KR20000056757A - Apparatus and Method for Multichannel Measuring of Magnetic field - Google Patents

Abstract

PURPOSE: A device for measuring magnetic field of multi-channel and its method is provided to prevent that output of standard magnetic field sensor is inputted to noise of other magnetic field sensor by using digitalized compensation magnetic field and to enhance the accuracy at measuring magnetic field by minimizing an error of compensation magnetic field. CONSTITUTION: A device for measuring magnetic field of multi-channel is composed of a standard magnetic field sensor, a magnetic field sensor, compensation coils(CL1-CLN), an A/D convertor(11), a bit rate regulator(12), a revision unit(13), a clock generator(14) and a D/A convertor(15). The standard magnetic field sensor is composed of a SQUID(Superconducting Quantum Interface Device;SQ0), an amp(1) and a feedback coil(FL0) and constructs a FLL(Flux Locked Loop). The magnetic field sensor is composed of SQUIDs(SQ0-SQN), amps(2-4) and a feedback coils(FL1-FLN) and constructs FLLs. The compensation coils(CL1-CLN) compensates the magnetic field according to unshield environment around magnetic field sensors. The A/D convertor(11) converts the analog output of standard magnetic field sensor to digital. The bit rate regulator(12) regulates the bit rate of digital data outputted from the A/D convertor(11) in order to match to operating point of magnetic sensor. The revision unit(13) revises digital data outputted from the bit rate regulator(12) in order to match the characteristic of compensation coils(CL1-CLN). The D/A convertor(15) converts output from the revision unit(13) to analog and provides to the compensation coils(CL1-CLN).

Description

Apparatus and Method for Multichannel Measuring of Magnetic field

The present invention is a multi-channel magnetic field measuring device for detecting the intensity of the magnetic field for the position by arranging a superconducting quantum interference device (SQUID), one of the superconducting elements in an array, generated in an unshielded environment The present invention relates to a multichannel magnetic field measuring device and a method for canceling an excessive magnetic field component that acts as an inhibitory factor in the fine magnetic field measurement of a multichannel magnetic field measuring device.

In general, SQUID is a device that can detect extremely weak magnetic field of about one hundred millionth of the earth's magnetic field. It can detect the spatial distribution of magnetic field or magnetic object through movement.

Therefore, it is widely used in various fields such as measuring instruments, core measuring instruments, submarine detectors, resource probes, and non-destructive inspections as well as magnetic field measurement, in particular, 3D image processing system using magnetic signals. It is becoming.

However, in order to detect minute signals under a large magnetic field present in an unshielded environment, a flux meter in the form of a gradient meter should be used.

In this case, there are two types of magnetic flux measuring instruments. There are two methods of using a SQUID and a method of manufacturing a magnetic pick-up coil in the form of a hardness tester and inputting it into one SQUID.

In particular, in the case of the high temperature superconducting SQUID, since the high temperature superconducting pickup coil is not commercialized, a method of using a plurality of SQUIDs and a method of implementing the hardness measuring coil at the device level have been attempted.

On the other hand, the method using a plurality of SQUID can be divided into a method of detecting the difference by reading each signal of the SQUID and a method of detecting the difference between the reference SQUID, the conventional technique applied to the method of detecting the difference between the reference SQUID According to the multi-channel magnetic field measuring device as shown in Figure 1, the reference magnetic field sensor consisting of SQUID (SQ ₀ ), amplifier (1) and feedback coil (FL ₀ ) to form a flux locked loop (FLL) And magnetic flux consisting of SQUID (SQ ₁ ) (SQ ₂ ) (SQ _n ), amplifiers (2) (3) (4), and feedback coils (FL ₁ ) (FL ₂ ) (FL _n ) for each of n channels. The magnetic field sensor constituting the fixed loop (FLL) and the compensation coil (CL ₁ ) (CL ₂ ) (CL _n ) for canceling the large magnetic field around each magnetic field sensor.

Referring to the operation of the prior art configured as described above is as follows.

The magnetic field measured by the SQUID (SQ ₀ ) of the reference magnetic field sensor is output in the form of voltage, amplified by the amplifier 1 and applied to the respective compensation coils CL ₁ (CL ₂ ) and CL _n .

Subsequently, the peripheral magnetic field applied to each SQUID (SQ ₁ ) (SQ ₂ ) (SQ _n ) is canceled by the offset magnetic field formed in each of the compensation coils CL ₁ (CL ₂ ) and CL _n . The magnetic field measurement value according to the characteristics is output for each channel.

At this time, since the magnetic field measurement values of the magnetic field sensors are different from each other according to their positional characteristics, that is, the distance characteristics, these values are output without being canceled by the offset magnetic field.

Therefore, the magnetic field is detected by detecting the difference between the magnetic field measurement value of each channel and the output value of the reference magnetic field sensor.

However, the multi-channel magnetic field measuring device according to the related art generates the offset magnetic field according to the continuous analog output, and thus has the following problems.

First, since the signal generated by the noise of the SQUID of the reference magnetic field sensor is continuously input to the compensation coil, abnormal crosstalk between the reference magnetic field sensor and the rest of the magnetic field sensor occurs, and this crosstalk propagates to the whole system and is abnormal. The oscillation is enabled, which acts as a noise generating factor, and the resulting noise cannot obtain a desired level of Common Mode Rejection Ratio (CMRR), that is, in-phase removal rate.

Second, an error in the offset magnetic field applied to each magnetic field sensor occurs due to the physical characteristics of each compensation coil, that is, the number of coil turns.

Accordingly, the present invention has been made to solve the above-described problems, and by using the digitized offset magnetic field to prevent the output of the reference magnetic field sensor to be input to the noise of the other magnetic field sensor, An object of the present invention is to provide a multi-channel magnetic field measuring apparatus and method for minimizing errors to improve the accuracy of magnetic field measurement.

The multi-channel magnetic field measuring device according to the present invention comprises a superconducting quantum interference device consisting of two superconducting junctions and a superconducting loop to change external magnetic flux into voltage at both ends of the superconducting junction, and an amplifier for amplifying a voltage difference at one end of the superconducting junction. A plurality of magnetic field sensors having a magnetic flux-locked loop (FLL) are arranged by a feedback coil connected to the output terminal of the amplifier and the other end of the superconducting junction, and one of them is designated as the reference magnetic field sensor so that the output of the reference magnetic field sensor and the output of each magnetic field sensor In the multi-channel magnetic field measuring device for measuring the magnetic field by the difference value, the compensation coil for canceling the magnetic field surrounding the magnetic field sensor by generating a magnetic field proportional to the applied electric signal level and installed to correspond to each magnetic field sensor except the reference magnetic field sensor; To convert analog voltage output of reference magnetic field sensor to digital And a correction unit for correcting the digital data output from the A / D converter according to the characteristics of each compensation coil, and a D / A converter converting the output of the correction unit into an analog electric signal and outputting the analog coil to the compensation coil. It is characterized by.

And adjusting the number of bits of the digital data output from the A / D converter so that the operating point of the magnetic field sensor does not change more than a specific value instantaneously.

In addition, during the dead time for reversing the bias applied to the superconducting quantum interference device, the digital output data of the compensator is converted into an analog electric signal and applied to each compensation coil so as to cancel the magnetic field so as to synchronize the dead time with the D / A converter. And a clock generator for providing the clock pulses.

Another embodiment of the multi-channel magnetic field measuring device according to the present invention consists of two superconducting junctions and a superconducting loop to amplify the voltage difference at one end of the superconducting quantum interference element and the superconducting junction which converts external magnetic flux into voltage at both ends of the superconducting junction. And a plurality of magnetic field sensors having a magnetic flux fixed loop (FLL) formed by a feedback coil connected to an amplifier and an output terminal of the amplifier and the other end of the superconducting junction, and a separate magnetic field sensor that does not use a superconducting quantum interference element. In the multi-channel magnetic field measuring device that measures the magnetic field by the difference between the output of the reference magnetic field sensor and the output of each magnetic field sensor, it is installed to correspond to each magnetic field sensor except the reference magnetic field sensor and is proportional to the applied electric signal level. Compensation coil to generate magnetic field and cancel the magnetic field around magnetic sensor An A / D converter for converting the analog voltage output of the long sensor to digital, a correction unit for correcting the digital data output from the A / D converter according to the characteristics of the respective compensation coils, and an output of the correction unit And a D / A converter which converts the signal into a compensation coil and outputs the compensation coil.

The multi-channel magnetic field measuring method according to the present invention is composed of two superconducting junctions and a superconducting loop, a superconducting quantum interference device for converting external magnetic flux into voltage at both ends of the superconducting junction, and an amplifier for amplifying a voltage difference at one end of the superconducting junction. A plurality of magnetic field sensors having a magnetic flux-locked loop (FLL) are arranged by a feedback coil connected to the output terminal of the amplifier and the other end of the superconducting junction, one of which is designated as the reference magnetic field sensor, and the peripheral magnetic field sensor except for the reference magnetic field sensor In a multi-channel magnetic measuring device having a compensation coil for canceling a magnetic field and the analog output of the reference magnetic field sensor is applied to the compensation coil to cancel the peripheral magnetic field of each magnetic field sensor, converting the analog output of the reference magnetic field sensor to digital To compensate for the characteristics of each compensation coil Is converted into an electrical signal characterized in that the offset is applied by the surrounding magnetic field for each magnetic field sensor to each compensation coil and measuring the magnetic field in accordance with the difference value of the output of the output and the reference magnetic field sensor according to the position characteristics of the magnetic field sensors.

1 is a layout showing the configuration of a multi-channel magnetic field measuring apparatus according to the prior art

2 is a layout showing the configuration of a multi-channel magnetic field measuring apparatus according to the present invention

3 is a graph showing the output characteristics of the multi-channel magnetic field measurement apparatus according to the present invention

* Description of the symbols for the main parts of the drawings *

SQ ₀ to SQ _n : Superconducting quantum interference device 1 to 4: Amplifier

FL ₀ to FL _n : feedback coil CL ₁ to CL _n : compensation coil

11: A / D converter 12: Bit number control unit

13: Corrector 14: Clock Generator

15: D / A Converter

Hereinafter, a preferred embodiment of a multi-channel magnetic field measuring apparatus and method according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a layout showing the configuration of a multi-channel magnetic field measuring apparatus according to the present invention, Figure 3 is a graph showing the output characteristics of the multi-channel magnetic field measuring apparatus according to the present invention.

The multi-channel magnetic field measuring device according to the present invention comprises a reference magnetic field sensor consisting of a SQUID (SQ ₀ ), an amplifier (1) and a feedback coil (FL ₀ ) to form a flux locked loop (FLL), and n channels. Each consists of SQUID (SQ ₁ ) (SQ ₂ ) (SQ _n ), amplifier (2) (3) (4), feedback coil (FL ₁ ) (FL ₂ ) (FL _n ) Compensation coil (CL ₁ ) (CL ₂ ) (CL _n ) for canceling the magnetic field due to the magnetic field sensor and the unshielded environment around each magnetic field sensor, and A / D for converting the analog output of the reference magnetic field sensor to digital Bit number adjusting unit 12 and bit number adjusting unit 12 for adjusting the number of bits of digital data output from the converter 11 and the A / D converter 11 to match the operating point of the magnetic field sensor. The output of the compensator 13 and the compensator 13 for correcting the digital data whose number is adjusted to match the characteristics of each of the compensation coils CL ₁ , CL ₂ and CL _n is converted into analog. The correction unit during the dead time for reversing the bias applied to the SQUID of each magnetic field sensor and the D / A converter 15 provided to each correction coil CL ₁ , CL ₂ , and CL _n . Synchronize with the dead time period in the D / A converter 15 so that the digital output data of (13) is converted to analog and applied to each compensation coil CL ₁ (CL ₂ ) (CL _n ) to achieve magnetic field cancellation. And a clock generator 14 for providing the clock pulse.

Referring to the operation of the present invention configured as described above are as follows.

The magnetic flux converted into a voltage form by SQUID (SQ ₀ ) of the reference magnetic field sensor is amplified by the amplifier 1 and converted into digital data of a predetermined number of bits by the A / D converter 11 to adjust the number of bits 12. ) Is entered.

Subsequently, the bit number adjusting unit 12 adjusts the number of bits of the digital data output from the A / D converter 11 to match the operating point of the magnetic field sensor, and outputs the bit number to the corrector 13.

The correction unit 13 distributes the digital data output from the bit number control unit 12 to each of the compensation coils CL ₁ , CL ₂ , and CL _n , and at the same time, according to a preset value. Correction is made to match the characteristics of each compensation coil CL ₁ , CL ₂ , and CL _n and outputted to the D / A converter 15.

At this time, the digital data correction value set by the correction unit 13 is performed before the actual magnetic field measurement. For example, when a certain level of the experimental magnetic field is applied to the reference magnetic field sensor, the output of the reference magnetic field sensor according to the A / D converter 11, the number of bits adjusting unit 12, the corrector 13 and the D / A converter each compensation coil by way of the _{(15) (CL 1) (} CL 2) (CL n) , each compensation coil _{(CL 1) (CL 2)} (CL n) , so the applied should generate the same magnetic field offset.

In practice, however, a slight error occurs due to the difference in the number of coil turns of each compensation coil, so that each compensation coil CL ₁ (CL ₂ ) (CL _n ) can be corrected through the correction unit 13 to correct this error component. This is to adjust the signal level applied to).

Therefore, when the digital data is output through the correction unit 13 in which the correction value is set in this way, the D / A converter 15 performs the respective compensation coils CL ₁ according to the clock pulse supplied from the clock generation unit 14 ( CL ₂ ) (CL _n ) applies an analog signal.

At this time, the high-temperature superconducting SQUID reduces the low frequency noise caused by fluctuations in the critical current by using the bias reversal method, that is, the method of periodically reversing the applied bias, and the magnetic field measuring operation is performed during the time when the bias reversal is performed. This is called dead time because it is not.

Therefore, canceling the surrounding magnetic field during this dead time can minimize the interference between the signals, so that the D / A converter 15 converts the digital data to analog during this dead time and outputs the analog data according to each compensation coil CL ₁ (CL). ₂ ) The clock generator 14 generates a clock pulse synchronized with the dead time so that CL _n generates an offset magnetic field.

Subsequently, each of the compensation coils CL ₁ , CL ₂ , and CL _n generates an offset magnetic field according to the analog signal during the applied dead time, thereby removing the peripheral magnetic field components applied to each magnetic field sensor. Only the fine magnetic field component according to the characteristic is output through each of the amplifiers 2, 3, and 4.

And the output of each magnetic field sensor is compared with the output of the reference magnetic field sensor, the difference value is output as the actual measured value and the magnetic field measurement is completed.

3 is an example of applying the present invention, the presence of a 10 ³ Φ ₀ ambient magnetic field and the output of the reference magnetic field sensor digitized to 1/4 Φ ₀ level SQUID (SQ ₁ ) (SQ of channel 1 and channel 2 applying the offset magnetic field. _2), and at the same time, channel 1 and channel 2 of the SQUID (SQ ₁₎ (SQ ₂₎ if the gradient (gradient) input for varying the frequency and phase of the Φ ₀ size present in the channel 1 and channel 2 This graph shows the output of CH1 (CH2) and the relative values (CH1-CH2) of channel 1 and channel 2, and the outputs of channel 1 and channel 2 are very noisy due to the application of a digitized offset magnetic field As the level changes, it shows a continuous output, making it possible to make accurate magnetic measurements without noise components.

Theoretically, if the output of the reference magnetic field sensor is digitized to less than 1 / 2Φ level, the desired output can be obtained.However, the magnetic flux is instantaneous if the surrounding magnetic field is severely changed by applying a value slightly smaller than 1 / 2Φ to the offset magnetic field. It is possible to move more than 1 / 2Φ to obtain the desired result, so it is an example of digitization to 1 / 4Φ level in consideration of this point.

In addition, the reference magnetic field sensor in the present invention is configured to provide a reference magnetic field value for forming the offset magnetic field and compare with the output value of the other magnetic field sensor, the core of the present invention is to form an offset magnetic field with a digitized reference magnetic field value, so do not use SQUID. Even if it is replaced by a general magnetic field sensor, if the noise level of the offset magnetic flux due to its own noise is sufficiently smaller than the digital value (for example, 1 / 4Φ), the same effect as using the magnetic field sensor using SQUID can be obtained.

The multi-channel magnetic field measuring apparatus and method according to the present invention has the following effects.

First, since the output of the reference magnetic field sensor is digitized and the offset magnetic field using the digital data is used, the coupling component with the magnetic field sensor can limit the magnetic flux fixing loop of the other magnetic field sensor, thereby ensuring the stability of the system.

Second, since the magnetic field canceling operation is performed during the dead time, inflow noise between the magnetic field sensors can be prevented.

Third, since the signal level for canceling magnetic field formation is appropriately adjusted according to the characteristics of each compensation coil, accurate magnetic field measurement can be performed by reliably canceling out peripheral magnetic field components unnecessary for magnetic field measurement.

Claims (7)

Two superconducting junctions and a superconducting loop, a superconducting quantum interference device for converting external magnetic flux into voltage at both ends of the superconducting junction, an amplifier for amplifying a voltage difference at one end of the superconducting junction, and an output terminal of the amplifier and the other end of the superconducting junction A multi-channel magnetic field is arranged in which a plurality of magnetic field sensors with a magnetic flux-locked loop (FLL) are formed by the feedback coils connected, and one of them is designated as the reference magnetic field sensor and measures the magnetic field by the difference between the output of the reference magnetic field sensor and the output of each magnetic field sensor In the measuring device, A compensation coil installed to correspond to each magnetic field sensor except the reference magnetic field sensor, and generating a magnetic field proportional to an applied electric signal level to cancel the magnetic field around the magnetic field sensor; An A / D converter for converting the analog voltage output of the reference magnetic field sensor into digital; A correction unit for correcting the digital data output from the A / D converter to match the characteristics of the respective compensation coils; And a D / A converter converting the output of the correction unit into an analog electric signal and outputting the compensating coil to each compensation coil. The method of claim 1, And a bit number adjusting unit for adjusting the number of bits of the digital data output from the A / D converter to match the operating point of the magnetic field sensor. The method of claim 1, During the dead time for reversing the bias applied to the superconducting quantum interference device, the digital output data of the compensator is converted into an analog electric signal and applied to each compensation coil to cancel the magnetic field so that the dead time period is applied to the D / A converter. And a clock generator for providing a clock pulse synchronized with the multi-channel magnetic field measuring device. Two superconducting junctions and a superconducting loop, a superconducting quantum interference device for converting external magnetic flux into voltage at both ends of the superconducting junction, an amplifier for amplifying a voltage difference at one end of the superconducting junction, and an output terminal of the amplifier and the other end of the superconducting junction Multiple magnetic field sensors having a magnetic flux-locked loop (FLL) formed by the feedback coils connected to each other are arranged, and a separate magnetic field sensor without superconducting quantum interference elements is designated as the reference magnetic field sensor. In the multi-channel magnetic measuring device for measuring the magnetic field by the difference value, A compensation coil installed to correspond to each magnetic field sensor except the reference magnetic field sensor, and generating a magnetic field proportional to an applied electric signal level to cancel the magnetic field around the magnetic field sensor; An A / D converter for converting the analog voltage output of the reference magnetic field sensor into digital; A correction unit for correcting the digital data output from the A / D converter to match the characteristics of the respective compensation coils; And a D / A converter converting the output of the correction unit into an analog electric signal and outputting the analog coil to the compensation coil. Two superconducting junctions and a superconducting loop, a superconducting quantum interference device for converting external magnetic flux into voltage at both ends of the superconducting junction, an amplifier for amplifying a voltage difference at one end of the superconducting junction, and an output terminal of the amplifier and the other end of the superconducting junction A plurality of magnetic field sensors in which a magnetic flux fixation loop (FLL) is formed by the feedback coils connected are arranged, one of which is designated as a reference magnetic field sensor, and has a compensation coil for canceling the peripheral magnetic field of each magnetic field sensor except for the reference magnetic field sensor. In the multi-channel magnetic field measuring device that the analog output of the reference magnetic field sensor is applied to the compensation coil to cancel the peripheral magnetic field of each magnetic field sensor, By converting the analog output of the reference magnetic field sensor to digital to compensate for the characteristics of each compensation coil, and converting it to analog and applying it to each compensation coil, the magnetic field of each magnetic field sensor is canceled and according to the positional characteristics of each magnetic field sensor And measuring a magnetic field according to a difference between an output and an output of the reference magnetic field sensor. The method of claim 5, The step of correcting the analog output of the reference magnetic field sensor to digital to match the characteristics of each compensation coil And adjusting the number of bits of the digitally converted reference magnetic field sensor to match the operating point of the magnetic field sensor. The method of claim 5, In the step of correcting to match the characteristics of each compensation coil and converting it to analog and applying to each compensation coil And performing the correction and analog conversion operations in synchronization with a dead time for reversing a bias applied to a superconducting quantum interference device.