JPH0798370A - Narrow-band film circuit - Google Patents

Abstract

PURPOSE:To provide a narrow-band FLL circuit (magnetic flux lock loop) capable of being applied with a large magnetic feedback signal PHIfnoiseC for removing the unnecessary band signal. CONSTITUTION:This narrow-band FLL circuit 1 is provided with an FLL circuit having a SQUID loop 2, an amplifier 13, and a feedback coil M, negatively feeding back the output of the amplifier 13 to the SQUID (superconducting quantum interference device) loop 2 via the feedback coil M, monitoring the magnetic flux lock loop, and measuring the magnetism value and a narrow-band circuit 15 feeding back the frequency band of the output of the amplifier 13 to the narrow-band SQUID loop 2. The mutual inductance of the feedback coil M is made larger than that of the SQUID loop 2.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention is suitable for biomagnetism measurement such as magnetocardiogram wave, electroencephalogram wave, and eye muscle magnetic field, geomagnetism measurement, or magnetic susceptibility measurement of a substance, and further an interface for magnetic signal transmission. SQUID (Superconducting Qu
antum Interference Device: Superconducting quantum interference device) A FLL circuit (Flux Locked Loop) used for a flux meter. Here, SQUID is
When a magnetic flux from the outside is applied to the SQUID loop, which is a superconducting loop that includes a Josephson junction in the loop and is applied to the SQUID loop while being kept at a low temperature, it circulates in the SQUID loop. Utilizing the fact that a current is induced and a minute change in the applied external magnetic flux appears as a large change in the circulating current due to the quantum interference effect in the Josephson junction in the loop,
It measures a minute change in magnetic flux. The FLL circuit is a circuit including an input coil, a SQUID loop, an amplifier, a feedback coil, and the like. The output voltage of the SQUID is input to the amplifier, and its output is added to the feedback coil to perform negative feedback. It is composed. The magnetic field to be measured can be obtained by monitoring the above feedback amount with an output value.

[0002]

2. Description of the Related Art Conventionally, the applicants have proposed a circuit as shown in FIG. 3 as a narrow band FLL circuit used in a magnetometer or the like. As shown in FIG. 3, the narrow band FLL circuit 21 includes an SQUI including two Josephson junctions 25 and 26.
An amplifier 33 is provided in the D loop (superconducting loop) 22. The magnetic field to be measured is detected by the pickup coil 23, and is coupled to the SQUID loop 22 as an input magnetic flux through the input coil 24. SQU
The coil M _fC adjacent to the ID loop 22 is the first feedback coil. The output of the amplifier 33 is applied as a feedback magnetic flux to the first feedback coil M _fC via the first feedback resistor R _fC . The output of the amplifier 33 is the band narrowing circuit 35, the second
The feedback magnetic flux Φ _fnoiseC is applied to the SQUID loop 22 via the feedback resistor R _fnoiseC and the second feedback coil M _fnoiseC . Band narrowing circuit 35 used in the FLL circuit of FIG.
For example, a Twin-T type band elimination filter or the like can be used. In the narrow band FLL circuit 21 of FIG.
It is characterized in that the band-narrowing circuit 35 is provided separately from the normal feedback system of the FLL circuit. When the band-narrowing circuit is used in this way, the magnetic flux Φ _els containing the signal in the frequency band of the target signal
Is only _fed back to the SQUID loop 22 through R _fC , the cancellation is not so large and the amplitude is larger than that of the signals of other frequency components. The magnetic flux Φ _fnoiseC including signals in other unnecessary bands is _SQUI even through R fnoiseC.
Since it is fed back to the D loop 22, it is canceled at the input side of the narrow band FLL circuit 21, and signals in the unnecessary band (noise component) other than the target signal do not appear at the output V _out side. Therefore, the system is not saturated by external noise other than the target signal (see Japanese Patent Application No. 5-165882).
In the SQUID shown in FIG. 3 described above, in order to simplify the circuit configuration, the coil for inputting the feedback signal to the SQUID loop 22 has a mutual inductance M with respect to the SQUID 22.
_{The fC} was small. In the conventional SQUID 22 configured as above, in order to cancel the large amplitude magnetic flux input signal Φ _fnoiseC in the unnecessary band, this SQUID 22
Same size must add magnetic feedback signal [Phi _NoiseC, its case, the following equation _{Φ noiseC = Φ fnoiseC = MfC ×} I fnoiseC = M fC × V out / R fnoiseC ......... (1) is satisfied .

[0003]

However, in the above formula (1), the output voltage V _out of the narrow band FLL circuit 21 is limited by the power supply voltage of the electronic circuit, and therefore the voltage value cannot be made too large. Therefore, in the above equation (1), the feedback magnetic flux Φ
To increase the value of _fnoiseC , the second feedback resistor R
_{Either fnoiseC} must be set low or the mutual inductance M _fC of the first feedback coil must be set high. However, _if the value of the second feedback resistor R _fnoiseC is set small, the feedback current I _fnoiseC of the feedback system becomes large,
The power consumption of the electronic circuit increases, which causes a practical problem.
The present invention has been made to solve the above problems, and an object of the present invention is to provide a narrow band FLL circuit capable of applying a large magnetic feedback signal Φ _fnoiseC for removing unwanted band signals. And

[0004]

In order to solve the above problems, a narrow band FLL circuit according to the present invention has an SQUID loop, an amplifier and a feedback means, and outputs the output of the amplifier by the feedback means. F that measures the magnetic value by negatively feeding back to the loop and monitoring the magnetic flux lock loop
A narrow band FLL circuit comprising an LL circuit and a narrow band circuit for narrowing the frequency band of the output of the amplifier and feeding back to the SQUID loop, wherein the feedback means has a mutual inductance with respect to the SQUID loop. It is configured with a large feedback coil.

[0005]

According to the present invention having the above-mentioned structure, the SQUID can be realized without unnecessarily increasing the power consumption of the electronic circuit.
Since the mutual inductance of the feedback coil for negative feedback to the loop is set to be large, the above equation (1)
As a result, the feedback magnetic flux value to be fed back to the SQUID loop can be increased, and even if a large amplitude signal is generated in the unnecessary band, it can be easily canceled.

[0006]

Embodiments of the present invention will be described below with reference to the drawings. First, the first embodiment of the present invention is shown in FIG. In this embodiment, the mutual inductance of the SQUID loop of the feedback coil for applying the feedback magnetic flux for removing the unwanted band signal to the SQUID loop of the narrow band FLL circuit already proposed is made larger than that of the conventional one.

That is, as shown in FIG. 1, the narrow band FLL circuit 1A includes two Josephson junctions 5A and 6A.
A superconducting loop (SQUID loop) 2A including a bias current source and an amplifier 13A (not shown) is provided. The magnetic field to be measured is the pickup coil 3A.
Detected by the input coil 4A and input magnetic flux Φ
It is coupled to the SQUID loop 2A as _in. SQUI
Of the coils adjacent to the D loop 2A, M _fA is the first feedback coil. The output of the amplifier 13A is the first feedback resistor R
_A feedback magnetic flux Φ _fA is applied to the first feedback coil M _fA via _fA . On the other hand, the output of the amplifier 13A is applied as feedback magnetic flux to the SQUID loop 2A via the band narrowing circuit 15A and the second feedback coil M _fnoiseA .

In this case, the inductance value M _fA of the first feedback coil and the inductance value M of the second feedback coil
_The following equation M _fnoiseA >> M _fA ... (2) is established between _fnoiseA and _fnoiseA . For example, the value of M _fnoiseA is 1 of the value of M _fA.
For example, 00 times.

According to the above equation (1), the above configuration makes it possible to increase the value of the feedback magnetic flux Φ _fnoiseA for canceling the input signal in the unnecessary band in the state of FIG. In this embodiment, as shown in FIG.
Since the signal in the frequency band of the target signal is fed back to the SQUID a little compared to the signals in other frequency bands, the output amplitude becomes large, but the signals in the other unnecessary bands are narrowed by the narrowing circuit 15A and the first feedback circuit. Since it is _fed back through the resistor R _fnoiseA and the first feedback coil M _fnoiseA , it is canceled at the input side of this FLL circuit, and signals in the unnecessary band other than the target signal do not appear at the output V _out side. Therefore,
The system will not be saturated by external noise other than the target signal.

Next, a second embodiment of the present invention is shown in FIG.
This embodiment is common to the first embodiment in that it is configured by adding a narrow band circuit 15B having a band elimination type transfer characteristic to a conventional FLL circuit, but the narrow band circuit 1
It differs from the first embodiment in that a feedback circuit system including 5B is connected to the input coil 4B side of the FLL circuit. According to this structure, the input coil, which originally has a larger mutual inductance than the feedback coil, can also be used as the feedback coil for removing the unwanted band signal, and the number of parts can be saved as compared with the first embodiment.

The present invention is not limited to the above embodiment. The above-mentioned embodiment is an exemplification, has substantially the same configuration as the technical idea described in the scope of the claims of the present invention, and has any similar effect to the present invention. It is included in the technical scope of the invention.

[0012]

As described above, according to the present invention having the above structure, the mutual inductance of the feedback coil for negatively feeding back to the SQUID loop is set to a large value without unnecessarily increasing the power consumption of the electronic circuit. By doing so, the feedback magnetic flux value to be fed back to the SQUID loop can be increased from the above equation (1), and even if a large amplitude signal occurs in the unnecessary band, this can be easily canceled.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of a SQUID for a narrow band FLL circuit that is a first embodiment of the present invention.

FIG. 2 is a circuit diagram showing a configuration of a SQUID for a narrow band FLL circuit which is a second embodiment of the present invention.

FIG. 3 is a circuit diagram showing a configuration of a conventional SQUID for a narrow band FLL circuit.

[Explanation of symbols]

1A, 1B narrow band FLL circuit 2A, 2B SQUID loop 3A, 3B pickup coil 4A, 4B input coil 5A, 5B Josephson junction 6A, 6B Josephson junction 13A, 13B amplifier 15A, 15B narrow band circuit 21 narrow band FLL circuit 22 SQUID Loop 23 Pickup Coil 24 Input Coil 25,26 Josephson Junction 33 Amplifier 35 _Narrowing Band M _fA , M _fB , M _fC First Feedback Coil M _fnoiseA Second Feedback Coil R _fA , R _fB , R _fC First Feedback resistance R _fnoiseA , R _fnoiseB , R _fnoiseC Second feedback resistance

Claims (1)

[Claims] 1. An SQUID loop, an amplifier, and a feedback means are provided, and the output of the amplifier is sent to the S output by the feedback means.
A FLL circuit that measures a magnetic value by negatively feeding back to a QUID loop and monitoring a magnetic flux lock loop; and a narrower frequency band of the output of the amplifier, and the SQU.
A narrowband FLL circuit including: a narrowband circuit that feeds back to an ID loop, wherein the feedback unit includes a feedback coil having a large mutual inductance with respect to the SQUID loop. circuit.