein the only one limit point of the extended convex hull of an input variable / input variables determined in the previous step corresponds to an output that is at an output size limit.

This process is carried out repeatedly, with the first convex hull widening with each repetition, so that a training of the parameters of the model of the technical system takes place on the basis of the number of ascertained input variables / input quantity combinations and output quantities increasing with each repetition, whereby the method repeats until a certain criterion is met. The criterion is, for example, that a given accuracy of the model of the technical system is achieved.

Claims (9)

Method for determining a model of a technical system, wherein the determination of a range of variations of the input variables / input quantity combinations of the technical system takes place and wherein the model uses input variables / input quantity combinations to determine output variables of the technical system, comprising the following steps: a) specification of input quantity limits, b C) Determining input variables / input variable combinations within the input quantity limits and associated output variables, by setting input variables / input value combinations and measuring output quantities on the technical system, whereby at least one input variable / input variable combination is determined which causes an output variable that is on one Determining a first convex hull on the basis of the determined input variables / input variable combinations, wherein some od all input quantities / input quantity combinations are limit points of the first convex hull, with hyperplanes present at the boundary points, wherein the hyperplanes include the set of the determined input variables / input variable combinations, e) setting of further input variables / input variable combinations and measurement of output variables on the technical system, wherein the other Input variables / input quantity combinations are within the input size limits, as well as within the first convex hull and / or outside the first convex hull, excluding input variables / input quantity combinations lying within at least one further convex hull, wherein each further convex hull is merely a boundary point of the first convex hull Shell as well as the intersections of the only one boundary point adjacent hyperplanes with the input size limits and possibly existing intersections of the input quantity limit en are boundary points of the at least one further convex hull, wherein the only one boundary point of the first convex hull corresponds to an input quantity / input quantity combination which causes an output quantity which lies on an output limit, f) training of parameters of the model of the technical system based on the determined input variables / input value combinations and output variables. Method according to Claim 1 in which, if in step e) an adjustment of further input variables / input quantity combinations and measurement of output variables has taken place on the technical system and again at least one input variable / input variable combination has been determined which causes an output quantity which lies on an output limit based on the first convex envelope an expanded convex hull is determined on the basis of the now determined input variables / input quantity combinations, some or all of the now determined input variables / input quantity combinations being boundary points of the enlarged convex hull, again having hyperplanes at the boundary points, wherein the hyperplanes are the set of now determined input quantities / input size combinations wherein step e) is repeated, so that a new setting of further input variables / input variable combinations and measurement of output quantities at the tech nischer system takes place, wherein the other input variables / input size combinations are within the input size limits, as well as within the extended convex hull and / or outside the extended convex hull, excluding inputs / input combinations that are within at least one other convex hull, the other convex Shell only a boundary point of the extended convex hull and the intersections of the present at only one boundary point hyperplanes with the input quantity limits and possibly existing intersections of the input quantity limits are boundary points of at least one other convex hull, which is merely a boundary point of the extended convex hull an input variable / input variable combination which causes an output that is on an output limit. Method according to Claim 2 , the method according to Claim 2 is repeated, wherein the first convex hull expands with each repetition, so that according to step f) a training of the parameters of the model of the technical system based on the increasing with each repetition number of determined input variables / input quantity combinations and output variables, the method as long is repeated until a certain criterion is met. Method according to Claim 3 , the criterion being that a given accuracy of the model of the technical system is achieved. Method according to Claim 1 to 4 in which the determination of input variables / input variable combinations within the input quantity limits and the determination of the associated output variables is effected by setting input variables / input variable combinations and measuring output variables on the technical system, but not directly measuring at least one output variable that is at an output limit First, a training of the model of the technical system based on the set input variables / input variable combinations and measured outputs is done and then based on the model, the determination of at least one input variable / input variable combination takes place, which causes an output that is on an output limit. Method according to Claim 1 to 5 , wherein the technical system is an internal combustion engine. Method according to Claim 6 , wherein the internal combustion engine is operated according to the Otto principle or the diesel principle. Method according to Claim 1 to 7 , wherein the adjustment of the input variables / input variable combinations takes place by means of an automation system. Method according to Claim 8 , wherein the setting of the input variables / input variable combinations, a continuous monitoring takes place, whether an output limit is reached.

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