DE3512473A1 - Method and device for the adjustment of throttle valves in motor vehicles - Google Patents

Abstract

The invention relates to a method and a device for the adjustment of the throttle valve position in motor vehicles as a function of the position of an accelerator pedal. The position of the accelerator pedal is converted into an electrical signal. This signal is used to calculate a corresponding adjustment position of the throttle valve and to bring the throttle valve into this adjustment position. The adjustment position is calculated by means of a digital computer, in order to increase the sensitivity of the movement of the throttle valve the greater the variations of the accelerator pedal position. This has the effect of suppressing jerky fluctuations of the vehicle speed in the event of only small variations of the accelerator pedal position, whilst in the event of large variations of the accelerator pedal position the throttle valve can follow this movement without significant delay and with great responsiveness. <IMAGE>

Description

TER SEA. MÜLLER · STEINMEISTER

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DESCRIPTION

The invention relates to a method for adjusting a motor vehicle throttle valve as a function of Changes in position of an accelerator pedal of the motor vehicle according to the preamble of claim 1.

The invention also relates to a correspondingly designed device for carrying out the method according to the preamble of claim 8.

To the amount of fuel supplied to an internal combustion engine to be able to adjust is adjustable within the intake duct of the internal combustion engine Throttle valve arranged. Usually this throttle valve is via a mechanical linkage or a other suitable mechanical device connected to an accelerator pedal in such a way that when the Accelerator pedal position, the throttle valve is also adjusted. To improve the throttle response to obtain when the accelerator pedal position changes, it has already been proposed that the mechanical connecting device between the throttle valve and the accelerator pedal should be carried out to replace an electrically controlled servo system. This system has a potentiometer that controls the movement of the accelerator pedal is converted into a corresponding electrical signal, which is further processed electrically and for controlling an electrical adjustment device to move the throttle valve to a new position

TER MEER MÜLLER STEINMEISTER '

that corresponds to the new position of the accelerator pedal. Moved by the electrically controlled servo system The throttle valve has a very high responsiveness to changes in the position of the accelerator pedal, so that practically the movement of the throttle valve follows that of the accelerator pedal directly. A delay between two movement sequences, such as those in a mechanical connection between the throttle valve and the accelerator pedal is obtained does not occur here. As a result, even small changes in the accelerator pedal position become jerky Changes in vehicle speed result, especially when one is using such a servo system equipped motor vehicle is controlled by an inexperienced driver. '

In order to avoid such sudden changes in vehicle speed, the output of the Potentiometer connected to a CR low-pass filter in order to adjust the delivered position signal of the accelerator pedal in a suitable manner Way to change. However, the low-pass filter causes the output from the potentiometer Accelerator pedal position signal is delayed. This signal is also delayed further within the electrically controlled servo system. This results in a delay in the movement of the throttle valve relative to the movement of the accelerator pedal. The response or reaction sensitivity of the throttle valve with a Change in the accelerator pedal position therefore decreases and is particularly noticeable when strong Changes in the position of the accelerator pedal when the required rapid acceleration or deceleration of the Motor vehicle.

The invention is based on the object of a method and a device for adjusting the throttle valve To develop motor vehicles so that jerky fluctuations with only small changes in position of the

TER MEER ■ MÜLLER · STEINMEISTER

Accelerator pedal can be avoided and the throttle valve can follow these changes immediately and without significant delay in the event of large changes in position of the accelerator pedal.
5

In terms of the method, the solution to the problem posed is specified in the characterizing part of claim 1.

On the device side, the solution can be found in the characterizing part of claim 8.

Advantageous further developments of the method and the device are set out in the respective subordinate claims specified.

According to the invention, when adjusting a motor vehicle throttle valve initially as a function of changes in position of an accelerator pedal of the motor vehicle generates an accelerator pedal position signal corresponding to the position of the accelerator pedal. From this accelerator pedal position signal a throttle valve setting value for adjusting the throttle valve is calculated. The calculation takes place with the help of a computer, such that the responsiveness of the throttle valve moved depending on the change in position of the accelerator pedal with increasing Change in position of the accelerator pedal increases. On the basis of the throttle valve setting value calculated in this way, brought the throttle valve to the new setting position.

The drawing shows exemplary embodiments of the invention.

TER MEER - MÜLLER STEINMEISTER

Fig. 1 is a block diagram of a throttle valve adjusting device according to a first embodiment of the invention,

Fig. 2 is a flow chart for explaining the

Operation of a digital present in the setting device according to FIG Computers,

Fig. 3 to 6 different from a read-only memory

values read out according to FIG. 1,

Fig. 7 is a block diagram for explaining a

Part of a stepper motor control circuit in Fig. 1,

Fig. 8 is a flow chart for explaining the

Operation of one provided in the stepper motor control circuit of FIG digital computers,

9 to 10 are diagrams for explaining the operation of the throttle valve adjusting device according to Fig. 1,

Fig. 11 is a flow chart for explaining a

changed operation of the digital computer within the throttle valve adjuster according to Fig. 1,

Fig. 12 is a representation of various and

step periods read out from the read-only memory according to FIG. 1,

Fig. 13 is a flow chart for explaining a

further modification of the operation of the digital computer in the throttle valve adjustment device according to Fig. 1,

Fig. 14 is a flow chart of a still further modified mode of operation of the digital Computer within the throttle valve adjusting device of Fig. 1,

TER MEER · MÖLLER · STEINMEISTER

15 is a block diagram of a throttle valve adjusting device according to a second embodiment of the invention,

Fig. 16 is a diagram for explaining the contents of a read-write

memory according to Fig. 15,

Fig. 17 is an explanatory diagram

selectable weighting factors for the operation of the device according to FIG. 15, Fig. 18 is a flow chart showing the operation of a digital computer in the device according to FIG. 15, FIG. 19 shows a representation of various throttle valve setting values from the read-only memory according to FIG. 15,

FIGS. 20a and 20b are graphs for explaining the mode of operation the throttle valve adjusting device according to FIG. 15 and FIG. 21 is a graphical representation for explanation Modified selectable weight factors for operating the throttle valve adjustment device according to Fig.

In FIG. 1, a throttle valve adjusting device is shown in a schematic manner shown according to the invention for a motor vehicle, with which the invention Procedure can be carried out. The throttle valve adjusting device of FIG. 1 includes an accelerator pedal position sensor 10 and a throttle position sensor 12. The accelerator pedal position sensor 10 provides an analog signal Vl corresponding to the position of an accelerator pedal 1 when this is depressed. On the other hand, he delivers Throttle valve position sensor 12 an analog signal V2, which depends on the opening angle of a throttle valve 2.

TER MEER · MÜLLER · STEINMEISTER

The throttle position sensor 10 includes a potentiometer that is connected between a voltage source Vcc and a ground connection. The resistance of the potentiometer depends on how far the accelerator pedal 1 is depressed has been. The sliding contact arm of the Potentio-. meters is connected to the accelerator pedal 1, so that the Resistance value of the potentiometer is changeable, depending on whether the accelerator pedal 1 is completely released, depressed is or is in an intermediate position. The throttle position sensor 12 is similar to that Accelerator pedal position sensor 10 constructed and also has a potentiometer whose sliding contact arm with the Throttle valve 2 is connected, so that the resistance value of the potentiometer according to the position of the Throttle valve 2, which can be fully open or closed, is changeable.

The throttle valve 2 is via a mechanical lever device with an electrically controlled stepper motor 14 connected by adjusting the throttle valve 2 is made in order to be able to supply a certain amount of air to the engine in this way.

The sensor signals Vl and V2 are fed to a control circuit 20, which makes the required new setting of the Throttle valve determined at a certain time or the change in the throttle valve position. For this it defines the direction in which the stepper motor 14 must rotate, how large the period should be, in which the stepping motor 14 rotates by one step, and how high the number of times to be executed by the stepping motor 14 Steps must be. The control circuit 20 gives the information about the required new setting position in the form of binary coded signals, which first reach a stepper motor control circuit 3 0. The actual setting of the throttle valve 2 is then carried out with the aid of the stepper motor 14 and one assigned to it

TER MEER · MÜLLER ■ STEINMEISTER

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Stepper motor drive circuit 40 made with the stepping motor control circuit 30 is connected. The stepper motor control circuit 30 converts the binary Coded setting information for the throttle valve in a number of pulses with a predetermined period, with the help of which the throttle valve in the required new Setting position is moved. The stepper motor control circuit 30 generates an electronic one for this purpose Control signal with the predetermined period, and supplies it to the stepping motor drive circuit 40. This drives the stepping motor to take one step at a time every predetermined period to change the position of the throttle valve 2 in this way.

The control circuit 20 (digital computer) has a central processing unit 22 (CPU), an analog-to-digital converter 21 (ADC), a read-only memory 23 (ROM) and a read / write memory 24 (RAM). The CPU 22 is with the other units of the microcomputer 20 are connected via a data line 25. The analog / digital converter 21 receives at its input the voltage signals Vl and V2, which are from the accelerator pedal position sensor 10 and from the throttle valve position sensor 12 can be delivered. The analog / digital conversion starts after receiving a command signal the CPU 22, which controls the input channel for the purpose of converting the received analog signals into digital signals. To Once the analog / digital conversion of the input signals has taken place, the analog / digital converter 21 generates an interrupt signal so that the digital Signals are fed to the data bus 25 on command of the CPU 22.

The operating program for the CPU 22 and other suitable data for calculation are in the read-only memory 23 (ROM) of position values of the throttle valve 2 are stored in so-called look-up tables. The data or lookup data can be determined experimentally or empirically

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will. The CPU 22 can be programmed to be able to interpolate between the data to carry out different deployment points, if this is desired. Control signals or blocks that have a Specify the required throttle position are periodically switched to the stepper motor control circuit by the CPU 22 3 0 transferred.

In Fig. 2 is a flow chart of a program is shown, according to which the microcomputer 20 in Fig. 1 operates. The program starts with step 2 02. In step 2 04 the accelerator pedal position signal Vl and the throttle valve position signal V2, which are initially in analog Form present, converted into a digital form with the aid of the analog / digital converter 21. In the following Step 2 06 the converted signals are normalized in order to obtain corresponding signal values VIR and V2R which lie within a predetermined range, for example within the range from 0 to 255. The normalized Values VIR and V2R are then read into memory 24 (RAM).

In step 2 08, a required new setting or setting position VISET for the throttle valve 2 is also included Calculated using the central processor unit 22, based on a certain relationship that is in the computer is stored. This relationship shown in FIG. 3 represents the dependency of the new throttle valve setting position VlSET as a function of the normalized accelerator pedal position VlR. In step 210 the increase is VIDIF the new throttle valve setting position VlSET compared to the old throttle valve setting position VlSETaIt calculated. The calculated increase VIDIF indirectly indicates a change in position of the accelerator pedal 1 when this is depressed will. The same result with regard to the increase VIDIF can therefore also be obtained when the Difference between the new accelerator pedal position VlR and

TER sea ■ Müller. stone master

the old accelerator pedal position VlRaIt is determined.

In the following program step 212, the central processor unit 2 2 calculates the difference VER between the actual throttle position V2R and the required new throttle position VlSET. That The sign of the difference VER obtained in this way is positive if the required new throttle valve position VlSET greater than the throttle valve just detected

■ j ^ g position V2R is, and negative if the required new throttle valve position VISET is smaller than the just detected throttle valve position V2R. In step 214, the direction of rotation of the stepping motor 14 is determined, based on the sign of the calculated

"L5 difference VER. Has the difference VER a positive one Sign, the stepping motor 14 is rotated in such a direction that the throttle valve 2 opens. On the other hand, it is turned in the opposite direction to close the throttle valve if the sign the calculated difference VER is negative. In the program step 216, a period PER is determined in which the stepping motor 14 is during the execution of a step turns. This period PER is with the help of the central processor unit 2 2 based on another within the The computer's existing relationship is calculated, which is shown in FIG. It sets the period PER of the stepping motor rotation as a function of the absolute value of the calculated increase VIDIF. As shown in FIG. 4, the Period of the stepping motor rotation essentially linearly with the increase in the absolute value VIDIF. That means, that the period of the stepping motor rotation also decreases when the change with which the accelerator pedal 1 is depressed or is released increases. The calculated period of rotation PER therefore determines the throttle valve movement depending on the change in the accelerator pedal position. To a change in position of the accelerator pedal The central office can therefore obtain an exact signal

TER MEER · MÜLLER ■ STEINMEISTER

Processor unit 2 2 the rotation period PER on the basis of the relationship shown in Fig. 4, which the dependency represents the rotation period PER from the calculated absolute value VIDIF, and based on the absolute value of the calculated Calculate the difference VER as shown in FIG.

In step 218, the central processing unit 22 calculates the number of steps the stepper motor takes in each Cycle in the execution of this program must be carried out, based on a further stored in the computer and the relationship shown in FIG. This relationship represents the relationship between the number of steps and the STEP Represents the absolute value of the calculated difference VER. As shown in Fig. 6, the calculated step number STEP increases with increasing absolute value of the calculated difference VER. The stepping motor 14 must therefore be increased in number of turning steps when the position change of the accelerator pedal 1 when depressed or released increases.

In step 220, the central processor unit 22 issues an interrupt command βi and delivers the calculated one Values relating to the direction of rotation, the number of steps STEP and the period of rotation PER via the data line 25 to the stepping motor control circuit 30 at the end of a period TO of an execution cycle of the computer program. The stepping motor control circuit 3 0 then controls the stepping motor drive circuit 40 to

2Q change the position of throttle valve 2 in this way to be able to do so if necessary. In program step 2 22 the program jumps back to step 2 02 so that the next program cycle of the computer program can be run through.

In Fig. 7, the stepper motor control circuit 30 is shown in detail. It contains a central Processor unit 3 2, a ^ i interrupt generator 31,

TER MEER - MÖLLER. STEINMEISTER

a step counter 33, a read only memory 34 (ROM), a read / write memory 35 (RAM) and an output circuit 36. The CPU 32 is connected to the remaining circuits via a data line 37. The stepper motor control circuit 30 can for example contain a μΡϋ 6801 microcomputer.

The CPU 32 stores the data supplied from the control circuit 20 via the data line 25 in the memory

^ q 35 (RAM). The Oti interrupt generator 31 includes a Output shift register into which the calculated period PER is entered, a free-running counter that is stored in constant time intervals is gradually increased, and a comparison circuit that generates a <^ i interrupt signal returns when the count value of the free-running counter matches the value in the output shift register achieved. The c ^ i interrupt signal is therefore shown in Generated time intervals that coincide with the calculated period PER. In step C33 is the calculated Number of steps saved. He reduces the number of steps by one step each time he takes a corresponding one Command signal is received from the CPU 32. In the memory 34 (ROM) are an operating program for the CPU 3 2 and others suitable data is stored in so-called look-up tables, which are used to generate suitable bit patterns for the Position of the throttle valve 2 can be used. The output circuit 36 converts these bit patterns into corresponding ones Pulse signals around.

Referring to Figure 8, there is shown a flow chart of a program to be used by the microcomputer in the stepping motor control circuit 3 0 works. This program begins with step 3 02. In the following program step 3 04 the computer waits for either a cCi interrupt signal or to receive a ßi interrupt signal. It should be pointed out again that the CXi interrupt signal occurs at time intervals that

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coincide with the calculated period PER, while the ßi interrupt signal occurs at time intervals, those with the period TO of a cycle in the execution of the program belonging to the control circuit 20 central processor unit 22 match. In program step 306 it is determined whether the ßi interrupt signal ■ has been received. If the answer is positive, the program goes to step 3 08, in which the central Processor unit 3 2 stores the information about the throttle valve positioning, that is to say the values relating to the Direction of rotation, the period and the number of steps that have been transmitted to it by the control circuit 20. These Values are stored in memory 35 (RAM). The step number value STEP is entered in the step counter 33, while the period PER is loaded into the output shift register of the cCi interrupt generator 31. in the subsequent step 310, the computer program jumps back to the initial step 302 to respond to the next J ^ i interrupt signal or wait for ßi interrupt signal.

If the answer in step 306 is negative, the program then reaches step 312, in which the question is asked whether the ^ i interrupt signal has been received is. If this answer is negative, the program goes to

₂ c following step 314 and then likewise back to output step 3 02 in order to again await the receipt of a Chi or ßi interrupt signal.

If, on the other hand, the answer is positive in step 312, was 2Q received a cCi interrupt signal, so achieved the program then step 316, in which the central processing unit 3 2 an interrupt control flag puts. A required bit pattern is then determined in step. This is done through Searching for a bit pattern based on the throttle valve setting information, which has been transmitted from the control circuit 20.

TER MEER · MÜLLER · STEINMEISTER

In the subsequent step 3 20, the central processor unit 3 2 resets the free-running counter of the ^ i interrupt generator 31 to zero or clears it while it decreases the step counter 33 by one step. In program step 322, the determined bit pattern is transmitted to the output circuit 36, in which it is converted into corresponding pulse signals. The program then reaches step 324 and then jumps back again to the initial step 322 in order to wait for the next (^ i or IQ ßi interrupt signal.

The pulse signal is transmitted from the output circuit 36 to the stepping motor drive circuit 40, so that this the Stepper motor 14 can be set in rotation, in order to in this way the throttle valve 2 in the required new Bring setting position.

As shown in FIGS. 9 and 10, the stepping motor 14 performs a calculated step STEP in each case Period or time that corresponds to the calculated PER period. Like a comparison of those in FIG. 9 13 and 10 immediately shows, the calculated period PER is greater and the calculated number of steps STEP smaller, so that the stepper motor 14 moves over a smaller angle and at a slower speed rotates when the position of the accelerator pedal is changed only slowly and little, as opposed to a fast one and large change in accelerator pedal position. This means that the throttle valve 2 at slower and lower Change of the accelerator pedal position also only moves slowly or with a lower response rate to avoid unnecessary Avoid changes in vehicle speed. On the other hand, the throttle valve 2 moves at high speed or high response rate if the position of the accelerator pedal changes rapidly and to a considerable extent so that the machine can react quickly to desired accelerations or decelerations.

TER MEER · MÜLLER. STEINMEISTER

. drv Figure 11 is a n.iohfol ijtMui nio "lifi :: i ei I t>: i described flow chart for control of the microcomputer within the control circuit 20. This program corresponds essentially to that according to FIG. 2. However, the stepping motor rotation or rotation period PER is now calculated differently in order to obtain a high responsiveness of the throttle valve movement when the accelerator pedal position is changed rapidly.

IQ The computer program according to FIG. 11 begins with step 502. In the subsequent step 504, the accelerator pedal position signal Vl and the throttle valve position signal become V2 is read in or recorded simultaneously or one after the other and converted to digital with the aid of the analog / digital converter 21 Signals converted. The digital signals obtained in this way are normalized in the subsequent program step 5 06, so that respective signal values VIR and V2R which are within a predetermined range are obtained. These normalized signal values VIR and V2R are stored in memory 24 (RAM). In program step 5 08 the central processor unit 2 2 calculates the required new setting position VISET of the throttle valve 2 with the aid a relationship as it has already been explained with reference to FIG. There is the new throttle position VlSET plotted as a function of the normalized accelerator pedal position VlR.

In program step 510, the central processor unit 2 2 calculates the difference VER between the actual one Throttle valve position V2R and the required new throttle valve position VlSET of the throttle valve 2. Das The sign of the calculated difference VER is positive if the required new throttle valve setting position VlSET is greater than the instantaneous or current throttle valve position V2R. The sign is against it negative if the new throttle valve setting position VISET is less than the current one. In step 512

TER MEER ■ MÜLLER · STEINMEISTER

the direction in which the stepper motor 14 is to rotate based on the sign of the calculated difference VER established. The stepping motor 14 rotates with a positive sign of the calculated difference VER in one direction to open the throttle while moving in the opposite direction to close it the throttle valve rotates when the sign of the calculated difference is negative.

- ^ q In the following program step 514, the central Processor unit 22 the period PER, which corresponds to the period or time in which the stepping motor 14 turned one step further. The period PER is determined from a relationship shown in FIG is. There the stepping motor rotation or rotation period PER is a function of the absolute value of the calculated difference VER applied. As can be seen from this Fig. 12, the stepping motor rotational period increases substantially linearly with increasing absolute value of the calculated difference VER. The calculated period of rotation PER determines the response behavior the throttle valve movement when the position of the accelerator pedal changes.

In step 516, the central processing unit 2 2 determines the number of steps that the stepper motor takes within of the period TO when executing the program. This number of steps is STEP with the help of the relationship shown in Fig. 6 is set. There the number of steps is STEP as a function of the absolute value of the calculated difference VER shown. As can be easily seen, the calculated step count takes STEP as Function of this absolute value VER to. This means that the stepping motor 14 has an increased number of steps must perform if sieve when depressing or free-5 let the accelerator pedal 1 change the corresponding accelerator pedal position elevated.

TER MEER · MÜLLER ■ STEINMEISTER

In the program step. 518 delivers "the central pro-oasoiv unit 2 2 a ßi interruption signal and transmits the calculated values relating to the direction of rotation of the stepper motor, the number of steps STEP and the rotation period PER via the data line 25 to the stepper motor control circuit 30, and that in each case at the end of a period TO of a cycle when the computer program is being carried out. The stepper motor control circuit 30 in turn controls the stepping motor drive circuit 40 so that the position of the IQ throttle valve 2 is changed in the desired manner. After running through program step 520, this again reaches starting point 502, so that a next Program cycle can be started.

"L5 Another program for operating the digital computer in the throttle valve control apparatus is shown in FIG. The computer program begins with the step 602. In the following step 604, the accelerator pedal position signal Vl is converted into a digital signal. The signal value of the accelerator pedal position converted in this way is then scanned in step 606.

In program step 6 08 the central processor unit 2 2 calculates the difference between the new and the old sample of accelerator pedal position. The direction of rotation of the stepping motor 14 is then set in step 610 determined, based on the sign of the difference calculated in step 6 08. Is the new sample larger than the old one, the stepper motor 14 rotates in one direction to open the throttle valve. Against it turns he is going to close the throttle in the opposite direction if the new sample is less than is the old sample.

In step 612, the central processing unit 2 2 calculates the number of steps that the stepper motor takes during the must execute the program cycle mentioned. This number of steps is determined with the help of a relationship that is in the computer

BATH

TER MEER - MÜLLER STEINMEISTER

is stored. The relationship gives the required number of steps as a function of the absolute value of the calculated Difference between the samples. The calculated number of steps increases when the absolute value the said calculated difference increases. It follows that the stepping motor 14 has an increased number of • Steps when the change in accelerator position increases.

In program step 614, the central processor unit determines 2 2 the required step period that corresponds to the period or time in which the stepping motor 14 rotates one step further. This period is also based on a stored in the computer Relationship preserved. This relationship gives the dependence of the stepper motor rotation or rotation period as a function of the absolute value of the above calculated difference between the samples. The stepping motor rotation period increases with increasing Absolute value of the calculated difference. This means that the stepping motor rotation period decreases as the Change in position of the accelerator pedal increased.

In program step 616, the central processor unit 2 2 delivers a ßi interrupt signal and transmits the calculated values relating to the direction of rotation, the number of steps and the step period via the data line 25 to the stepper motor control circuit 30 at the end of the cycle period TO when the computer program is being executed. The stepping motor control circuit 30 then controls the stepping motor drive circuit 40, so that the position of the throttle valve 2 is changed as desired. After going through the step 618 the program returns to the initial step 6 02 so that a next program cycle is run through can.

TER MEER - MÜLLER STEINMEISTER

351247J

Fig. 14 shows a flow chart for the modified one Operation of the digital computer within the throttle control device of Figure 1. The computer program begins with step 6 22. Subsequently, in step 6 24, the accelerator pedal position signal Vl and the Throttle position signal V2 converted separately into digital signals. Thereupon the step 626 the required new throttle valve setting position with the help of the central processing unit 2 2 calculated based on a relationship stored in the computer. This relationship represents the dependency of the the new throttle valve setting position as a function of the accelerator pedal position Vl.

In step 628 the central processor unit 2 2 calculates the difference between the new throttle valve setting position and the current or current position of the throttle valve 2. Thereafter, in step 630, the The direction of rotation of the stepping motor 14 is determined based on the sign of the difference calculated in this way. Of the Stepping motor 14 rotates in a direction to open the throttle valve 2 when the set value of new throttle position is greater than that of the old or current throttle position.

Correspondingly, the stepping motor 14 rotates in the opposite direction to the closing of the throttle valve, if the setting value of the new throttle valve position is less than that of the current throttle valve position is.

In program step 632, the central processing unit calculates 2 2 the required number of steps, which the stepping motor 14 within the executed program cycle must perform. This number of steps is also determined with the help of a relationship that is in the computer is stored. This relationship gives the required number of steps as a function of the absolute value of the calculated Difference. The calculated number of steps increases

TER MEER - MÜLLER STEINMEISTER

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with an increasing absolute value of the calculated difference between the throttle valve setting position values. That means that the stepping motor 14 must perform an increased number of rotary steps when the change occurs the accelerator pedal position increased.

In the following program step 634, the central processor unit 2 2 determines the required step period or step duration that corresponds to the period or time in which the stepper motor is 14 rotated one step further. The said step period is also stored in the computer with the help of a Relationship determined that the dependency of the stepper motor rotation or rotation period as a function represents the absolute value of the calculated difference. The stepping motor rotation period increases with increasing Absolute value of the calculated difference. As a result, the time to carry out a turning step of the stepping motor decreases with increasing change in the accelerator pedal position. The step size remains the same.

In program step 6 36 the central processor unit 2 2 delivers a ßi interrupt signal and transmits the calculated values with regard to the direction or direction of rotation, the number of steps and the step period the data line 25 to the stepper motor control circuit 30, namely at the end of the cycle period TO in execution of the computer program. The stepper motor control circuit 30 then controls the stepper motor drive circuit 40 so that in this way the position of the throttle valve 2 is changed as desired. To Passing through step 638, the program returns to the initial step 6 22, so that a new program cycle can be carried out.

TER MEER · MÜLLER · STEINMEISTER

15 shows a further control device according to the invention. Same elements as in Fig. 1 are provided with the same reference numerals.

According to FIG. 15, the control device has a control circuit 50 which receives sensor signals V1 and V2 and a new setting position for the throttle valve 2 is determined in certain or predetermined time intervals. the Control circuit 50 supplies the required new digit information in the form of binary digit signals or binary encoded signals to a stepper motor control circuit 60 which converts the binary encoded signals into a number of pulses in order to bring the throttle valve 2 into the desired new setting position with their help.

The control circuit 50 includes a digital computer with a central processing unit 52 (CPU), a Analog / digital converter 51 (ADC), a read-only memory 53 (ROM) and a write-Z-read memory 54 (RAM).

The analog / digital converter 51 receives voltage signals Vl and V2 at its input, of which the signal Vl from the accelerator pedal position sensor 10 and the signal V2 from the throttle position sensor 12. the Signal conversion with the aid of the analog / digital converter 51 takes place under the control of the CPU 52, which controls the corresponding Activates or opens the input channel for signal conversion.

The operating program for the CPU 52 and other suitable data are in the memory 53 (ROM) Look-up tables stored, which are used to determine a required position of the throttle valve 2 will. The data stored in the so-called look-up tables or assigned memory areas can can be determined experimentally or empirically. In addition, there is another table in the memory 53 (ROM) as shown in FIG. the end

TER MEER · MÖLLER ■ STEINMEISTER

From this table, the CPU 22 optionally reads desired weight factors, depending on the change in the accelerator pedal position. A memory area having addresses Ao to An is provided in the memory 54 (RAM) as shown in FIG. Under these addresses n + 1 values of the accelerator pedal position Vl are stored, which in sequence in very can be read out at short time intervals. The CPU 52 shifts the old values Vltl to Vltn one at a time higher address and deletes the oldest value Vltn + 1 every time it reads out a new value Vlto. The new value Vlto is then stored under the lowest address Ao. The CPU 52 can be programmed that it can interpolate between data that is available at different start or entry points, if so desired. Control signals or groups of control signals for specifying the desired throttle valve positions can be periodically transmitted to the stepper motor control circuit 60 using the CPU 52.

18 is a flow chart for explaining the Operation of the computer within the control circuit 5 is shown. The computer program starts with step 702 at very short time intervals · In the following step 704, the accelerator pedal position signals Vl and the throttle valve position signal V2 in each case by itself with the aid of the analog / digital converter 51 into digital Signals converted.

In program step 706, the central processor unit 52 shifts the old values Vltl to Vltn one at a time Address further up and clears the oldest value Vltn + 1, as shown in FIG. In step 7 08 the converted new value Vlto is stored at the lowest address Ao. Then in step 710 the Absolute value DiFSP of the increase in the new value Vlto compared to the last value Vltl determined. Who is so

TER MEER · MÜLLER · STEINMEISTER

The calculated absolute value DiFSP corresponds to the change in the movement of the accelerator pedal 1. The stated values Vlto bis Vltn + 1 represent position values of the accelerator pedal, for example at different times to to tn + 1.

In program step 712, the central processing unit 52 selects one of three weight factor sets No. 1, No. 2 or No. 3, depending on how great the absolute value DiPSP of the difference between the new value Vlto and the last value is VItX. For example, the head office chooses Processor unit 5 2 weight factor set No. 1 to add the weight factor WO for the new value Vlto 1/2 and the weight factor Wl for the last value Vltl also set to 1/2 if the calculated The absolute value DiSFP is larger than zero and smaller than a lower reference value DiFSP 2, as in FIG. 17 shown. The central processor unit 52, on the other hand, selects the weight factor set No. 2 to set the weight factor Wo for the new value Vlto to 3/4 and the Weight factor Wl for the last value Vltl to be set to 1/4 if the calculated absolute value DiSFP is greater than the lower reference value DiFSP2 and smaller than a higher reference value DiFSPl. Corresponding the central processing unit selects the weight factor set No. 3 out to get the weight factor where for the new Set the value Vlto to 7/8 and the weight factor Wl for the last value Vltl to 1/8 if the calculated The absolute value DiFSP is greater than the higher reference value DiSFPl. As can be seen in Fig. 17, 0, the new value Vlto is weighted higher than the last value Vltl if the absolute value DiFSP or the change the accelerator pedal position increases per unit of time. It should be noted that the weighting of the Accelerator pedal position values can also be made in other ways. For example, Fig. 21 shows various Weight factor sets with which successively read accelerator pedal position values are higher than the last values

TER MEER MÜLLER STEINMEISTER ... -

-31-weighted, the larger the absolute value DiFSP becomes.

In step 714, the central processor unit 52 calculates the weighted mean value Vltyp of the values read out Accelerator pedal position values Vltl and Vlto to:

Vityp = Vlto χ Wo + Vltl χ Wl.

Subsequently, in step 716, the new setting position Vopt of the throttle valve 2 is set with the help of the central Processor unit 5 2 and calculated on the basis of a relationship that is stored or stored in the computer. programmed. This relationship determines the dependency of the new throttle valve setting position Vopt of the weighted average value VItyp, as shown in FIG. Calculated in the following program step 718 the central processor unit 5 2 then an increase VERR compared to the new throttle valve setting position Vopt the current or old throttle valve setting position V2. This calculated increase VERR becomes 20 in step 7 output by the central processor unit 5 2 in the form of a binary number, which is sent to the stepper motor control circuit 60 is forwarded. With the aid of the stepping motor control circuit 60, the via the data line 55 binary number received by the computer corresponding to the increase VERR converted into a number of pulses, with the help of which the throttle valve 2 is brought into the new required position. After going through of program step 722 in FIG. 18, the program returns to initial step 702, so that a new Program cycle can be started. The pulse signal or the signal pulses arrive from the stepper motor control circuit 6 0 to the stepping motor drive circuit 40, which in turn uses the stepping motor 14 for adjustment the throttle valve 2 is rotated into the new setting position.

TER MEER · MÜLLER · STEINMEISTER

If the change in the position Vl of the accelerator pedal 1 is less than a predetermined value, the last and the new value Vltl and Vlto, the respective positions of the accelerator pedal 1 are assigned, weighted in the same way, the weighting process proceeding in exactly the same way, as has already been explained in connection with step 712 of the flow chart according to FIG. In In this case, the change is AVIAV of the weighted mean value VlAV of the accelerator pedal position values Vltl and Vlto less than the change Avi of the accelerator pedal positions Vl, as shown in Fig. 20a. This means that the throttle valve 2 is low in responsiveness is moved in accordance with a small change in the accelerator pedal position to avoid unnecessary changes in the speed of the Motor vehicle with only slight changes in the accelerator pedal position to avoid.

The rate at which the weighted mean value VlAV of the accelerator pedal position values Vltl and Vlto changes increases & ⁿ f as the change in the accelerator pedal position increases.

When the accelerator pedal position changes to a large extent to make rapid acceleration or deceleration, the weighted mean value of the accelerator pedal position values also changes to a large extent or high sensitivity depending on the change in the position of the accelerator pedal, as shown in Figure 20b. This means that the throttle valve 2 is running at high speed or high responsiveness to large changes in the pedal position. The dash-dotted line in Fig. 20b relates to a control device in which an analog low-pass filter at the output of the Accelerator pedal position sensor 10 is arranged. As can be easily seen, the response time is in the control device according to the invention by the time t shorter than in the said control device with the analog low-pass filter.

TER SEA. MÜLLER ■ STEINMEISTER

3b12473

With the method and the device according to the invention it is thus achieved that the ability to claim with respect to the movement of the throttle valve when the position changes of the accelerator pedal becomes larger, the larger the position changes of the accelerator pedal. That means that through the invention undesired. fluctuations in the. vehicle speed suppressed v / earth that would otherwise occur with only slight changes in the accelerator pedal position and the like Movement or adjustment of the throttle valve occurred. Rather, the throttle follows the Movement of the accelerator pedal so that it reacts faster and more fully to changes in accelerator pedal position reacts, the larger they are.

L e r s e i I e

Claims (12)

3512473 TER MEER-MÜLLER-STEINMEISTER PATENTANWÄLTE-EUROPEAN PATENT ATTORNEYS Dipl.-Chem. Dr. N. ter Meer Dipl. Ing. H. Steinmeister 43
D-8000 MUNICH 80 D-4800 BIELEFELD 1 WG84316 / 257 (2) / TK April 4, 1985 Mü / tM / Ur / b NISSAN MOTOR COMPANY, LIMITED 2, Takara-cho, Kanagawa-ku, Yokohama-shi, Kanagawa-ken, Japan Method and device for throttle valve adjustment in motor vehicles Priority: April 5, 1984, Japan, Ser.No. 59-68031 (P) April 5, 1984 to Japan, Ser.No. 59-68032 (P) PATENT CLAIMS /Ί.JProcedure for setting a motor vehicle throttle ^ fold one depending on changes in position Accelerator pedal of the motor vehicle, characterized in that - an accelerator pedal position signal corresponding to the position of the accelerator pedal (1) is generated, - A throttle valve setting value from the accelerator pedal position signal for setting the throttle valve (2) is calculated, - The calculation with the aid of a computer (20, 50) is carried out in such a way that the sensitivity of the depending on the change in position of the accelerator pedal TER MEER · MÖLLER · STEINMEISTER 351 -2- moved throttle valve (2) increases with increasing change in position of the accelerator pedal (1) and - the throttle valve (2) is brought into the calculated setting position. 2. The method according to claim 1, characterized in that the Calculation of the throttle valve setting value as follows Steps include: - Measurement of the change in position of the accelerator pedal (1), - Calculation of a number of steps (STEP) from the measured change in position of the accelerator pedal, such that the The number of steps increases as the position changes, and - Calculation of a step period (PER) from the measured change in position of the accelerator pedal, such as that the step period decreases with increasing change in position, and that - the throttle valve (2) step by step according to the number of calculated steps and over each calculated step periods is moved. 3. The method according to claim 1, characterized in that the calculation of the throttle valve setting value is as follows Steps include: - Sampling of the accelerator pedal position signal (Vl) at predetermined times (to, ti, ..., tn + 1), - Calculation of the difference (DiPSP) between a new one (Vlto) and an old (Vltl) sample of the accelerator pedal position signal (Vl), - Calculation of a number of steps (STEP) from the calculated difference in such a way that the number of steps increases with increasing Difference increased, and - Calculation of a step period (PER) from the calculated difference in such a way that the step period TER MEER · MÜLLER · STEINMEISTER decreased with increasing difference, and that - the throttle valve (2) step by step according to the number of steps and over the respectively calculated Step periods is moved. 4. The method according to claim 1, characterized in that the calculation of the throttle valve setting value is as follows Steps include: - Calculation of a setting position (VlSET) for the throttle valve (2) on the basis of the accelerator pedal position signal (Vl), - Measurement of the current setting position of the throttle valve (2), - Calculation of a difference (VER) between the calculated and the current setting position of the Throttle valve (2), - Calculation of a number of steps (STEP) from the calculated difference (VER), such that the number of steps increases with increasing difference (VER), and - Calculation of a step period (PER) from the calculated difference (VER), such that the step period with increasing difference (VER) becomes smaller, and that - the throttle valve (2) step by step according to the number of calculated steps and over each calculated step periods is moved. 5. The method according to claim 1, characterized in that the calculation of the throttle valve setting value is as follows Steps include: - Sampling of the accelerator pedal position signal (Vl) at predetermined times (to, ti, ..., tn + 1), - Calculation of a setting position for the throttle valve (2) at the predetermined times on the Basis of a sample of the accelerator pedal position TER SEA. MÜLLER ■ STEINMEISTER - 4- signals, - Calculation of a first difference between new and old setting positions, - Measurement of the current actual setting position the throttle valve (2), - Calculation of a second difference between the calculated setting position and the measured actual one Setting position, - Calculation of a number of steps from the calculated second difference in such a way that the number of steps increases with increasing second difference, and - Calculation of a step period from the first calculated difference in such a way that the step period decreases with increasing first difference, and that - the throttle valve- (2) step by step according to the number of steps and over the calculated in each case Step periods is moved. 6. The method according to claim 1, characterized in that the calculation of the throttle valve setting value is as follows Steps include: - Sampling of the accelerator pedal position signal (Vl) at predetermined times (to, ti, ..., tn + 1), - Calculation of a setting position for the throttle valve (2) at the predetermined times on the Based on a sample of the accelerator pedal position signal, - Calculation of a first difference between new and old setting positions, - Measurement of the current actual setting position of the throttle valve (2), - Calculation of a second difference between the calculated setting position and the measured actual one Setting position, - Calculation of a number of steps from the calculated second TER MEER - MÖLLER ■ STEINMEISTER Difference, such that the number of steps increases as the second difference increases, and - calculating a step period as a function of the calculated first and second differences, and that - the throttle valve (2) step by step according to the number of steps and over the respectively calculated Step periods is moved. 7. The method according to claim 1, characterized in that the calculation of the throttle valve setting angle is as follows Steps include: - Sampling of the accelerator pedal position signal (Vl) at predetermined times (to, ti, ..., tn + 1), - Calculation of a difference between new and old samples of the accelerator pedal position signal, - Determination of weight factors (Wo, Wl, ...) for the new and old samples in such a way that the weighting factors for the new samples are greater than for the old samples are, when the difference between the samples increases, - Calculation of a weighted mean value from the weighted new and old samples and - Calculation of a throttle valve setting value based on the calculated weighted average, such that the throttle valve setting value increases as the weighted mean value increases. 8. Device for setting a motor vehicle throttle valve as a function of changes in position of an accelerator pedal of the motor vehicle,
marked by - A signal source (10) for generating an accelerator pedal position signal (Vl), - A control circuit (20, 50) for calculating a Throttle valve setting position depending on the TER MEER · MÜLLER ■ STEINMEISTER -6- Accelerator pedal position signal (Vl), the means for increasing the sensitivity of the throttle valve, which is moved depending on the change in position of the accelerator pedal (2) with increasing change in position of the accelerator pedal (1) contains / and through - A drive control device connected to the control circuit (20, 50) (30 or 60, 40, 14) for guiding the throttle valve (2) into the throttle valve setting position. 9. Apparatus according to claim 8, characterized in that the control circuit - means for measuring the change in position of the accelerator pedal, - Means for calculating a number of steps (STEP) from the measured gas pedal position change, such that the number of steps increases as the accelerator pedal position changes, and - Means for calculating a step period (PER) from the measured gas pedal position change, such as that the step period decreases with increasing accelerator pedal position change, and that - The drive control device (30 or 60, 40, 14) means for moving the throttle valve (2) according to the Number of calculated steps and over the respective calculated step periods. 10. Apparatus according to claim 8, characterized in that the Control circuit (20, 50) - Means for sampling the accelerator pedal position signal (Vl) at predetermined times or after predetermined ones Time intervals, - Means for calculating a difference between new and old samples of the accelerator pedal position signal, - Means for calculating a number of steps CSTEP) TER SEA. MÖLLER STEINMEISTER the calculated difference, such that the number of steps increases as the calculated difference increases, and - Means for calculating a step period (PER) the calculated difference in such a way that the step period decreases as the calculated difference increases, and that - The drive control device (30 or 60, 40, 14) means for moving the throttle valve (2) according to the Number of calculated steps and over the respective calculated step periods. 11. The device according to claim 8, characterized in that the control circuit (20, 50) - Means for calculating a setting position for the throttle valve (2) on the basis of the accelerator pedal position signal (Vl), - Means for measuring the current setting position the throttle valve (2), - Means for calculating a difference between the calculated and the current setting position of the Throttle valve (2), - Means for calculating a number of steps (STEP) from the calculated difference, such that the number of steps increases as the calculated difference increases, and - Means for calculating a step period (PER) the calculated difference in such a way that the step period decreases as the calculated difference increases, and that - The drive control device (30 or 60, 40, 14) means for moving the throttle valve (2) accordingly the number of calculated steps and over the respective calculated periods. TER MEER · MÜLLER · STEINMEfSTER -8th- 12. Apparatus according to claim 8, characterized in that the control circuit (20, 50) - Means for sampling the accelerator pedal position signal (Vl) at predetermined times or after predetermined ones Time intervals, - Means for calculating a difference between new and old samples of the accelerator pedal position signal, - Means for determining weighting factors (Wo, Wl, ..) for the new and old samples, such that the Weighting factors for the new sample values are greater than for the old sample values when the calculated The difference between the samples increases, - Means for calculating a weighted mean value from the weighted new and old samples and - Means for calculating a throttle valve setting value on the basis of the calculated weighted Mean value, such that the throttle valve adjustment value increases with increasing weighted mean.