DE3440555C2 - - Google Patents

Description

The invention relates to a device according to the genus Main claim.

DE 33 08 610 A1 describes a method for Fault detection in electrical devices with a corresponding to the preamble of claim 1 Device known. Here is an single control unit connected to a diagnostic line. To the A lamp and a loudspeaker are connected to the diagnostic line. There is also an external diagnostic device on the diagnostic line connectable. The control device has a self-diagnosis device on. After a detected fault, it is sent to the diagnostic line connected lamp automatically controlled so that it turns on Emits continuous signal. It is still possible to use the Diagnostic line to control the lamp so that it flashes issues to signal an error code.

DE 31 21 645 A1 describes a method and an apparatus for Detection of errors in sensors in vehicles known. The donors are connected to a single electrical device. The single ones Encoders are checked in sequence. The review happens with the aid of a comparator to which comparison values are supplied. If an error is detected, an error word is stored in the memory of the Control unit stored. An error display is then activated. An external diagnostic device can be connected to the electrical device be connected. This is then the saved Error word issued for the purpose of evaluation.

It is an object of the invention for self-diagnosis in an electronic Device of the type mentioned a simple monitoring device to form a display of diagnostic results for several connected electronic devices allowed.

This object is solved by the features of claims 1 to 8.  

The device according to the invention with the characteristic features of claims 1 and 8 has the advantage that through them an easy diagnostic option of multiple electronic Devices is created. The wiring effort is low because of the electronic devices only via a single diagnostic line are interconnected. By using only one Playback device connected to the diagnostic line, the circuit effort is kept low. The playback device can in the simplest case consist of a lamp. Kick If an error occurs in one of the electronic devices, the Playback device only activated at first, with no special Diagnostic results are output. Now for more information An operator can find out about the error that has occurred, e.g. B. the driver or the staff of a repair service, one Press the diagnostic switch, whereupon the electronic device outputs a more detailed error message to the playback device. A connection of an external diagnostic device is not for this required. This makes it an operator on site possible the right decision for or against a further journey to meet z. B. greater damage to a component of the Motor vehicle, such as the catalyst to avert.

The measures listed in the subclaims are advantageous Developments and improvements in the main claim specified device possible. It is particularly advantageous that with the diagnostic switch different signal codes can be generated by which the individual electronic devices can be addressed. Thereby individual electronic devices can be specifically requested then output their diagnostic results. The individual signal codes either by different numbers of Actuations or by different length of actuation of the Diagnostic switch are generated.  

The load on the microcomputers in the electronic devices is particularly low if there is a fixed schedule, that the signal codes are first recognized in a measuring window and then after a subsequent synchronization window Output of the diagnostic results in the form of signal sequences expires.

To activate the playback device after an error of an electronic device has been detected, it makes sense to Playback device with such a high frequency on and switch off that on the one hand the microcomputer is one of the least two electronic devices the signal so generated on the Diagnostic line from those that can be generated with the aid of the diagnostic switch Can distinguish signal codes and on the other hand corresponding human sense organ this signal as Continuous signal senses.

Furthermore, it is possible without difficulty, even more complicated ones Workshop diagnostic devices to be connected to the diagnostic line then act as a playback device.

It is also advantageous that by repeatedly pressing the Diagnostic switch, which makes one and the same electronic device is repeatedly addressed, multiple diagnostic results can be called up one after the other from the addressed electronic device are.

Two embodiments of the invention are in the drawing shown and in the description below explained in more detail. It shows

Fig. 1 is a circuit even representation of the first embodiment,

Fig. 2 and Fig. 3 shows signal diagrams for explaining two possible modes of action,

Fig. 4 is a schematic diagram of the processes in a microcomputer and

Fig. 5 shows the circuit diagram of a second embodiment.

In the exemplary embodiment according to FIG. 1, two electronic devices 10, 11 are shown, which can be used in a known manner to control two functions of an internal combustion engine or a motor vehicle. These electronic devices 10, 11 are each connected via a connector pin 12, 13 to a diagnostic line 14 , through which the two electronic devices 10, 11 and possibly further electronic devices are connected to one another. A diagnostic switch 15 , which is preferably designed as a pushbutton switch, is connected to the diagnostic line 14 . Furthermore, a diagnostic lamp 16 is connected as a playback device for the diagnosis, the second connection of which is connected to the positive pole of a supply voltage source 17 .

To simplify the illustration, the basic internal structure of the two electronic devices 10, 11 which is decisive for the diagnosis is only shown in more detail in the case of the electronic device 10 , although the electronic device 11 and, if appropriate, further electronic devices are constructed accordingly. The plug pin 12 is connected via an input impedance converter 18 to an input of a microcomputer 19 . A diagnostic output of this microcomputer 19 is connected via an OR gate 20 to the base of a switching transistor 21 , the switching path of which connects the connector pin 12 to ground. A safety device 22 , in particular a watchdog circuit, is also connected to the microcomputer 19 , the output of which is connected to a further input of the OR gate 20 . A watchdog circuit is known for example from DE-OS 28 42 392 and is used for cyclical monitoring of the program sequence in the microcomputer 19 , that is to say for monitoring the microcomputer 19 itself.

The mode of operation of the exemplary embodiment shown in FIG. 1 is explained in more detail below with reference to the signal diagram shown in FIGS . 2 and 3. The two signal diagrams illustrate this two alternatives. Detects the microcomputer 19 on the basis of contained in it diagnostic program a fault at one or more of the connected sensors, amplifiers or other components, it will output a fault signal via the OR gate 20 to the base of Given switching transistor 21 . A corresponding error signal can be generated by the safety device 22 if an error occurs in the microcomputer 19 itself, ie in its program execution. The error signal is an intermittent signal through which the switching transistor 21 periodically connects the diagnostic lamp 16 to ground so that it lights up. The frequency is chosen so high, preferably higher than 50 Hz, that the human eye perceives the diagnostic lamp 16 as permanently switched on. When the diagnostic lamp 16 lights up, the driver of a vehicle is informed that an error has occurred somewhere.

Instead of an optical playback device, such as the diagnostic lamp 16 , an acoustic system, e.g. B. a speaker or a buzzer to indicate an error. If the driver now wants to find out more information about the type of error that has occurred, he actuates the diagnostic switch 15 . Its 0 signal is fed to the microcomputer 19 via the input impedance converter 18 . Depending on the type of operation, the operator can query one of the electronic devices 10, 11 . This takes place either according to FIG. 2 depending on the duration of the actuation of the diagnostic switch 15 or according to FIG. 3 depending on the number of operations. According to Fig. 2, during a measurement window tm determined in the microcomputer 19, the length of the operation of the diagnostic switch 15. In the case shown, the actuation is recognized as four time units and the corresponding microcomputer 19 is activated. The microcomputers 19 of the other electronic devices 11, 10 then remain without reaction. In the case of FIG. 3, two actuations are recognized and the corresponding microcomputer 19 is activated again. After the measurement window tm there follows a synchronization window ts, in which the microcomputer 19 recognizes that the identification has been completed. Then, a blink code corresponding to the error is output via the OR gate 20 to the switching transistor 21 , which causes the diagnostic lamp 16 to light up accordingly, as shown in FIG. 2 or 3 twice. This lighting up twice can then be equated with a certain error using a table.

As a result of the time sequence described, the load on the microcomputer 19 is minimal, the times for the measurement window tm, the synchronization window ts and the blink code being substantially greater than the computer runtime.

Only one error is output for each request by actuating the diagnostic switch 15 . If the request is repeated, a second error, if any, is displayed. This continues until the first error is displayed again, which shows that there are no further errors. If the diagnostic lamp 16 already flashes in the same way when the second request is made, the result is that there is only a single error.

Of course, it is also possible to carry out a more complex workshop diagnosis by connecting corresponding workshop measuring devices (workshop diagnosis devices) to the diagnosis line 14 . Otherwise, the diagnostic lamp 16 can be a permanently installed lamp in the dashboard of the vehicle or a lamp that can be connected in individual cases.

In Fig. 4, the corresponding functions in the microcomputer 19 are shown in terms of hardware for a better explanation of the mode of operation and can of course also be implemented in this way. However, the functions are usually implemented in software.

The input of the microcomputer 19 connected to the output of the input impedance converter 18 is connected via a low-pass filter 30 to the clock input C of a counter 31 , the number outputs of which are connected to a comparator 32 . A fixed numerical value N is applied to the comparison number inputs of the comparator 32 . The output of the comparator 32 is connected via an AND gate 33 to a diagnostic output part 34 , the output of which is simultaneously the output of the microcomputer 19 connected to the OR gate 20 . The output of the low-pass filter 30 is also connected to a timing element 35 , the delay time of which is the synchronization time ts. The output of this timer 35 is connected to a further input of the AND gate 33 . The output of this AND gate 33 is also connected to the reset input R of the counter 31 .

If the diagnostic program of the microcomputer 19 detects an error, the high-frequency signal sequence already described is fed to the diagnostic lamp 16 via the diagnostic output part 34 . This high frequency (greater than 50 Hz) cannot reach the clock input of the counter 21 through the low-pass filter 30 . Only the low-frequency pulses of the diagnostic switch 15 can reach the counter 31 and are counted up there. The coding of the respective microcomputer 19 is the number N, ie if N key pulses are received, a 1 signal is generated at the output of the comparator 32 . The timer 35 is restarted with each input pulse. If the time of the synchronization window ts has passed without a new pulse having been received, a 1 signal is also generated on the output side, as a result of which the AND gate 33 switches and on the one hand resets the counter 31 and on the other hand the diagnostic signal sequence in the diagnosis - Output part 34 triggers. This can consist, for example, of two pulses, whereupon the diagnostic lamp 16 lights up twice. The two flashes can indicate a defective temperature sensor, for example.

The second exemplary embodiment shown in FIG. 5 is partially constructed in the same way as the first exemplary embodiment shown in FIG. 1, which is why components with the same wiring are not described again. The main difference is that the diagnostic line 14 is not connected to the inputs of the microcomputer 19 and not to the diagnostic switch 15 . Each electronic device is assigned its own diagnostic switch here, the electronic device 10 the diagnostic switch 15 and the electronic device 11 the diagnostic switch 40 . Coding is not necessary since each diagnostic switch 15, 40 only addresses a single microcomputer 13 in an electronic device 10, 11 . The diagnostic results are output in accordance with what has been described above, ie only a single diagnostic lamp 16 is required for all electronic devices 10, 11 .

Claims (10)

1. Device for self-diagnosis in an electronic device, which contains a microcomputer with a diagnostic program, with a playback device for playback of the diagnostic results generated in the form of various signal sequences, with a diagnostic line to which the playback device can be connected, which is then in the event of an error in the electronic device or its periphery can be activated, characterized in that at least one further corresponding electronic device (11) is connected to the diagnosis line (14), that for short-term connection of the diagnostic line (14) to ground, a common diagnostic switch (15) is present and that the electronic devices ( 10, 11 ) only deliver the diagnostic results to the playback device ( 16 ) after actuation of the common diagnostic switch ( 15 ). 2. Device according to claim 1, characterized in that a key switch is provided as a common diagnostic switch ( 15 ). 3. Apparatus according to claim 1 or 2, characterized in that with the diagnostic switch ( 15 ) different signal codes can be generated through which the individual electronic devices ( 10, 11 ) can be addressed. 4. The device according to claim 3, characterized in that the individual signal codes can be generated by different numbers of operations of the diagnostic switch ( 15 ). 5. The device according to claim 3, characterized in that the individual signal codes can be generated by different lengths of actuation of the diagnostic switch ( 15 ). 6. Device according to one of claims 3 to 5, characterized in that after detecting the signal code, the electronic devices ( 10, 11 ) wait for a synchronization window (t _s ) before they deliver the diagnostic results to the playback device ( 16 ). 7. Device according to one of the preceding claims, characterized in that for activating the playback device ( 16 ) it is switched on and off at such a high frequency that on the one hand the microcomputer ( 19 ) one of the at least two electronic devices ( 10, 11 ) the signal generated in this way and present on the diagnostic line ( 14 ) can be distinguished from the signal codes which can be generated with the aid of the diagnostic switch ( 15 ) and, on the other hand, a corresponding human sensory organ perceives this signal as a continuous signal. 8. Device for self-diagnosis in an electronic device, which contains a microcomputer with a diagnostic program, with a playback device for playback of the diagnostic results generated in the form of different signal sequences, with a diagnostic line to which the playback device can be connected, which then occurs when an error occurs in the electronic device or its periphery can be activated, characterized in that at least one further electronic device ( 11 ) is connected to the diagnostic line ( 14 ), that each electronic device ( 10, 11 ) is assigned its own diagnostic switch ( 15, 40 ) and that after actuation of one of the diagnostic switches ( 15, 40 ) from the corresponding electronic device ( 10, 11 ) the diagnostic results of this electronic device ( 10, 11 ) can be output to the diagnostic line ( 14 ). 9. Device according to one of the preceding claims, characterized in that a workshop diagnostic device can be connected as the playback device ( 16 ) at any point on the diagnostic line ( 14 ). 10. Device according to one of the preceding claims, characterized in that by repeated actuation of the diagnostic switch ( 15, 40 ), whereby one and the same electronic device ( 10, 11 ) can be repeatedly addressed, several diagnostic results in succession from the addressed electronic device ( 10, 11 ) are available.