JP2641882B2 - Device for determining a predetermined trigger point of a sensor signal - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for determining a predetermined trigger point of a sensor signal, and more particularly, to an apparatus for determining a trigger point of a noisy electrical sensor signal that is repeated in time. It is about.

2. Description of the Related Art This type of device is used, for example, to synchronously drive another device using a trigger point derived from a sensor signal. In this case, the physical process of forming the sensor signal must be synchronized with the other device. It is difficult to determine a predetermined trigger point because the sensor signal can be significantly disturbed by internal fluctuations in the physical process monitored by the sensor or by external influences.

German patent publication 3127264 describes a device for determining a trigger point of an electrical signal. The apparatus identifies a disturbance (noise) of a measurement signal to be processed as a disturbance and determines a unique trigger point when the sensor signal has a very large disturbance. This requires that the sensor signal be input to a number of comparators having different threshold levels.

Briefly, the above device operates as follows. That is, when the sensor signal exceeds the threshold of the first comparator, from when the sensor signal exceeds the first threshold to when the sensor signal exceeds the second threshold of the comparator which is larger than the first threshold. A counter for calculating the time length of the timer starts. If the sensor signal is also above the second threshold, the trigger point is determined exactly by when the first threshold is exceeded. If the value exceeds the second threshold value, the trigger point is determined using the time length detected by the counter. In other words, the trigger point is determined retrospectively, and in response to the second threshold, the acquisition of the signals necessary to determine the trigger point is terminated, and the trigger point is determined via information that can be retrieved from the counter. .

[Problems to be Solved by the Invention] The known devices as described above have a drawback that a trigger point cannot be determined in real time, and for many purposes, this determination in real time is desirable or necessary. is there.

Means for Solving the Problems In order to solve the above problems, in the present invention, an apparatus for determining a predetermined trigger point of a time-repeated noisy electric sensor signal is provided. Comparing means (13) for generating an output signal to determine a trigger point when the sensor signal exceeds a second threshold value by comparing with a plurality of threshold values of
Suppressing means for suppressing the output signal from the comparing means for a predetermined period after the trigger point is determined (17)
After the sensor signal rises above the second threshold, falls below a first threshold that is smaller than the second threshold without previously rising above a third threshold that is larger than the second threshold. Means (15) for identifying that a trigger point generated when the sensor signal exceeds a second threshold value is incorrect when the false trigger point is identified. A configuration is adopted in which the threshold is raised and the suppression by the suppression means is stopped.

[Operation] With the above configuration, the trigger point can be determined in real time even when the noise of the sensor signal is very large, so that the repetitive physical process represented by the repetition of the electronic sensor signal and other processes Can be synchronized.

The sensor signal is amplified as needed. The sensor signal is input to a number of comparators having different signal levels as thresholds for processing. The magnitude of the threshold value defining the K-th trigger point is obtained according to the difference (amplitude difference) between the maximum and minimum peak values of the (K-1) -th signal. Thus, the threshold is a relative threshold. False triggering is prevented by suppressing the output signal of the comparator that compares to the second threshold for a period (eg, 0.95T) of less than the length of time (T) between two trigger points. . If noise occurs during a time period in which the noise is not suppressed, the disturbance is detected using two adjacent threshold values. According to the device of the present invention, other information other than the sensor signal is not required for synchronization.

EXAMPLES The present invention will be described in detail with reference to examples shown in the drawings.

The embodiment described below relates to detection of the start of fuel supply of the distribution type injection pump.

In FIG. 1, reference numeral 10 denotes a piezoresistive sensor, the output signal of which is supplied to an amplifier 11. Amplifier 11
Is applied to a peak value memory 12 for storing a positive peak value and a negative peak value of the amplified sensor signal. An amplified sensor signal is supplied to the lead wire 110, and is used for observation using, for example, an oscilloscope. The amplified sensor signal is further applied via a lead 111 to a threshold detector 13 comprising a number of comparators to be compared with respective thresholds described later. The peak value stored in the peak value memory 12 is applied via 120 and 121. The output terminal of the threshold detector 13 is connected via a lead 130 to the pulse forming device 16, to which a suppression signal is supplied via a lead 161. Threshold detector 1
The output terminal of 3 is connected to a trigger pulse monitoring device 15 via a lead 131, and this trigger pulse monitoring device operates the threshold adjustment device 14 and the signal suppression device 17 via a signal line 150. Suppression can be stopped. The signal suppressing device 17 is connected to the pulse forming device 16 via a lead 161, and a signal 160 is supplied to the signal suppressing device 17. The threshold adjuster 14 adjusts the threshold of the threshold detector 13. From the output terminal of the pulse forming device, an original fuel supply start signal 160 and a signal 170 suitable for the engine tester can be extracted.

Next, the function of the apparatus shown in FIG. 1 will be described with reference to the pulse diagrams shown in FIGS. In FIG. 2a, reference numeral 20
What is indicated by is a sensor signal before or after amplification of the sensor 10. This sensor signal is supplied to a peak value memory 12 which stores negative and positive peak values of the sensor signal. In the threshold value detector 13, relative absolute values of the threshold values 210 to 214 are determined according to the stored peak value.
In FIG. 2a, the reference numeral 210 indicates 0% of the signal amplitude.
, The one indicated by reference numeral 214 is the threshold corresponding to 100% of the signal amplitude. 1st, 2nd
And the third threshold are indicated by reference numerals 211, 212, and 213, respectively. Each time the sensor signal 20 exceeds the threshold value 212, a predetermined trigger point is determined. The predetermined trigger point exists at a point indicated by reference numerals 215, 216, and 217, for example. The reference numeral 201 indicates a fuel filling pulse, and the reference numeral 202 indicates a decrease pulse. If appropriate measures are not taken to suppress such noise, the fuel filling pulse 201 will also lose weight 2 pulses.
02 also forms an incorrect trigger point. 2b
In the figure, a period 220 is shown in which the trigger points falling within the period from the trigger points 215 to 216 are suppressed. The length of time to suppress the trigger pulse is sent to the pulse forming device 16 via the lead 161. From the output terminal of the pulse forming device 16, a fuel supply start pulse indicated by reference numeral 230 is extracted. The noise such as the fuel filling pulse and the weight reduction pulse (202, 201) has its comparison signal suppressed, so that an erroneous fuel supply start pulse is not generated without erroneous triggering. The output signal of the pulse forming device 16 is extracted from the output terminal 160 as a fuel supply start pulse, and is extracted from the output terminal 170 as an engine test signal.

The above description shows the function of the device in steady driving with few false triggers. FIG. 2d, on the other hand, shows a sensor signal containing noise which causes a false trigger. 2b, the same reference numerals as in FIG. 1a indicate the same as in FIG. 1a. In the event of an erroneous trigger, the sensor signal first exceeds the second threshold at point 240 but does not reach the third threshold 213 and the first signal at point 241. Below the threshold. By falling below the threshold value 211 at the point 241, this sensor signal is identified by the trigger pulse monitoring device 15 shown in FIG. 1 as noise that causes an erroneous trigger. Since the threshold value adjusting device 14 is operated by the trigger pulse monitoring device, the threshold values 211 and 212 are raised, and the suppression is stopped at the same time. If a noise signal of this type is followed by a pulse that exceeds the threshold 213 after exceeding the threshold 212 or the raised threshold 242, the suppression function is activated first, followed by the threshold. value
242 is gradually reduced. At start-up of the device, the power-on reset signal introduces the same synchronization process already mentioned at the time of the false trigger. Typical values for various thresholds are 7% of maximum amplitude for threshold (211), 10% of maximum amplitude for threshold (212), and maximum amplitude for threshold (213). Of 55
% And the amount of increase of the thresholds 211 and 212 are adjusted to the maximum amplitude, for example, each is increased by about 40%.

In the case of the sensor signal shown in FIG. 3a, the maximum amplitude fluctuates considerably. As a result, the absolute level of the threshold value decreases after the pulse indicated by reference numeral 310, is raised again after the pulse indicated by reference numeral 311 and is lowered again after the pulse indicated by reference numeral 312. To make the figure easier to read, lowering and raising the absolute threshold
And 214 only. Of course threshold 210
To 212 are also raised and lowered according to the maximum amplitude.

 FIG. 3b illustrates the signal suppression function.

The reference numeral 320 indicates the counting state of the first counter, and the reference numeral 321 indicates the counting state of the second counter. Both counters are signal suppression devices of FIG.
17 and is used to determine a signal suppression period. Each counter counts up and down alternately, and the counting direction of the counter changes at each trigger point. The count-up is detected time length T between two trigger points, corresponding to the count state of the up counter when reaching this time length T is one trigger point t _K. When the countdown, when the trigger point has appeared on the basis of the equation _{T = t K -t K-1} , the period must be suppressed which is determined. This period is shorter than T, for example, 0.95T. In FIG. 3c, the suppression signal is indicated by reference numeral 220 (see FIG. 2b), from which the relationship between the suppression signal and the length of time during which the counter is used for countdown can be understood. A region where the device shown in FIG. 1 can mainly output only the fuel supply signal is denoted by reference numeral 34.
Indicated by

It should be noted that, after the trigger point is determined, the period (331) shorter than T (330) is obtained by counting down from the count value of the up counter to a value smaller than the count value. When the second threshold value is raised, the counter is reset. The counting of the counter is performed by inputting to a clock counter from a variable frequency oscillator.

The signal detected by the sensor is a pressure signal or an ignition start signal.

Further, as the sensor, not only a piezoresistive sensor but also a piezo sensor or an ion current sensor can be used.

The present apparatus can be formed in an analog type, but may also be a component of a program stored in a microcomputer. How to implement this device is a matter of design for a person skilled in the art. Therefore, a detailed description of the circuit technology will be omitted.

[Effects of the Invention] As is clear from the above description, according to the present invention, after the sensor signal exceeds the second threshold value and the trigger point is determined, the signal from the comparison means is sent for a predetermined period of time The output signal can be suppressed so that a double trigger does not occur. Further, when the sensor signal falls below the first threshold without exceeding the third threshold after exceeding the second threshold, the signal exceeds the second threshold. The trigger point that occurs sometimes is identified as incorrect,
At this time, since the second threshold value is raised and the suppression by the suppression means is stopped, a correct trigger point can be determined in real time even if the sensor signal is a signal containing noise. This makes it possible to easily synchronize a repetitive physical process represented by repetition of an electric sensor signal with another process.

[Brief description of the drawings]

FIG. 1 is a block circuit diagram of the device of the present invention, and FIGS.
FIGS. 3 (c) and 2d are diagrams illustrating the principle of the apparatus shown in FIG. 1, and FIGS. 3 (a) to 3 (c) are diagrams illustrating a method for removing a fault by signal suppression. 10 Piezoresistive sensor, 11 Amplifier 13 Threshold detector 14 Threshold adjuster 15 Trigger pulse monitor 16 Pulse generator 17 Signal suppressor

Continuation of the front page (56) References JP-A-54-46577 (JP, A) JP-A-59-614 (JP, A)

Claims (18)

(57) [Claims] An apparatus for determining a predetermined trigger point of a noisy electrical sensor signal that is repeated in time, comprising: comparing an amplified sensor signal with a plurality of predetermined thresholds; Comparing means for generating an output signal to determine a trigger point when the threshold value is exceeded (13)
Suppressing means for suppressing the output signal from the comparing means for a predetermined period after the trigger point is determined (17)
After the sensor signal exceeds the second threshold, a first threshold smaller than the second threshold without previously exceeding a third threshold greater than the second threshold. Means (15) for determining that a trigger point generated when the sensor signal exceeds a second threshold value when the value falls below a second threshold value is incorrect; An apparatus for setting a predetermined trigger point of a sensor signal, wherein the threshold value is raised and the suppression by the suppression means is stopped. 2. The method according to claim 1, wherein the output signal of the comparison means obtained by comparison with the second threshold value is equal to T =
Apparatus according to paragraph 1 claims, characterized in that it is suppressed t _k -t _k-1 shorter than the time length determined by the equation period. 3. Apparatus according to claim 1, wherein the time length (T) between the two trigger points is determined by an up-counter. 4. The apparatus according to claim 1, wherein a period shorter than the time length (T) is obtained by a down counter. 5. The apparatus according to claim 1, wherein the count direction of the counter changes for each trigger point. 6. The method according to claim 1, wherein after the trigger point is determined, the countdown is performed from the count value reached by the up counter to a value smaller than the count value. apparatus. 7. Apparatus according to claim 6, wherein the counter is reset when the second threshold is raised. 8. Apparatus according to claim 3, wherein a clock from a variable frequency oscillator is input to the counter. 9. The apparatus according to claim 1, wherein a positive peak value and a negative peak value of said sensor signal are stored. 10. A threshold value for defining a K-th trigger point,
Apparatus according to claim 9, wherein the apparatus is varied according to the amplitude formed from the minimum and maximum values of the (K-1) th sensor signal. 11. The method according to claim 10, wherein the second threshold value is preferably 10 amplitudes.
11. Apparatus according to claim 1, wherein the first threshold value is preferably set to 7% and the third threshold value is preferably set to 55%. . 12. Apparatus according to claim 1, wherein the first and second thresholds are increased by about 40%. 13. The apparatus according to claim 1, wherein the signal detected by the sensor is a pressure signal. 14. The device according to claim 13, wherein the sensor is a piezoresistive sensor. 15. The device according to claim 13, wherein the sensor is a piezoelectric sensor. 16. The apparatus according to claim 1, wherein the fuel supply of the fuel pump is started by a trigger point. 17. The device according to claim 1, wherein the detected signal is an ignition start signal. 18. The apparatus according to claim 17, wherein the sensor is an ion current sensor.