EP2513727A1

EP2513727A1 - Method for determining function parameters for a control unit

Info

Publication number: EP2513727A1
Application number: EP10788302A
Authority: EP
Inventors: Marcus Boumans; Markus Bossler; Martin Johannaber; Maximilian Reger
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2009-12-17
Filing date: 2010-12-02
Publication date: 2012-10-24
Also published as: JP2013513877A; WO2011082908A1; KR20120104249A; CN102652292A; US20120283848A1; US9046885B2; DE102009054905A1; IN2012DN03268A; CN102652292B

Abstract

The invention relates to a method for determining function parameters (20) for a control unit (22), and to a control unit (22) in which the method according to the invention is carried out. The control unit (22) is provided for actuating a technical system (10), wherein in the method at least one target variable is predefined for a system behaviour and a variation of the function parameter (20) is carried out, wherein from a received response to the function parameter (20) an evaluation of the set function parameters (20) is carried out taking into account the at least one predefined target variable.

Description

Description title

Method for determining functional parameters for a control device

The invention relates to a method for determining functional parameters for a control unit and such a control unit.

State of the art

In the case of injection systems for internal combustion engines, control unit functions that are implemented in the control units used must be designed according to requirements with regard to the target parameters or evaluation criteria of the manufacturer and the end customer via functional parameters.

The complexity of the functions and thus the number of functional parameters increase with increasing demands on the system. At the same time, however, the customer demands a simplification of the structures, since a complex software structure can only be handled with expert knowledge and is difficult to apply.

The above-mentioned control unit functions make it possible to determine fixed settings by means of a parameter set, in many cases also by means of several parameter sets, via constants, characteristic curves and characteristic diagrams. It should be noted that the complexity of the functions and thus the number of maps is constantly increasing. Function specialists who know the influence of each parameter at best can interpret the functions according to the requirements of the customer.

The customer gets his desired compromise from a variety of optimal, possible compromises. Deviations from the requirements can be compensated by recursions. Disclosure of the invention

Against this background, a method for determining functional parameters with the features of claim 1 and a control unit with the features of claim 10 are presented. Embodiments result from the dependent claims and the description.

Through the use of self-applying functions, a plurality of function parameters, characteristics and maps can be reduced to one or a few operating point dependent weighting maps for the user. Thus, even with increasing complexity of the ECU functions, the complexity for the customer or the user can be reduced. The application takes place as a specification of the target values and criteria or their weightings. Thus, the user need not be a functional specialist to implement the desired system requirements. Furthermore, it is not necessary for the user to know the function parameters.

The method enables an application by directly specifying objective target values or criteria for a function in the control unit.

It should be noted that increasingly complex software structures increase the technical requirements and the effort in the application both internally and at the customer. The use of self-applying functions with weighting maps in the control unit makes it possible to change and specify the system behavior directly via the target variables or evaluation criteria or via their weightings. For the user, a multiplicity of function parameters, characteristic curves and characteristic maps can thereby be reduced to one or a few operating point-dependent weighting characteristics.

The invention makes possible an application by setting target variables, in which case the concentration is the target variables and not the functional parameters. This leads to a reduction in complexity for the user, especially since no function specialist is necessary for the vote.

The presented procedure allows a systematic approach with objective evaluation of the settings. Furthermore, recursions are necessary for adjustment. solution is less costly. Optionally, a reduction of map structures in the control unit can be achieved.

With the method, it is possible to develop a control unit function or to extend existing control unit functions, so that they apply independently. The function goals are specified by the applicator or customer in design via one or more weighting characteristics of the target variables or criteria. The function learns the necessary internal function parameters.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination indicated, but also in other combinations or in isolation, without departing from the scope of the present invention.

Brief description of the drawings

Figure 1 shows a schematic representation of a possible embodiment of the method described.

FIG. 2 shows a further possible embodiment of the method.

Embodiments of the invention

The invention is schematically illustrated by means of embodiments in the drawings and will be described in detail below with reference to the drawings.

FIG. 1 outlines a method sequence which directly performs parameter variations, such as, for example, function parameters, on a target system or system 10 and in which the system 10 is operated at different operating points. From the system response, criteria are calculated from the system 10 in a step 12. From the calculated criteria and the predefined target values then, for example, a mathematical model or criteria model 14 is formed, which creates the dependencies of the target variables and criteria from the parameters.

An optimizer 16 may optimize on the basis of the given weighting criteria from a weighting map 18 on this model 14 and determine the optimal function parameters 20 and provide them to the actual functions of the controller 22 and update them again and again, the optimizer 16 is a development of system responses or can take into account the criteria calculated on the system responses, for example by a gradient analysis or evaluation.

The system 10 thus initially moves with start parameters of the control unit function. In doing so, the system 10 is operated at any operating point with the adjusted function parameters 20, providing outputs on which criteria are calculated. With these criteria, the criteria or behavioral model 14 is created. The optimizer 16 determines the optimal parameters with a given weighting in the measured range of the behavioral model 14 and changes the corresponding function parameters with the results.

This means that the system 10 initially uses function parameters which have been specified or accepted, for example. However, these are not usually tuned to the system 10, i. that these are not optimal for the system 10.

At the beginning of the determination of the functional parameters 20, the behavioral model 14 usually does not exist. However, it is also possible to deposit a behavioral model 14 of a similar system 10.

The system 10 is then operated at different operating points and thereby learns its own behavior at different operating points. In this process, the optimizer 16 of the function specifies parameter combinations representing a prediction of the optimizer 16 with respect to an improvement of the behavioral model 14. Thus, parameter combinations are tried which are intended to improve the behavior of the system 10. The behavior model 14 is extended by the criteria and the parameter combination. With the extended parameter combination and the associated criteria, a new extended behavioral model 14 is calculated.

The optimizer 16 uses the behavior model 14 and checks whether the parameter specification has led to the improvement or deterioration of the behavior of the system 10. As a result, the optimizer 16 gradually determines the combination of parameters in which the optimal behavior of the system 10 is established with respect to the criteria. This is done in an iterative process in which the behavioral model 14 grows until the optimal behavior is found. This is done for each operating point.

The optimizer 16 determines each of the optimal parameters of the behavioral model 14 in the measured range and gives a forecast on whether a further improvement of the behavior can be achieved. The task of the optimizer 16 is to evaluate the criteria of the behavioral model 14 according to the prediction from the weighting maps.

In this case, the specification to the optimizer 16 may be a summation criterion of weights for which the optimizer 16 finds only a solution of the parameters. Alternatively, the function may be designed such that the optimizer 16 delivers a multitude of function parameters 20 via multi-objective optimization and the function parameter selection takes place via the weighting of the criteria from a memory or model of optimal parameters. In this case, after learning the criteria model 14, the weighting criteria can be shifted at any time. The function parameters 20 take effect immediately. The user can apply in this way without having to know the function parameters 20.

This results in two phases:

1 . Fast learning of the function parameters 20 and the application by tuning the weighting maps 18.

2. Slow adaptation of the function parameters 20 over the lifetime. A phase change can be made via the information of the learned operating behavior.

If, after the second phase, there is a memory or model of optimum parameters for the function via a multi-objective optimization, the weightings can be changed at any time, for example by switching different weighting maps or by controlling directly on the weightings.

FIG. 2 shows a procedure similar to that in FIG. 1, with the difference that parameters are not varied directly on a system 30, but rather via an intermediate model 32, in order to avoid noticeable influences of the variations.

The intermediate model 32 replaces the system 30 and is aligned with the system 30 under defined conditions by identification, optimization, or other computations (block 35).

From the answer of the intermediate model 32, criteria from the intermediate model 32 are calculated in a step 34. A mathematical model or criteria model 36 is then formed from the calculated criteria and target variables, which creates the dependencies of the target variables and criteria on the parameters.

An optimizer 38 can then optimize by providing weighting criteria from a weighting map 40 on this model 36 and determine the optimal function parameters 42 and make them available to the actual ECU functions 44 and keep updating. The optimization can also be calculated in the wake of the control unit.

An alternative is to calculate this method outside the control unit software and to transmit the settings to the test carrier via a tool or tool with an interface to the control unit. The results of the tuning are then available directly in the control unit or have to be transferred to the control unit after tuning via the tool.

A particular advantage is that the ECU software does not have to be changed. It should be noted, however, that different setups or regu- can not be implemented on the weightings. Furthermore, an additional tool must be available for the application and also for the customer.

Claims

claims

1 . Method for determining functional parameters (20, 42) for a control unit (22) which is provided for activating a technical system (10, 30), wherein at least one target variable predefines a system behavior and a variation of the functional parameters (20, 42) is carried out is carried out, wherein from an obtained response to the function parameters (20, 42) an evaluation of the adjusted function parameters (20, 42) is performed taking into account the at least one predetermined target size.

The method of claim 1, wherein the function parameters (20, 42) are varied directly on the system (10, 30) and the response is an answer of the system (10, 30).

3. The method of claim 1, wherein the function parameters (20, 42) via an intermediate model (32) are varied and the answer is an answer of the intermediate model (32).

4. Method according to one of claims 1 to 3, in which criteria are calculated from the response and a model (14, 36) of the system (10, 30) is formed from the calculated criteria and the at least one predetermined target variable.

5. The method according to any one of claims 1 to 4, wherein an optimizer (16, 38) is used.

The method of claim 5, wherein the optimizer (16, 38) accounts for evolution of the responses.

7. The method according to any one of claims 1 to 6, wherein a number of target variables are specified and the system behavior is given by a weighting of the target variables

8. The method according to any one of claims 1 to 7, which is executed within a control unit software.

9. The method according to any one of claims 1 to 7, which is executed outside of a control unit software.

10. Control unit having a computing unit on which functions are executed, wherein the control unit (22) is adapted to determine function parameters (20, 42) of the functions with a method according to one of claims 1 to 9.