DE4223253C2 - Control device for a vehicle - Google Patents

Description

The invention relates to a control device in a vehicle according to the preamble of claim 1.

Today's control devices for vehicles fulfill various Functions ranging from fuel metering to adjustment the air supply to the internal combustion engine or to control an auto matic transmission range. Within these basic tasks more modern Control devices for vehicles are activated by operating a Ver in different operating states of the vehicle various control functions (operating modes). For example, in connection with the control of the air supply for the engine, the setting of an influence on the air supply Actuator with a view to idling control, drive slip control, vehicle speed control and / or the control depending on the accelerator pedal (E-gas), etc. An engine control system according to the latter example is from Ver publication "Gerhard Kolberg, electronic engine control for Motor vehicles, MTZ Motortechnische Zeitschrift, 46th year, Booklet 4/1985 "known. All these control functions (operating modes) are used by a position controller for the control element  Influencing the performance of the internal combustion engine performed. Each The controller has different requirements depending on the control function with regard to its dynamics and accuracy. At for example, the accuracy of the reg is in idle control lers in the foreground, while a dynamic that is too great makes one restless Would mean idling and is therefore undesirable. With an arrival traction control, the accuracy of the control is secondary, while the dynamics of the control process are in the foreground. The before existing controller thus compromises between them different requirements.

From DE 40 09 640 C1 is an ASR / ABS system with hydraulic Multi-circuit brake system known, which is controlled by an electroni cal control device both traction control and anti blocking control is carried out.

DE 39 40 178 A1 is an actuator for a throttle valve to perform a traction slip and a driving speed speed regulation known.

From DE 39 39 292 A1 is a composite control system for the chassis Gelung and ABS / ASR control known in the different Control elements through different control strategies under common more coherent acquisition of measured values.

A digital controller with changeable operating parameters for on position of an actuator in different operating modes, where Different operating parameters are assigned to each operating mode are not known.

From DE-OS 33 46 436 is a device for idling speed known regulation, in which a digital PID controller is used. The controller output signal depends on the control deviation and their change from table values.

It is therefore an object of the invention to provide a control device for driving to provide evidence in which the various requirements for the Reg Depending on the control function, fin the.

This task is accomplished through the features of the patent spell 1 solved.

The procedure according to the invention leads to a control device for vehicles, the dynamics of the regulation or control processes are adapted to the respective operating state.  

This results in an improvement in the control behavior and thus an improvement of the respective control or regulation function.

It is also advantageous that an adjustment of the servomotor with large is carried out only in operating states which require this quick adjustment. This will make the servomotor spared, because adjustment speed and energy consumption only in one operating modes are at a high level.

This also leads to an increase in the life of the actuator Motor-connected potentiometers for position detection. Another Improvement can be seen in that, especially at idle regulation, a soft, precise adjustment of the control element enables light so that the quality of the idle control improves sert. This is associated with a soft adjustment of the Actuator reduced noise, so that another Improvement in the quality of the scheme is expected.

By determining the controller signals from tables a quick Program run with a simple program structure for a digi tal regulator achieved, which is advantageously a reduction means the effort for the control device.

A different one depending on the operating mode is also advantageous Specification of the controller parameters when calculating the controller output signal according to the given regulator equations.

Further advantages result from the following description of Embodiments as well as from the dependent claims.  

The invention is explained below with reference to the embodiments presented in the drawing Darge. In this case, 1, Fig. Is a block diagram of a control device for vehicles, while in Fig. 2 a flow chart is shown, which gas system E illustrates the erfindungsge Permitted procedure of an embodiment for a so-called.

Fig. 1 shows a control unit 10 consisting of an entrance 12, calculating section 14, storage area 16 and output area 18. The areas mentioned are connected to one another via a line system 20 for mutual data exchange. The input region 12 is linked via an input line 22 with a measuring device 24, which for detecting the position of the 26 connected to the measuring device, the driver-operable control element 28 of a mechanical manure Verbin, preferably an accelerator pedal, is used. Furthermore, the input area 12 is connected via input lines 30 to 32 to measuring devices 34 to 36 for detecting further operating variables of the drive unit of the vehicle and / or of the vehicle. The output region 18 of the control unit 10 is connected via an output line 38 to an adjusting device 40 for setting the air supply to the drive unit of the vehicle. Furthermore, the output area 18 of the control unit 10 is connected via further output lines 42 to devices (not shown) for controlling further adjusting elements, such as valves for fuel metering, devices for ignition adjustment, adjusting devices for an automatic transmission, adjusting elements for electronically actuatable clutches, etc., which is indicated by the dashed lines line 42 shown is symbolized.

In the preferred exemplary embodiment, the control device shown in FIG. 1 represents an electronic engine power control. In the case of such a control device, the following control functions or operating modes are generally provided. In driving mode, when the accelerator pedal 28 is actuated, a setpoint for the position of the actuating element of the adjusting device 40 influencing the air supply is formed in the computing area 14 at least as a function of the position of the accelerator pedal detected by the encoder 24 . This is used to form a control deviation with the position of the adjusting device 40 detected by one of the measuring devices 34 to 36 , the control deviation thus formed is converted by a digital control algorithm into a control signal which is sent via the output line 38 to adjust the adjusting device in the sense of an approximation of the actual position to the target position. In the described control loop, the controller is subject to average requirements with regard to speed and accuracy.

Furthermore, an operating mode can occur during driving, which is characterized by exceeding a predetermined slip of the drive wheels. In the arithmetic area 14 , by evaluating the wheel rotation speeds of the drive wheels detected by the measuring devices 34 to 36, it is determined whether an impermissible slip occurs on at least one of the drive wheels. In such a case, the position setpoint of the adjusting device 40 is manipulated in such a way that the slippage of the at least one drive wheel is reduced by reducing the power of the drive unit in such a way that a predetermined value is assumed. This requires the control loop shown above to respond very quickly (<100 ms) to the corresponding request to withdraw the adjusting device 40 . A comparable requirement arises in connection with an engine torque control, which leads to an opening of the adjusting device 14 in the event of inadmissible slip on at least one of the wheels as a result of the engine braking torque or during cornering. The response to such a requirement must also be very fast, especially if the appropriate corrections are used to improve the stability of driving behavior in curves. Accuracy is not in the foreground, a high degree of accuracy is not necessary (approx. 0.3 degrees is sufficient).

In the operating mode "vehicle speed control", the adjusting device 40 is controlled in such a way that the vehicle speed detected by one of the measuring devices 34 to 36 corresponds to a predetermined target value. This setpoint is specified in the known manner by the driver using a further control element. Since the setting of the desired driving speed must be very precise, the requirements for the controller are a very high accuracy and a moderate speed, so that the specified value can be adhered to very precisely without large control vibrations.

Comparable requirements are made for the idle speed control via the adjusting device 40 . Depending on operating variables such as battery voltage, engine temperature, engine speed, driving speed, gear position, etc., a setpoint for the position of the adjusting device is formed, which is set by the control circuit described above. To improve the quality of the idle control is the controller in this operating mode a very high accuracy (position accuracy in the range of 0.02 degrees) with moderate speed with small speed deviations and a very quick intervention in the event of sudden idling speed reduction z. B. by switching on the compressor of the air conditioning system ver so that the predetermined position for idle control can be maintained precisely and with soft adjustment. This significantly improves the quality of the idle control, in particular reduces noise.

In this context, further operating modes can be the setting of the adjusting device 40 in connection with a regulation of the gas composition, for regulating the position of the adjusting device 40 during gearbox interventions, for regulating the position of the adjusting device 40 for limiting the driving speed and / or speed, etc., etc. .

According to the invention, provision is now made for carrying out the respective Operating mode to provide a digital controller, which either based on specified control algorithms with proportional, in tegral and / or differential equations or based on Tables in which depending on the control deviation and the temporal change proportional, integral and / or differential portions of the controller output signal are read out, used. It is provided that to carry out the respective Operating modes of these controllers different, especially on the respective current operating mode adapted to meet the requirements de has values.

Reference to the flowchart of Fig. 2 of an electronic engine power control with the operating modes of driving, Antriebsschlupfregelungs- / engine drag torque regulation is operating at the embodiment, the vehicle speed control operation and idling operation, the regulation procedure of the invention illustrated.

The distinction between the individual operating modes is made on the basis of operating variables of the drive unit and / or the vehicle, which are detected by the measuring devices 34 to 36 and the measuring device 24 . Such distinctions are essentially known from the prior art.

After starting the program part under initialization and entering the start conditions, the operating variables of the drive unit or of the vehicle, which are intended for the evaluation after the following program steps, are read in in a first step 100. The values representing these operating values are either supplied directly by the respective measuring device or via a bus system, e.g. B. CAN supplied. The operating variables are the following variables: position of the accelerator pedal, position of the adjusting device 40 , vehicle speed, possibly idle switch, engine speed, number of wheel revolutions or ASR and / or MSR request signals, engine temperature, battery voltage, engaged gear stage , Status of an air conditioning system and similar consumers, etc., switching state of the control element for driving speed control, etc.

In the subsequent query step 102 , it is checked whether the idle operating state is present. This query is carried out on the basis of the position of the accelerator pedal or the adjusting device 40 , the switching state of an idle switch that may be present, the engine speed and / or the driving speed. If the accelerator pedal is released or the adjustment device is in its idle position and the engine speed and / or driving speed is below a predetermined value, the drive unit is in the idle state, whereupon proceeding to step 104 in the program part according to FIG. 2. There, a setpoint for the position of the adjusting device 40 is calculated on the basis of the input operating parameters such as engine speed, engine temperature, battery voltage, etc. and is related to the measured actual value to form a control deviation. In the subsequent step 106, finally, the table of the digital controller selected for regulating the idling speed is selected or the controller parameters fulfilling the requirements for the controller are read out, whereupon in subsequent step 108 by reading out the table values of the selected table as a function of the control deviation or its change or the controller output signal is calculated based on the selected parameters and the control deviation, a controller output signal is formed. The controller algorithm used can be a controller with a proportional, integral and / or differential component.

After determining or calculating the controller output signal, the subsequent step 110 a limitation in the sense of a limit of the actuating speed and / or the absolute adjustment of the Adjustment device or when the maximum speed is exceeded or the maximum speed and the program part repeated with step 100.

If it was recognized in query step 102 that the drive unit is not in idle mode, then in the subsequent query step 112 it is checked whether there is a request signal for a drive slip control and / or an engine torque drag control. If this is the case, in step 114, analogously to step 106, a setpoint value for the adjusting device 14 is formed from the request signal, which is related to the current actual position in order to form a control deviation, whereupon in step 116 the respective table is indicated by the corresponding table pointer value selected or the corresponding parameters are loaded. The controller output signal according to step 108 is formed on the basis of the tables or parameters selected in step 106 analogously to step 108, the limiting operation following step 110 also following step 108. After step 110 has ended, the program part is repeated with step 100.

If, according to step 112, there is no request signal, the Step 120 checks whether the drive unit or the vehicle is in the operating speed control mode. This will be in the  essentially based on the status indicator operated by the driver baren operating element for vehicle speed control determined. If the vehicle speed controller is switched on, then the Step 120 following step 122 the target position value on the ba sis the difference between the target speed and the actual speed speed calculated to form the control deviation from the actual position of the adjusting device in relation and in the following step 124, which is for driving speed control level table or the parameters of the digital controller selected. The calculation of the controller output signal according to step 126 corresponds according to steps 108 and 118 with those selected in step 124 parameters leads to the actuation of the adjustment device according to the given data. After step 110 for limitation, the Program part repeated here also starting with step 100.

If it is recognized in query step 120 that the system is not in the cruise control mode, the control device is in the driving mode. In this case, according to step 128, the target position value is formed on the basis of the driver request determined by the position of the control element and, if necessary, transformed via table values, related to the actual position value to form the control deviation, and in step 130 the table or table selected for this operating mode the selected parameters are determined. The calculation of the control output signal in step 132 results from the foregoing, whereupon the limitation takes place in step 110. The program part is then repeated with step 100.

In summary, it should be noted that when calculating the reg ler output signal after steps 108, 118, 126 and 132 necessary program always has the same scope. The different Chen dynamic values of the controller are achieved in that the Calculation of the controller output signal with the necessary program  different table pointer values is called, so that un different tables of the controller calculation are used. Thereby different dynamics can be achieved for the position controller the because the assignment of the control deviation or its changes to the controller output signal depending on the table regarding the requirements tion (LCR, ASRMSR, FGR, normal operation) are selected accordingly. In the preferred embodiment, the position is determined regulator over table values. It is also the adjustment device around a throttle valve of an internal combustion engine or the control rod of an injection pump.

The procedure according to the invention finds users everywhere where, with a single control loop with digital controller over a Actuator several operating modes with different requirements speed, accuracy, robustness, Stability, etc. of the controller or the control loop the.

It should be noted that in the description of the embodiment only speed and accuracy requirements were mentioned the. In other exemplary embodiments, however, other criteria can also be used teries are created, such as B. Robustness and stability of the Re gelkreises, which is to be set higher in an operating mode, or Transient response, etc.

Claims (6)

1. control device in a vehicle,

• - with an actuator,
• - With a controller for setting this control element in the context of a position control loop in various operating modes such as idle control, ASR control, vehicle speed control, E-gas control, with different requirements for the controller or control loop, characterized in that
• the controller is a digital controller with changeable operating parameter values, proportional, integral and / or differential factors or table values,
• - This controller in each operating mode adopts predetermined operating parameter values adapted to the respective operating mode for setting the control element in the respective operating mode.

2. Control device according to claim 1, there characterized in that the control loop is a control loop for location regulation of the air supply to an internal combustion engine send actuator. 3. Control device according to one of the preceding claims, there characterized in that the controller in tabular form depends on the control deviation and its change is specified. 4. Control device according to claim 3, there characterized in that depending on the operating mode different Tables are selected, their parameters according to the respective Requirements are selected. 5. Control device according to claim 1, there characterized in that in connection with the idle control ei ne high accuracy (in the range of 0.02 degrees) is required in Connection with the ASR / MSR control and the control of the vehicle low accuracy (approx. 0.3 degrees) is required.   6. Control device according to claim 1, there characterized in that in connection with the Driving speed control the speed of the control compared to the speed of the regulation during an ASR / MSR intervention is small.