CN106646316A - Method for testing noise of switching-type Hall sensor - Google Patents

Abstract

The invention discloses a method for testing the noise of a switching-type Hall sensor. The method indirectly tests the noise performance of the sensor by observing the power-up process of the sensor and comprises steps of: placing the switching-type Hall sensor in a magnetic field generator; powering the sensor with a square signal output by a signal generator, wherein the amplitude of the square signal is from 0 to VDD, the VDD is the operating voltage of the sensor chip, the cycle of the square signal is 2*(Tpu + N*Ts), Tpu is the power-up time of the sensor chip, Ts is the sampling cycle of the sensor chip, N is an integer between 5 and 10, the duty cycle of the square signal is 50%; detecting the output of the sensor with a oscilloscope, wherein the oscilloscope is configured to be triggered by rising edges, a trigger source is a square wave generated by a signal generator, and persistence time is set as infinity. The method obtains a high-frequency power supply voltage source by using the signal generator on the premise of the known power-up initial state of the chip, and obtains the upper and lower limits of the BOP/BRP by observing the statistical characteristic of the power-up process of the sensor so as to obtain the noise characteristics of the switching-type Hall sensor.

Description

The method of testing of Hall switch sensor noise

Technical field

The invention belongs to sensor testing techniques field, is related to a kind of sensor noise method of testing, more particularly to it is a kind of The method of testing of Hall switch sensor noise.

Background technology

Hall element is a kind of magnetic field sensor made according to Hall effect, widely should be had in the automotive industry With, including power, Body Control, polling power controlling and anti-lock braking system etc..In order to meet the needs of different system, suddenly You are divided into two kinds of line style Hall element and Hall switch sensor by sensor.One as Hall element of noiseproof feature Important indicator, plays most important to Hall element, the especially design of high sampling rate high accuracy Hall switch sensor Effect.Concrete manifestation of the noise in Hall switch sensor is exactly that the turn threshold for causing sensor occurs random change Change.

It is the input-output characteristic of a preferable bipolar switch Hall element shown in Fig. 1：Abscissa Bin is input Magnetic field intensity, ordinate HALL_OUT is output level (" 0 " represents low level, and " 1 " represents high level).It can be seen that working as Bin> During BOP, the output of sensor is by high step-down；Work as Bin<BRP is that the output of sensor is uprised by low；BHYS=BOP-BRP is defined For the retarding window of Hall switch sensor.After having noise superposition to come in, the input and output of Hall switch sensor Characteristic changes, as shown in Figure 2：The turn threshold (BOP/BRP) of sensor understands random fluctuation, and the size of random fluctuation is received The impact of the length of noise size and observation time.

It is as shown in Figure 3 in the traditional test methods of laboratory environment breaker in middle type Hall element：Sensor is positioned over In one-dimensional magnetic field environment, and it is powered with source of stable pressure, with the output of universal meter detection sensor；If being output as " 0 ", no Until its upset is " 1 ", now corresponding magnetic field intensity is BRP to record to the disconnected magnetic field intensity that reduces；If being output as " 1 ", no Disconnected increasing magnetic field is " 0 " until its upset, and now corresponding magnetic field intensity is BOP to record.This method of testing, due to magnetic The pace of change of field intensity is too slow, can only often measure the lower limit (BOPB and BRPB in Fig. 2) of BOP and BRP.And switching mode is suddenly That working sensor is in two kinds of different states：After BOP (or BRP) has been tested, Hall element can be switched to other one Individual state, thus the upper limit (BOPT and BRPT in Fig. 2) for wanting test b OP and BRP is accomplished by producing the alternation of a high frequency Magnetic field.

However, regrettably, at present most magnetic field generator cannot all produce the alternating magnetic field of high frequency, thus survey The noiseproof feature of examination Hall switch sensor BOP/BRP also becomes abnormal difficult.

The content of the invention

The technical problem to be solved is：A kind of method of testing of Hall switch sensor noise is provided, can The noiseproof feature of accurate test Hall switch sensor BOP/BRP.

To solve above-mentioned technical problem, the present invention is adopted the following technical scheme that：

A kind of method of testing of Hall switch sensor noise, the method for testing is the upper electric mistake by observing sensor Journey, measures the noiseproof feature of sensor indirectly：Hall switch sensor is positioned in magnetic field generator；Use signal generator To sensor power, the amplitude of square-wave signal is 0 to VDD to the square-wave signal of output, and VDD is the operating voltage of sensor chip, Cycle is 2* (Tpu+N*Ts), and Tpu is the power-on time of sensor chip, and Ts is the sampling period of sensor chip, and N takes 5 and arrives Integer between 10, dutycycle is 50%；With the output of oscillograph detection sensor, oscillograph is set to rising edge triggering, tactile Rise the square wave produced for signal generator, and sunset glow set of time is infinity；

If the upper electric initial state of sensor chip is " 1 ", start to incrementally increase magnetic field intensity from Bin=0, often arrange one Secondary magnetic field intensity Bin, is required for removing an oscillograph sunset glow manually；

When 0<=Bin<BOPB, the first output waveform VOUT_1 of sensor is approximately equal to the output wave of signal generator Shape, when signal generator exports high level, the output of sensor is also always high level, is not in upset situation；

Work as Bin>BOPB, when signal generator exports high level, output waveform VOUT_2 of sensor can be with relatively low There is the situation of upset in probability；

Work as BOPB<Bin<BOPT, with being continuously increased for Bin, when signal generator exports high level, sensor output The probability of upset also more and more higher, while the time point of upset is also increasingly to reach；

Work as Bin>BOPT, when signal generator exports high level, first that sensor will be after the power-up sampled point Overturn；

According to observed result above, VOUT_1 magnetic field intensities corresponding with the critical value of VOUT_2 are exactly BOPB, VOUT_ 4 magnetic field intensities corresponding with the critical value of VOUT_5 are exactly BOPT；In the same manner, if the upper electric initial state of sensor chip is " 0 ", Start progressively to reduce magnetic field intensity from Bin=0, just determine the lower limit BRPB and upper limit BRPT of BRP；

Wherein, VOUT_1 is 0<=Bin<The output waveform of sensor during BOPB；VOUT_2 be Bin less times greater than BOPB when The output waveform of sensor；VOUT_3 represents that Bin is continuously increased the probability of caused sensor output waveform upset and becomes big, VOUT_4 represents that Bin further increases the time point of caused sensor output waveform upset to reach；VOUT_5 is Bin> The output waveform of sensor during BOPT.

A kind of method of testing of Hall switch sensor noise, by the power up for observing sensor, measures indirectly The noiseproof feature of sensor；

Hall switch sensor is positioned in magnetic field generator；With the square-wave signal of signal generator output to sensing Device is powered, and the amplitude of square-wave signal is 0 to VDD, and VDD is the operating voltage of sensor chip, and the cycle is 2* (Tpu+N*Ts), Tpu is the power-on time of sensor chip, and Ts is the sampling period of sensor chip, and N takes the integer between 5 to 10, dutycycle For 50%；

With the output of oscillograph detection sensor, oscillograph is set to rising edge triggering, and trigger source is that signal generator is produced Raw square wave, sunset glow set of time is infinity.

As a preferred embodiment of the present invention, if the upper electric initial state of sensor chip is " 1 ", from the beginning of Bin=0 Incrementally increase magnetic field intensity；If the upper electric initial state of sensor chip is " 0 ", start progressively to reduce magnetic field from Bin=0 strong Degree；Primary field intensity Bin is often set, is required for removing an oscillograph sunset glow manually.

As a preferred embodiment of the present invention, when 0<=Bin<BOPB, the first output waveform VOUT_1 of sensor is near The approximately equal to output waveform of signal generator, when signal generator exports high level, the output of sensor is also always high electricity It is flat, be not in upset situation；

Work as Bin>BOPB, when signal generator exports high level, output waveform VOUT_2 of sensor can be with relatively low There is the situation of upset in probability；

Work as BOPB<Bin<BOPT, with being continuously increased for Bin, when signal generator exports high level, sensor output The probability of upset also more and more higher, while the time point of upset is also increasingly to reach；

Work as Bin>BOPT, when signal generator exports high level, first that sensor will be after the power-up sampled point Overturn.

Used as a preferred embodiment of the present invention, according to above-mentioned observed result, VOUT_1 is corresponding with the critical value of VOUT_2 Magnetic field intensity be exactly the corresponding magnetic field intensity of critical value of BOPB, VOUT_4 and VOUT_5 be exactly BOPT；In the same manner, if sensing The upper electric initial state of device chip is " 0 ", then start progressively to reduce magnetic field intensity from Bin=0, just determines the lower limit BRPB of BRP and upper Limit BRPT；

Wherein, VOUT_1 is 0<=Bin<The output waveform of sensor during BOPB；VOUT_2 be Bin less times greater than BOPB when The output waveform of sensor；VOUT_3 represents that Bin is continuously increased the probability of caused sensor output waveform upset and becomes big, VOUT_4 represents that Bin further increases the time point of caused sensor output waveform upset to reach；VOUT_5 is Bin> The output waveform of sensor during BOPT.

The beneficial effects of the present invention is：The method of testing of Hall switch sensor noise proposed by the present invention, Know on chip on the premise of electric initial state, using signal generator generation high frequency supply voltage source, by observing electric mistake on sensor The statistical property of journey obtains the upper and lower bound of BOP/BRP, so as to draw the noise characteristic of Hall switch sensor.This does The benefit of method is the low frequency feature for replacing magnetic field generator using the high frequency characteristics of signal generator, completes Hall switch biography The noise testing of sensor, is increased without extra equipment and expense.

Description of the drawings

Fig. 1 is the input-output characteristic of preferable bipolar switch Hall element.

Fig. 2 is the input-output characteristic of bipolar switch Hall element affected by noise.

Fig. 3 is the conventionally test schematic diagram of Hall switch sensor.

Fig. 4 is the novel test schematic diagram of Hall switch sensor noiseproof feature.

Fig. 5 is output voltage in Hall switch sensor power up with the variation relation of Bin.

Specific embodiment

Describe the preferred embodiments of the present invention in detail below in conjunction with the accompanying drawings.

Embodiment one

Present invention is disclosed a kind of method of testing of Hall switch sensor noise, the method for testing is by observing biography The power up of sensor, measures the noiseproof feature of sensor indirectly, and test philosophy figure is shown in figure (4)：By Hall switch sensor In being positioned over magnetic field generator；With the square-wave signal of signal generator output to sensor power, the amplitude of square-wave signal is arrived for 0 VDD, VDD are the operating voltages of sensor chip, and the cycle is 2* (Tpu+N*Ts), Tpu for sensor chip power-on time, Ts For the sampling period of sensor chip, N takes the integer between 5 to 10, and dutycycle is 50%；It is defeated with oscillograph detection sensor Go out, oscillograph is set to rising edge triggering, trigger source is the square wave that signal generator is produced, and sunset glow set of time is infinity.

If the upper electric initial state of sensor chip is " 1 ", start to incrementally increase magnetic field intensity from Bin=0；If sensing The upper electric initial state of device chip is " 0 ", then start progressively to reduce magnetic field intensity from Bin=0；Primary field intensity Bin is often set, all Need to remove an oscillograph sunset glow manually.

When 0<=Bin<BOPB, the first output waveform VOUT_1 of sensor is approximately equal to the output wave of signal generator Shape, when signal generator exports high level, the output of sensor is also always high level, is not in upset situation.Such as Fig. 5 In VDD for signal generator output waveform, the VOUT_1 in Fig. 5 be 0<=Bin<The output waveform of sensor during BOPB.

Work as Bin>BOPB, when signal generator exports high level, the output of sensor can occur turning over relatively low probability Situation about turning.If the VOUT_2 in Fig. 5 is output waveforms of the Bin less times greater than sensor during BOPB.

Work as BOPB<Bin<BOPT, with being continuously increased for Bin, when signal generator exports high level, sensor output The probability of upset also more and more higher, while the time point of upset is also increasingly to reach.As figure (5) in VOUT_3 be Bin not The disconnected probability for increasing caused sensor output switching activity becomes big situation, and it is that further increase causes Bin to scheme the VOUT_4 in (5) Sensor output switching activity time point to reach situation.

Work as Bin>BOPT, when signal generator exports high level, first that sensor will be after the power-up sampled point Overturn.If the VOUT_5 in Fig. 5 is Bin>The output waveform of sensor during BOPT.

According to observed result above, VOUT_1 magnetic field intensities corresponding with the critical value of VOUT_2 are exactly BOPB, VOUT_ 4 magnetic field intensities corresponding with the critical value of VOUT_5 are exactly BOPT；In the same manner, if the upper electric initial state of sensor chip is " 0 ", Start progressively to reduce magnetic field intensity from Bin=0, just can determine the lower limit BRPB and upper limit BRPT of BRP.

In sum, the method for testing of Hall switch sensor noise proposed by the present invention, electricity is first in known chip On the premise of state, high frequency supply voltage source is produced using signal generator, by the statistical property for observing sensor power up The upper and lower bound of BOP/BRP is obtained, so as to draw the noise characteristic of Hall switch sensor.The benefit of this way is profit With the high frequency characteristics of signal generator, replace the low frequency feature of magnetic field generator, the noise for completing Hall switch sensor is surveyed Examination, is increased without extra equipment and expense.

Here description of the invention and application are illustrative, are not wishing to limit the scope of the invention to above-described embodiment In.The deformation and change of embodiments disclosed herein is possible, real for those skilled in the art The replacement and equivalent various parts for applying example is known.It should be appreciated by the person skilled in the art that without departing from the present invention Spirit or essential characteristics in the case of, the present invention can in other forms, structure, arrangement, ratio, and with other components, Material and part are realizing.In the case of without departing from scope and spirit of the present invention, embodiments disclosed herein can be entered Other deformations of row and change.

Claims (5)

1. a kind of method of testing of Hall switch sensor noise, it is characterised in that the method for testing is by observing sensing The power up of device, measures the noiseproof feature of sensor indirectly：Hall switch sensor is positioned in magnetic field generator；With To sensor power, the amplitude of square-wave signal is 0 to VDD to the square-wave signal of signal generator output, and VDD is sensor chip Operating voltage, the cycle is 2* (Tpu+N*Ts), and Tpu is the power-on time of sensor chip, and Ts is all for the sampling of sensor chip Phase, N takes the integer between 5 to 10, and dutycycle is 50%；With the output of oscillograph detection sensor, oscillograph is set to rise Along triggering, trigger source is the square wave that signal generator is produced, and sunset glow set of time is infinity；

If the upper electric initial state of sensor chip is " 1 ", start to incrementally increase magnetic field intensity from Bin=0, a magnetic is often set Field intensity Bin, is required for removing an oscillograph sunset glow manually；

When 0<=Bin<BOPB, the first output waveform VOUT_1 of sensor is approximately equal to the output waveform of signal generator, During signal generator output high level, the output of sensor is also always high level, is not in upset situation；

Work as Bin>BOPB, when signal generator exports high level, output waveform VOUT_2 of sensor can be with relatively low probability There is the situation of upset；

Work as BOPB<Bin<BOPT, with being continuously increased for Bin, when signal generator exports high level, sensor output switching activity Probability also more and more higher, while the time point of upset is also increasingly to reach；

Work as Bin>BOPT, when signal generator exports high level, first that sensor will be after the power-up sampled point occurs Upset；

According to observed result above, VOUT_1 magnetic field intensities corresponding with the critical value of VOUT_2 are exactly BOPB, VOUT_4 with The corresponding magnetic field intensity of critical value of VOUT_5 is exactly BOPT；In the same manner, if the upper electric initial state of sensor chip is " 0 ", from Bin=0 starts progressively to reduce magnetic field intensity, just determines the lower limit BRPB and upper limit BRPT of BRP；

Wherein, VOUT_1 is 0<=Bin<The output waveform of sensor during BOPB；VOUT_2 is that Bin is sensed less times greater than during BOPB The output waveform of device；VOUT_3 represents that Bin is continuously increased the probability of caused sensor output waveform upset and becomes big, VOUT_4 tables Show that Bin further increases the time point of caused sensor output waveform upset to reach；VOUT_5 is Bin>Sense during BOPT The output waveform of device.

2. a kind of method of testing of Hall switch sensor noise, it is characterised in that by the power up for observing sensor, The noiseproof feature of sensor is measured indirectly；

Hall switch sensor is positioned in magnetic field generator；The square-wave signal exported with signal generator is supplied sensor Electricity, the amplitude of square-wave signal is 0 to VDD, and VDD is the operating voltage of sensor chip, and the cycle is 2* (Tpu+N*Ts), and Tpu is The power-on time of sensor chip, Ts is the sampling period of sensor chip, and N takes the integer between 5 to 10, and dutycycle is 50%；

With the output of oscillograph detection sensor, oscillograph is set to rising edge triggering, and trigger source is what signal generator was produced Square wave, sunset glow set of time is infinity.

3. the method for testing of Hall switch sensor noise according to claim 2, it is characterised in that：

If the upper electric initial state of sensor chip is " 1 ", start to incrementally increase magnetic field intensity from Bin=0；If sensor core The upper electric initial state of piece is " 0 ", then start progressively to reduce magnetic field intensity from Bin=0；Primary field intensity Bin is often set, is required for An oscillograph sunset glow is removed manually.

4. the method for testing of Hall switch sensor noise according to claim 2, it is characterised in that：

When 0<=Bin<BOPB, the first output waveform VOUT_1 of sensor is approximately equal to the output waveform of signal generator, During signal generator output high level, the output of sensor is also always high level, is not in upset situation；

Work as Bin>BOPB, when signal generator exports high level, output waveform VOUT_2 of sensor can be with relatively low probability There is the situation of upset；

Work as BOPB<Bin<BOPT, with being continuously increased for Bin, when signal generator exports high level, sensor output switching activity Probability also more and more higher, while the time point of upset is also increasingly to reach；

Work as Bin>BOPT, when signal generator exports high level, first that sensor will be after the power-up sampled point occurs Upset.

5. the method for testing of Hall switch sensor noise according to claim 4, it is characterised in that：

According to above-mentioned observed result, VOUT_1 magnetic field intensities corresponding with the critical value of VOUT_2 are exactly BOPB, VOUT_4 with The corresponding magnetic field intensity of critical value of VOUT_5 is exactly BOPT；In the same manner, if the upper electric initial state of sensor chip is " 0 ", from Bin=0 starts progressively to reduce magnetic field intensity, just determines the lower limit BRPB and upper limit BRPT of BRP；

Wherein, VOUT_1 is 0<=Bin<The output waveform of sensor during BOPB；VOUT_2 is that Bin is sensed less times greater than during BOPB The output waveform of device；VOUT_3 represents that Bin is continuously increased the probability of caused sensor output waveform upset and becomes big, VOUT_4 tables Show that Bin further increases the time point of caused sensor output waveform upset to reach；VOUT_5 is Bin>Sense during BOPT The output waveform of device.