DE2850534A1 - Control microprocessor for ignition and fuel injection in IC engine - depends on count processes performed by input-output unit to reduce number of bits needed - Google Patents

Abstract

The system's input/output unit is designed so that the fewest possible number of bits are needed (pref. 8 bits). Various arithmetic operations are assigned to the input/output unit, which contains a first counter (61) connected to a first speed generator to determine counts dependent on speed or angle of rotation. A second counter (74) counts a frequency proportional to the amount of air drawn into the engine during the count time. The count result is passed to a databus (14). A count derived from this result is, in turn, counted in a third counter (67) so that the injection time and/or the closed time of an electronic switch in the primary circuit of the ignition coil is determined by at least part of this count time.

Description

Device, in particular for controlling the ignition and / or

State of the art fuel injection processes in internal combustion engines The invention is based on a device according to the preamble of the main claim. For example, control devices containing microprocessors in automobiles are already known known from the following references: Electronics, January 20, 1977, page 102 ff, Electronic Design 1, January 4, 1977, page 34 ff, Elektronik, 1977, issue 4, Page 48 ff, SAE paper lir. 750 432, Application of Microprocessors to the Automobile, Page 65 ff, etz-b, Volume 28, 1976, Issue 15, Page 496 ff, Computer, August 1974, Page 33 ff.

There are also hard-wired computers for controlling processes in the motor vehicle or in the internal combustion engine, e.g. from DE-PS 2 504 843 (UTS-PS 4 063 539) known. Such a hard-wired computer has opposite a microprocessor system has the disadvantage of poorer variability, while the known microprocessor systems depending on the necessary input / output unit and the necessary storage values in the read-only memory that are dependent on this due to complex programs for preparing and processing the externally created Signals carry out more or less lengthy and therefore slow computing processes must, especially at higher speeds, a restriction at the expense of Have to experience computational accuracy, or they have to have a correspondingly high number of bits, especially for fuel injection, in which usually more than 8 bits are required.

In the German patent application P 27 32 781.7 there is already an input / output unit describes how various arithmetic operations take place. On the special ones However, problems relating to the detection of the amount of air drawn in have not been discussed in greater detail.

Advantages of the invention The device according to the invention with the characterizing Features of the main claim or the subsidiary claim has the advantage that through extensive relocation of arithmetic operations, in particular counting processes, to Input / output unit designed the microcomputer system with a lower number of bits can be, especially 8 bit.

Certain counting processes, such as those for recording a speed-dependent or angle-of-rotation-dependent numerical value, both for the ignition and for the injection The inputXoutputunit is used easy to integrate and enables the program-controlled sequence of various Counting processes not yet suitable for today's generation of microprocessors are.

The measures listed in the subclaims are advantageous Further training and improvements of the facility specified in the main claim possible. Counting the amount of air drawn in is particularly advantageous dependent numerical value in the second counting device. Through this multiple use of a meter can be the circuit complexity or the effort for the integration be reduced.

Furthermore, it is particularly advantageous for the first counting device by connecting two comparators to control ignition and / or fuel injection to use.

Furthermore, it is particularly advantageous to increase the accuracy to provide a speed detection through the above a definable speed a counting time that is longer by a certain factor for the counting of the amount of revenue proportional counting frequency can be determined. This factor must of course be corrected Calculation processes as a function of further parameters of the internal combustion engine again taken into account, i.e. compensated. With this method, the acquisition of the Air volume guaranteed with sufficient accuracy even at high speeds, without too high numerical values being taken in .Kauf at low speeds have to.

DRAWING Two exemplary embodiments of the invention are shown in the drawing and explained in more detail in the following description. It shows Fig. 1 is a block diagram of a known Microcomputer system for an internal combustion engine, FIG. 2 a first exemplary embodiment of the invention, FIG. 3 a decoder for controlling the switching elements connected to the data bus 2 and 7, FIG. 4 shows a diagram to illustrate the counting accuracy at different speeds, FIG. 5 shows a diagram to explain the mode of operation of the first exemplary embodiment, FIG. 6 shows a circuit configuration of a speed-dependent switching device for counting frequencies, FIG. 7 shows a second embodiment of the invention and FIG. 8 is a diagram for explaining the mode of operation of the second Embodiment.

Description of the exemplary embodiments In the case of the one shown in FIG. 1 The microcomputer system is a microprocessor 10 with a working memory (RAM) 11, with a read-only memory (ROM, PROM or EPROM) 12 and with an input / output unit 13 connected via a data bus 14 and an address bus 15. In dependence of the information content to be transmitted, or depending on the number of Such a data bus 14 can, for example, consist of three individual lines with selectable addresses exist. A read command line 16 connecting components 10 to 12 is over a terminal 17 is connected to the input / output unit 13 and is used to connect or retrieve saved information. One the components 10, 11 connecting Write command line 18 is also connected to the input / output unit via a terminal 19 13 and is used to read information into the buffer. One Program interrupt command line (interrupt) 20 leads from the input / output unit 13 via a terminal 21 to the microprocessor 10. This line is used when present interrupt a program that is currently running in the microprocessor for certain information. From a reset circuit 22 conducts a delete command line (Clear) 23 for e-dispensing / dispensing-10: Unit and the lflikrQprocessor / Sle is used to to create certain conditions of entry, e.g. at the beginning of a program.

A frequency generator 24 is connected to the microprocessor via a terminal 25 10 connected in order to supply this module with a base clock frequency. Preferably a frequency obtained therefrom by division is transmitted via terminal 25 of the input / output unit fed; A terminal 26 carrying a supply voltage is provided with a voltage stabilization circuit 27 connected, the stabilized output voltage of a terminal 28, as well as all Components is supplied that contain electronics.

An input circuit 29 has seven inputs 30 to 36, the are connected to external signaling devices. Thereby the respective state, e.g. an internal combustion engine reported to the computer system. One with inputs 30, 31 connected encoder arrangement 37 consists of a preferably with the crankshaft Toothed disk 370 connected to an internal combustion engine, on the circumferential side a A plurality of teeth 371 are attached. These teeth are picked up by a first pickup 372 is sampled by every ferromagnetic tooth in this inductive pickup 372 causes a change in flux, which results in a voltage signal. The thereby The speed-dependent signal sequence generated is fed to input 30-. Instead of ferromagnetic Teeth of other marks can also be provided, which can be scanned by other sensors are. For example, the disk can be strip-shaped in the circumferential direction: magnetized- be or have an array of holes that can be scanned by optical devices is. A reference mark 373 is also arranged on the disk 370. This reference mark 373 can of course also be arranged on another disk or another rotating part be. The reference mark 373 is scanned by a second pickup 374 and that Reference mark signal fed to input 31. More information about the internal combustion engine, or the vehicle as supply voltage U, temperature T, amount of air drawn in L, position of the throttle valve switch 38 and position of the start switch 39 at inputs 32 to 36. The number of this additional information can be expanded as required and is not limited to the information shown.

The seven input information items shown at the inputs 30 up to 36 are processed in the input circuit, suppressed and, if necessary, digitized. On the output side, this information is sent via terminal 40 to 46 is supplied to the input / output unit 13. Provided information on the input circuit 29 are present in analog form, they are indicated by an in the input circuit 29 included analog-digital converter, e.g. a VCO: voltage controlled oscillator, converted into frequencies. A signal processing can e.g. with the help of Schmitt triggers take place. Debouncing circuits and circuits known per se can be used for interference suppression can be used to protect against overvoltage.

Two output stages of the input / output unit are via terminals 47, 48 connected to switching output stages 49, 50, which are designed as ignition output stages are. Such ignition output stages contain a semiconductor switch in a known manner in the primary circuit of an ignition coil, in the secondary circuit at least one Ignition gap 51, 52 or spark plug is switched. Another switching output stage 54 for controlling the fuel injection via four injection nozzles 55 shown to 58 is also connected to the input / output unit 13.

The. Mode of operation of the illustrated, known microprocessor system is known and described many times in the literature. In addition to the aforementioned In this context, the state of the art is primarily based on the user manuals referenced by the various microprocessor manufacturers detailing both the structure and wiring of the individual components, as well as their mode of operation and Programming is described. Construction variants and circuit options, and suggestions are given in great detail. Take the manuals as an example of the company RCA - User Manual for the CDP 1802 Cosmac Microprocessor MPM-201A "and "RCA, Integrated Circuits, SSDt210, 4-76t 'referenced.

As part of a program stored in the read-only memory 12 from the microprocessor 10 externally applied to the input / output unit 13 information processed in connection with permanently stored information. That calculated Result, in the present case the signals for controlling ignition and injection, are passed on to the switching output stages 49, 50, 54 to execute the desired Switching commands. Final results and intermediate results are partly in memory 11 cached, and then called up again by the microprocessor when required to become.

The number of microprocessors, read-only memories and Main memory is not limited according to the representation, but can be dependent on the information to be processed, the scope of the program and the scope of the stored data can be expanded as required. Of course, this number also depends on the type of component used in each case, or on its work and storage options.

In the embodiment of the invention shown in Fig. 2 is the applied with the speed signal terminal 40 with the clock input C of a first Counter 61 connected, the number outputs via a first preliminary stage 62 with the Data bus 14 are connected. The preferably as a parallel connection, different The first gate stage 62, which is configured as a transmission gate, is controlled via a terminal 63. Terminal 41, which carries the reference mark signal, is connected to the reset input R of the counter 61, as well as via a timing element 64 with the gate input (Carry In) CI this counter 61 tied together. The timer 64 is for the present digital circuit design preferably also designed as a counter, the a fixed frequency counts up to a certain count. The circuit design shown 61 to 64 to determine a speed-dependent numerical value can be in multiple Way, e.g. also according to the German patent application P 27 32 781. 7th

The data bus 14 is also via a first buffer memory 65, whose acceptance input is controlled via a terminal 66, with the set inputs of the second counter 67, whose overflow output (Carr> y Out) CO with the reset input R of a flip-flop 68 is connected. The set input of the flip-flop 68 is controlled via a terminal 69. An output of the flip-flop 68 is to the terminal 53 is connected, and the second, complementary output is connected to an input of a AND gate 70 connected. The number outputs of the second counter 67 are via a Decoding stage 71 is connected to a second input of AND gate 70. Intended to the lowest count can be decoded, the decoding stage 71 can be used as an AND gate be formed, or the output CO is used instead of this decoding stage 71. Terminal 69 and another terminal 72 are connected to the via an OR gate 73 Load input (preset enable) PE of the second counter 67 connected.

Terminal 44 is connected to clock input C of a third counter 74, its gate input CI and its reset input R to the output of the AND gate 70 are connected. The number outputs of this third counter 74 are via a Second gate stage 76 controlled via a terminal 75 is connected to the data bus 14.

Terminal 25, which carries the basic clock frequency, is connected to the input of a Frequency divider stute 77 connected, at the two outputs two, preferably output frequencies different by a factor of 4 are present. These two output frequencies are wab-lweise via a switching device 78 the clock input C of the second counter 67 can be supplied.

The switching device 78 is used to control switching processes Connected to the data bus 14 via a switchover decoding stage 79. The trigger the switching commands are made via terminal 80.

The input signals for the circuit shown, as well as for the Circuits shown in the following figures are preferably at the fundamental frequency rasterized or

-synchronized. Synchronization levels necessary for this purpose However, for the sake of simplicity, they are not shown in more detail and from the introduction mentioned DE-PS 2 504 843, Fig. 4 is known. The circuit shown there serves at the same time the frequency doubling. They may also not be shown at the outputs required amplifier stages. They can be provided according to needs and signal levels will.

The decoding device 100 shown in FIG. 3 is on the input side with the address bus 15 and via the terminals 17, 19 with the read command line 16 and the write command line 18 are connected. The decoder is on the output side 100 connected to terminals 63, 66, 69, 72, 75, 80, 85, 1C4, 107, 110, 115 and 123. The decoder 100 is also contained in the input / output unit 13 and is used to control the gate steps connected to the said terminals, intermediate storage, Decoding levels and counters.

Depending on the input signals present, appears on a signal through one or more output terminals of the decoder 100 that the associated step is actuated. This can e.g. send a signal pass a preliminary stage or a counter takes over an existing numerical value. The sequence of these commands is determined by the program in the microprocessor and output as a command via lines 15, 16, 18.

The basic mode of operation of those shown in FIGS. 2 and 3 Input / output unit 13 in connection with the system shown in FIG. 1 is explained below with reference to the diagrams shown in FIGS. The detection is essential for the injection and also advantageous for the ignition the amount of air drawn in via an air flow meter, not shown in detail. If the air flow meter used supplies an analog output signal, it must in the input circuit 29 are converted into a frequency that corresponds to the amount of air is proportional. This frequency is counted via terminal 44 in counter 7 and during a predetermined time by the counter 67. The counter content of the counter 74 can at any time by the microprocessor via the gate stage 76 by a signal can be queried at terminal 75. The counting time that can be specified by the counter 67 can on the one hand through the counting frequencies that can be selected there and on the other hand through various numerical values are specified by the microprocessor via the data bus 14 and the buffer 65 can be taken over into this counter 67. To calculate both the correct The engine speed n must be detected at the ignition angle.

This is done via the arrangement 61 to 6b. To a reference mark signal the timer 64 is triggered at the terminal 41 and during the hold time This timing element 64 is counted into the counter 61 signals of the transmitter arrangement 37. The final counter reading reached is therefore proportional to the speed and can be accessed via the preliminary stage 62 can be called up by a signal at terminal 63 from the microprocessor. He is lying then in the microprocessor and can be used for the injection. For the injection, the reciprocal value of n or one is advantageously used suitably normalized value A / n in order to be favorable in the numerical range. The division is carried out in the microprocessor, but it can also be carried out by a known per se digital division is carried out in the input / output unit. The result Z1 becomes the counter 67 is loaded on a signal at the terminal 72 and with a fixed clock frequency f counted down. During this time, which corresponds to the period duration, is on Output of the decoding stage 71 a Signal through which the gate entrance CI of the counter 74 is enabled. This will add to the counter during this time 74 the frequency proportional to the air volume is counted. The one at the end of the said The counter reading in counter 74 is proportional to the uncorrected injection time. It can be called up via the gate stage 76 and is corrected in the microprocessor by means of correction values, which originate from other influencing variables or parameters and are also not shown Way to be fed to the microprocessor via the input / output unit multiplied. Such further parameters can be carried out in a manner similar to the air volume signal are converted into numerical values and transferred to the microprocessor via a preliminary stage will.

This modified injection numerical value Z2 is responded to a signal the terminal 69 is transferred to the counter 67 via the buffer 65 and counted. During the counting process, the flip-flop 68 is set and is at the output terminal 53 from a signal U53. This signal specifies the injection time and is triggered by a Overflow signal at the output CO of the counter 67, which resets the flip-flop 68 causes wira, ended.

From Fig. 4, curve I, it follows that at idle speeds below 1,000 revolutions per minute can achieve good accuracy with this method can. At high speeds, the times become so short and thus the counting results achieved so small that the accuracy is significantly deteriorated. The curve in general Increasing it by e.g. higher frequencies would have the disadvantage that the counters for would have to interpret very high numerical values, which are then reached at low speeds would (compare curve II) -.

In order to take this into account, from a certain speed, e.g. 1,000 revolutions per minute, the gate time for the counter 74 by a certain Factor increased. In the example shown, this factor is 4.

Exceeding this definable speed is recorded in the microprocessor recognized and via the data bus 14 and the decoder 79 is the Switching device 78 actuated, which now takes place at the clock input of the counter 67 the frequency fl is applied by the frequency f2, which is lower by a factor of 4. At the end of the down count.

process from the numerical value Z1, the switchover to takes place again the frequency fl, which is required for counting down the number Z2. Below the adjustable limit speed, all downcounting processes are carried out with the frequency fl. Due to this gate time, which is increased by a factor of 4, the counter 74 has a Counter reading increased by a factor of 4. After correction processes through other vehicle parameters In the microprocessor, the numerical value obtained must again be divided by a factor of 4 be to the. to compensate for four times the goal time. The factor 4 is therefore favorable, because the corresponding multiplication or division by simple shift operations can be made. -All other powers of two are just as cheap.

Instead of dividing by this specific factor to compensate for the extended'Torzeit can count the counter reading Z2 with a this factor increased frequency are executed. A third frequency would have to be used for this to provide.

An analogous solution is to keep the period below one the definable limit speed by a certain factor to the maximum The count of the counter 74 is not to be exceeded. It is also possible to Extension or shortening of the gate time for the counter 74 instead of the change the counting frequency for the counter 67, its initial numerical value Z1 with a factor to multiply or divide.

To recognize the selectable limit speed, e.g. the final count of counter 61 or counter 74 used will. By comparing such meter readings taken at regular intervals in the microprocessor with comparison values stored there it is possible to .such Recognize speed limits. Such a speed detection can, however, also in the Input / output unit 13 take place, for example by a circuit according to FIG. 6.

The wiring of the terminals 40, 41 with the components 61, 64 corresponds Fig. 2. The number outputs of the counter 61 are additionally with inputs of a digital one Comparator 81 connected, the comparison inputs preferably by hard wiring are charged with the numerical value X, which corresponds to this limit speed. Of the The output of the comparator is connected to the D input of a D flip-flop 82, the Clock input is connected to terminal 41. The output of flip-flop 82 is Connected via an AND gate 83 to the control input of the switching device 78. Terminal 89 is with the set input S and terminal 72 with the reset input R of a flip-flop 84 connected, the complementary output of which to another Input of AND gate 83 is connected.

The counter 61 never reaches the counter reading below the limit speed X, whereby at the output of the flip-flop 82 and thus at the output of the AND gate 83 constantly there is an O signal.

The switching device 78 thus constantly connects the clock input of the counter 87 with the frequency fl. The limit speed and thus the. Counter reading X is exceeded, flip-flop 82 is triggered by a trigger signal at terminal 41 is set and switches the switching device 78 to the frequency f2, provided that am second input of AND gate 83 is also a 1 signal. This is the case when the flip-flop 84 has been reset by a reset signal U72.

The flip-flop 84, the AND gate, is set again by a signal U62 83 is blocked and the switching device 78 again connects the clock input of the counter 67 with the frequency £ 1 until a new reset signal U72 appears.

Ln the second ftUsft'J'hiI1ngsbei'jpi1 der shown in FIG Finding is the applied with the speed signal terminal 40 via a frequency multiplier stage 101 is connected to the clock input C of the first counter 61. The the reference mark signal leading terminal 41 is via an OR gate 102 to the load input PE of the first Counter 61 connected. Its overflow outlet CO is connected to a further angang of the OR gate 102 connected. The data bus 14 is via a first buffer memory 103, whose acceptance input is controlled via a terminal 104, to the number inputs of the first counter 61 is connected. The number outputs of this counter 61 are both applied to first comparison inputs of a comparator 105, which is also via the preliminary stage 62 are connected to the data bus 14. Second comparison number inputs of the comparator 105 are via a further buffer 106, which is controlled via a terminal 107 is connected to the data bus 14. The number outputs of the first counter 61 are still applied to comparison number inputs of a second comparator 108, whose second comparison number inputs via a buffer 109 to the data bus 14 are connected. The buffer store 109 is controlled via a terminal 110.

The output of the comparator 105 is connected to the set input of a flip-flop 111 connected, the output of which is connected to the control input of a selection via a terminal 112 logic 113 is connected. The individual second stage channels are selected from the data bus 14 over a first decoding stage 114, the outputs of which also with the selection logic 113 and which is controlled via a terminal 115. A more detailed one Embodiments of the components 113, 114 are in the prior art mentioned at the beginning shown. The J and K inputs of two JK flip-flops 116, 117 have outputs the selection logic 113 connected. One output each of the two flip-flops 116, 117 is connected to one of the two terminals 47, 48 for controlling the switching output stages 49, 50 tied together. In a simpler embodiment, only one can use a flip-flop controlled switching output stage are provided. The high voltage distribution on the individual cylinders of the internal combustion engine are then carried out via a mechanical high-voltage distributor.

As in the first embodiment, the counter 67 is via the buffer 65 connected to the data bus 14. Its overflow output CO is once via an OR gate 118 is connected to its load input PE and continues via an AND gate 119 the reset input R of a flip-flop 120 is connected. The output of this flip-flop 120 is once with the gate input CI of the counter 67 and also with the output terminal 53 connected.

Terminal 69 is connected to another input of OR gate 118, and connected to the set inputs S of the flip-flop 120 and a further flip-flop 121. The complementary output of the flip-flop 121 is connected to a further input of the AND gate 119 connected.

The overflow output is used to report the overflow signals to the microprocessor CO of the counter 67 is connected to an input a feedback gate stage 122. The outputs of this feedback gate stage 122 controlled via a terminal 12) are connected to the data bus 14.

Further inputs b to -k are connected to the outputs of two more Flip-flops 124, 125 and the flip-flop 111, with the two terminals 45, 46, with the Outputs of the two flip-flops 116, 117 and finally with two higher-order bit outputs of the counter 74 connected. The inputs a, c and d are the feedback gate stage 122 is also connected to the inputs of an OR gate 127, the output of which is for supply connected to terminal 21 by "interrupt" signals.

he output of the second comparator 108 is connected to the clock input of the e.g. flip-flops 124 designed as flip-flops as well as with the set input of the flip-flop 125 connected. The output of the flip-flop 124 is both with the gate input CI as also connected to the reset input R of the counter 74. This counter 74 is according to In the first exemplary embodiment, it is connected to the data bus 14 via a gate stage 76. The clock input C of this counter 7 has a frequency proportional to the air volume leading terminal 44 connected. For multiple use of the counter 74 this can Clock input, however, also via a switching device according to FIG. 2 with further Fixed frequencies as well as other, parameter-dependent frequencies are connected. In addition to defining a numerical value from which the injection time is derived, the counter 74 can also be used cyclically to calculate further numerical values from which e.g.

the position of a solenoid valve, the throttle pressure control for automatic Gearbox, the odometer, the electric clock control and stepper motors monitor or have it controlled. This cyclical control is carried out by the microprocessor, wherein the counting frequency switching over a switching decoding stage 79 according to.dem first embodiment can be done.

The reset inputs R of flip-flops 111, 121, 125 are controlled via a second decoding stage 126 connected to the data bus 14, the control input of which is connected to terminal 115.

The mode of operation of the second exemplary embodiment shown in FIG. 7 is to be explained below with reference to the signal diagram shown in FIG. The frequency of the speed signal sequence applied to terminal 4ù is in the Frequency multiplier stage 101 multiplies, preferably doubled, and appears as a signal sequence U 101 at the clock input of the down counter first counter 61. The signal sequences shown in FIG. 8 are constant for the case permanent speed parameter shown. The reference mark signal U41 causes on Load input PE a setting of the counter 61 with that in the first buffer store 103 stored numerical value. This cached numerical value was already previously accepted by data bus 14 in response to a signal at terminal 104. The adopted The numerical value is counted down at the rate of the signal sequence U101 until it reaches the counter reading Zero an overflow signal U61 is generated at the overflow output CO. This. Overflow signal U61 in turn causes the counter 61 to be set again via the OR gate 102.

It thus acts like additional, internal reference mark signals.

The numerical value accepted from the buffer store 103 is variable and becomes determined by the program depending on the respective parameters. The on The output of the counter 61 can respond to a signal at the terminal 63 from the microprocessor via the data bus 14 and the gate stage 62 to any Time can be queried.

In the buffer memory o6 the clock at its control input pending signal sequence U107 the numerical values pending via the data bus cached. In the example shown, these numerical values alternate between Z1 and Z2. These cached numerical values are available at the second comparison inputs of the comparator 105 on; If the counter reading in counter 61 reaches the numerical value Z2, so the comparator 105 emits a first output signal and when the counter reading is reached Z1 a second. These output signals are shown as signal sequence U105 / U112. The flip-flop 111 is set and activated by the signals of this signal sequence Signals of the decoding stage 126 are each reset. Through the output of the Flip-flops 111 is controlled by the selection logic 113, which in turn the decoding stage 114 is controlled, alternately the flip-flop arrangement 75, 76 set and reset so that the signal sequences U47 and U48 develop. This can be done by the most varied of logic circuits. A possibility is shown in the prior art mentioned at the beginning. The signal sequences U47 and U48 alternately control the switching output stages 49, 50 and give, e.g. in the case of a Ignition system, the closing times of the electrical switch in the primary circuit of a Ignition coil in front, whereby the ignition is triggered by the end of the signal. Of the Circuit part of FIG. 7 previously described in its effect for controlling the Ignition processes are known from the prior art mentioned at the beginning.

The buffer at its control input is clocked in the buffer 109 pending signal sequence U110 the respective numerical values pending via the data bus cached. These numerical values can vary depending on parameters, are however shown in Fig. 8 (stationary operation) as a numerical value Z3. Achieved the changing numerical value in counter 61 has the numerical value Z3, then at the output of the comparator 108 generates a short output signal U108. These signals 108 are reported back to the microprocessor once via the flip-flop 125 and the feedback gate stage 122 and also generate an interrupt signal via the OR gate 124.

Such a signal interrupts the current program. Interrupt signals are common in microprocessor controls and their effect is limited known from the prior art specified at the beginning. Furthermore, the signal sequence U108 switches the flip-flop 124 so that the signal sequence U124 is generated.

Such a signal 124 starts an up counting process after the reset in the counter 74 with the frequency proportional to the air volume at terminal 44. The am end of Gate time reached counter reading in counter 74 is proportional the value Q / n, where Q is the amount of air drawn in per unit of time and n is the speed is. The numerical value reached can be entered via gate step 76 up to the beginning of a new one Signals U124 can be queried by the microprocessor. This adopted numerical value is in the microprocessor depending on parameters such as the temperature, of the air pressure etc., corrected and cyclical in response to a signal at terminal 66 taken over into the buffer memory 65.

The two flip-flops 120, 121 are set once by a signal U69 and also via the OR gate 118 and the set input PE of the in the buffer 65 stored numerical value is transferred to counter 67. The -as a down counter trained counter 67 begins in the clock he fixed or applied to terminal 85 selectable frequency to count downwards until an overflow signal U67 at the overflow output CO is generated. This overflow signal is reported back once via stage 122 and also generates an interrupt signal at terminal 21. Continue The counter 67 is set again via the OR gate 118. This process continues cyclically until the flip-flop 121 is reset via the decoding stage 126 will. This reset signal is a function of the program in the microprocessor based on the incoming interrupt signals. As a result of the reset Flip-flops 121 carries the subsequent overflow signal of the counter 67 via the AND gate 119 to reset the flip-flop 120. The one generated during the set flip-flop 120 Signal U53 at terminal 53 specifies the injection time and controls accordingly the injection process via the output stage 54. The use of several counting processes to determine an injection signal in Counter 67 allows simple Multiplication of binary numbers, which are relatively complex to implement in the microprocessor would be. Of course, the signal end of a signal U53 can also be directly caused by a signal U126 can be brought about by sending this signal directly to the reset input of the flip-flop 120 is fed.

The signals present at the inputs a to k of the feedback gate 122 Status reports, some of which are stored in flip-flops, can be sent through the microprocessor interrogated for a signal at terminal 123 and for correction the various numerical values can be used.

Parts of the input / output unit that are not essential for the invention 13 have been omitted to simplify the illustration, although they are of course for the functioning of the overall system is necessary. These are in particular the acquisition the other parameters of the internal combustion engine, as well as their processing. In the beginning stated prior art, this is described in more detail.

In the following, commercially available components are presented in tabular form that can be used, for example, in the specified circuits. The specified components are all from RCA (with one exception) and are identified by their number: Microprocessor 10 CDP 1802 D or CDP 1802 CD main memory 11 CDP i824 read-only memory 12 CDP 1833 CD counter 61, 67, 74 CD 4029 buffer 65 CD 4042 comparator 105, 108 MC 14 585 (Motorola) gate stage 62, 76 CD 4016 eroding stages 71, 79 CD 4556 Uscaltvorrichtun 78 CD 4016 or CD 4052 Sequence sub-segment level 77 CD 4040

Claims (14)

Claims g device, in particular for controlling the ignition and / or Fuel injection processes in internal combustion engines, with a microcomputer system consisting of a microprocessor, which is connected via a data bus and via an address bus each with at least one read-only memory (ROM, PROM, EPROM), a working memory (RAM) and an input / output unit is connected to the external signal transmitter are connected to the generation of operating parameter-dependent signals, thereby characterized in that in the input / output unit (13) a first with a speed sensor (37) related counting device (61) for determining the speed slower Numerical values are provided that a second counting device (67) is preferred Numerical values derived from these speed-dependent numerical values via the data bus fed and counted with a counting frequency that during this counting process in a third counting device (74) one of the in the intake manifold of the internal combustion engine sucked in Air volume proportional counting frequency is counted and the counting result is then saved in the data bus (14) is read, and that a result derived from this count Numerical value is counted by a counting frequency, the injection duration and / or the closing time for an electrical switch in the primary circuit of an ignition coil can be determined by at least part of this counting period. 2. Device according to claim 1, characterized in that the counting the numerical value dependent on the amount of air sucked in is also in the second Counting device (67) takes place. 3. Device according to claim 1 or 2, characterized in that the numerical value derived from the speed-dependent numerical value is essentially reversed is proportional to the speed n. 4. Inspection, especially for controlling the ignition and / or fuel injection processes in internal combustion engines, with a microcomputer system consisting of a microprocessor, via a data bus and an address bus, each with at least one read-only memory (ROM, PROM, EPROM), a working memory (RAM) and an input / output unit is connected to the external signal generator for generating operating parameter-dependent Signals connected are, characterized in that in the Input / output unit (13) a first with a speed sensor (37) in connection standing counting device (61) is provided, whose periodically changing Numerical content for the formation of a rotation angle signal with a preferably via the Data bus predeterminable numerical value is compared that during such a rotation angle signal in a third counting device (j4) one of the in the intake manifold of the internal combustion engine The amount of air drawn in is counted at the proportional counting frequency and then the counting result is read into the data bus (14), and that a result derived from this count Numerical value is counted by a counting frequency, the injection duration and / or the closing time for an electrical switch in the primary circuit of an ignition coil can be determined by at least part of this counting period. 5. Device according to claim 4, characterized in that for the formation of the rotation angle signal, a comparator (108) is provided which, when the The numerical content of the first counting device (61) and the predeterminable numerical value each emits an output signal by means of which a switching device (124) can be switched is. 6. Device according to claim 4 or 5, characterized in that the first counter (61) a second comparison device (105) for comparing its Numerical content is assigned with at least one predeterminable numerical value, wherein the first comparison device (108) for controlling the fuel injection processes and the second comparison device (105) is used to control the ignition processes is. 7. Device according to claim 5 or 6, characterized in that the first comparison device (108) in addition to the detection and / or control further operations is used, with a switching device for switching the air volume-proportional counting frequency fed to the third counting device (74) other fixed counting frequencies or counting frequencies proportional to these processes are provided. 8. Device according to one of the preceding claims, characterized in that that the injection duration and / or the closing time for the ignition by several counting cycles the counting counter (67) is set. 9. Device according to claim 8, characterized in that after each Counting cycle a signal to interrupt the program (Interrupt) the microprocessor is fed that this calculates an internally it signal to Completion of the cycles of a preliminary stage (121-119) feeds through which the overflow signal becomes effective as a switch-off signal at the end of the subsequent counting cycle. 10. Device according to one of the preceding claims, characterized in that that a speed detection - (61, 64, 81) is provided to increase the accuracy is by a certain factor above a definable speed longer counting time for counting the counting frequency proportional to the air volume is predeterminable and that this factor depends on corrective calculations further parameters of the internal combustion engine are taken into account again. 11. Device according to claim 10, characterized in that for Determination of the two beats, which differ by a certain factor Counting frequency for counting the number dependent on the speed by one certain factor is changeable. 12. Device according to claim 10 or 11, characterized in that that to take into account the specific factor a corresponding division or Multiplication of the corrected numerical value depending on the air volume is carried out. 13. Device according to claim 10 or 11, characterized in that that to take account of the specific factor, the counting of the corrected, The numerical value dependent on the air volume with a value changed by this factor Frequency takes place. 14. Device according to one of claims 10 to 13, characterized in that that the particular factor is a power of two, especially four.