JPH04160380A - Digital squid flux meter - Google Patents

Abstract

PURPOSE:To prevent the resonance of a input and output part of SQUID and control the generation of a noise magnetic flux by using the meter so that a shunt resistor for dumping may become an open state when a bias current is applied to SQUID. CONSTITUTION:When a bias current 21 is supplied to SQUID 1 from a pulse generator 2, a switch 8 is put off and, when the current 21 is put off, the switch 8 is turned on. Thus, only when the current 21 of SQUID 1 is turned off, the switch 8 is turned on to connect a shunt resistor 7 to an input and output circuit part. Further an outside magnetic flux PHI is transmitted to SQUID 1 through a pickup coil 3 and an input coil 4. And an output pulse during the time in which the magnetic field is negated by the magnetic field of a feedback coil 6 is counted in a detection part 5 to measure a magnetic flux PHI. At this time an positive (negative) output pulse to an positive (negative) magnetic flux PHIis synchronized with the current 21 to obtain.

Description

[Detailed Description of the Invention] [Summary] Regarding digital SQUID magnetometers that measure minute magnetic fields generated from living organisms etc. with high sensitivity, we have developed a shunt resistor that prevents resonance in the input/output circuit portion of the SQUID and that prevents resonance. In order to suppress the generation of noise magnetic flux caused by the magnetic flux, the SQUID is supplied with a pulsed bias current and the external magnetic flux picked up by the pickup coil is transmitted through the input coil, thereby outputting pulses in response to this external magnetic flux. Furthermore, in a digital SQUID magnetometer in which a shunt resistor of t is provided at a predetermined portion for damping operation, a switch is provided to switch the shunt resistor between an operating state and a non-operating state, and the switch is provided to synchronize with the pulsed bias current. The shunt resistor is switched to a non-operating state using the switching signal during the period when the bias current is supplied to the SQUID.

[Industrial application field]

The present invention is a digital SQUID magnetometer, especially a digital SQUID flux meter that measures minute magnetic fields generated from living bodies etc. with high sensitivity.
Regarding QUID magnetometer.

By measuring the magnetic field distribution generated by active currents accompanying the excitation of muscles and nerves in the body, especially in the brain, lungs, and heart, it is possible to estimate the current source generating the magnetic field. . It has been pointed out that this provides very meaningful diagnostic information and is useful for elucidating muscle and nerve activity in the living body. The digital SQUID magnetometer of the present invention can be used not only as a biomagnetism detector, but also for searching for magnetic monopoles, measuring earth currents,
It can also be used to measure rock magnetism.

[Conventional technology]

FIG. 7 is an explanatory diagram showing a conventional digital SQUID magnetometer.

In the figure, 71 is a SQUID and includes a Josephson junction.

Further, 72 is a pulse generator that outputs a bias current to the SQUID 71, 73 is a pickup coil for picking up the external magnetic flux Φ, and 74 is an input coil that forms a loop with the pickup coil to transmit the external magnetic flux Φ to the SQUID 71. be.

In addition, 75 is an up/down counter (
an integrator consisting of a detection unit) 79 and a D/^ converter 80;
76 is a feedback coil for generating a feedback magnetic field based on the output current of the integrator 75.

Further, 77 is a shunt resistor for suppressing resonance, and 78 is a stray capacitance.

Here, when the external magnetic flux Φ is applied to the SQUID 71, the output current corresponding to the number of output pulses is caused by negative feedback to the SQUID.
A feedback magnetic field is generated that flows through the feedback coil 76 placed near the D71 and cancels the magnetic field of the SQUID 71. Then, until this feedback magnetic field cancels the magnetic field of the SQUID 71, high-frequency pulses are output depending on the positive or negative of the fluctuation value of the external magnetic flux Φ. It is possible to measure the amount of magnetic flux applied from the

It has also been proposed to perform the functions of the up-down counter and the D/A converter using a write gate and a superconducting inductance (Japanese Patent Laid-Open No. 63-29097
No. 9).

In such a digital SQUID magnetometer, the output pulse of the SQUID 71 is connected to the input coil 74.
．． Pickup coil 73. Resonance may occur in circuit parts such as the stray capacitance 78, and this resonance phenomenon appears prominently in superconducting circuits where signals change at high speed. Furthermore, if the loss in the circuit is small, this vibration will remain until the next bias current is applied and cause a defective operation, so a shunt resistor 77 is provided to suppress the previous resonance.

[Problem to be solved by the invention]

In order to suppress the above-mentioned resonance, it is necessary to reduce the resistance value of the shunt resistor and increase the loss due to this resistance.

However, a resistor generates thermal noise current, and its value increases as the resistance value decreases. This thermal noise current then flows through the input coil and becomes noise magnetic flux.

Therefore, as the resistance value of the shunt resistor is decreased in an attempt to suppress the previous resonance, the noise magnetic flux increases and the S/N ratio decreases. This becomes more noticeable as the bias frequency becomes higher, as the period becomes shorter.

Therefore, in the present invention, when a bias current is applied to the SQUID, the shunt resistor for damping is placed in an oven state to prevent resonance in the input/output circuit portion of the SQUID and to reduce the noise magnetic flux caused by the shunt resistor. The aim is to reduce the occurrence of

[Means to solve the problem]

FIG. 1 is a diagram explaining the principle of the present invention.

In the figure, 1 is a SQUID, which is ring-shaped and includes a Josephson junction.

2 is a pulse generator which outputs a bias current 21 and a switching signal 22 (see FIG. 2).

3 is a pickup coil, which picks up external magnetic flux Φ.

4 is an input coil, which transmits external magnetic flux Φ to 5QtJID.

5 is a detection unit that counts the output pulses of the SQUID and obtains the external magnetic flux Φ.

6 is a feedback coil that cancels the magnetic field of the SQUID.

A shunt resistor 7 prevents the output pulse of the SQUID from resonating in circuit parts such as the input coil, pickup coil, and stray capacitance.

8 is a switch, which is operated by a switching signal 22.

The digital SQUID magnetometer of the present invention consists of the above-mentioned components. Note that in a device that only determines the presence or absence of the external magnetic flux Φ, it is not necessary to provide the feedback coil 6.

[Effect]

The operation of the present invention will be explained with reference to FIGS. 1 and 2.

In the figure, the bias current 21 is a high frequency pulse,
The switching signal (current) 22 is a signal that has a level that turns off the switch 8 when the bias current 21 is "0". Therefore, from pulse generator 2
When the bias current 21 is supplied to IDI, the switch 8 is turned off, and when the bias current 21 is cut off, the switch 8 is turned on.

In this way, only when the bias current 21 of the SQUID 1 is turned off, the switch 8 is turned on to connect the shunt resistor 7 to the input/output circuit portion of the SQUID.

Note that the external magnetic flux Φ is the pickup coil 3. It is transmitted to SQUIDI via input coil 4. Then, the value (positive or negative) of the external magnetic flux Φ is measured by counting the output pulses in the detection unit 5 until this magnetic field is canceled by the magnetic field of the feedback coil 6. At this time, a positive output pulse is obtained in response to a positive external magnetic flux Φ, and a negative output pulse is obtained in response to a negative external magnetic flux Φ, respectively, in synchronization with the bias current 21.

〔Example〕

The present invention will be described in detail with reference to FIGS. 3 to 6.

FIG. 3 is an explanatory diagram showing the first embodiment, and 311;
sQUID, 32 is a pulse generator, 33 is a pickup coil, 34 is an input coil forming a loop with the pickup coil, 35 is an up/down counter (detection section) 4
3 and an integrator consisting of a D/A converter 44, 36 a feedback coil, 37 a shunt resistor to suppress resonance, 38 an analog switch, 39 a stray capacitance, 42
is a switching signal for controlling on/off of the analog switch, and 41 is a bias current of the SQUID.

Here, the switching signal 42 and the bias current 4
1 are the same as the switching signal 22 and bias current 21 in FIG. 2, respectively.

And the bias current 41 is S Q U I D 3H
, m is supplied, the analog switch is turned off by the switching signal 42 and the shunt resistor 37 is not connected in parallel to the input coil 34, so the thermal noise current of the shunt resistor 37 flows to the input coil 34. No noise magnetic flux is generated. Note that the operation when measuring the external magnetic flux Φ with the up-down counter (detection section) 43 is the same as that described above as the operation of the present invention.

In addition, the shunt resistor 37 can perform the most effective damping action when the critical damping condition R = 1/2 (L/C) "'. Note that R is the value of the shunt resistor, and L is the value of the input coil. , C is the value of inductance of a pickup coil, etc., and C is the value of stray capacitance.

Further, the input/output circuit portion of the SQUID 31 is formed of a superconducting coil, a superconducting wire, a superconducting thin film, and the like. Furthermore, by configuring the up/down counter (detection section) 43 with a superconducting inductance, a multi-channel digital SQUID magnetometer can be integrated into one chip.

FIG. 4 is an explanatory diagram showing the second embodiment, which differs from the first embodiment in that a coupling coil 46 for magnetic field coupling with the input coil is provided, and a shunt resistor 37 is connected to the coupling coil 46. are doing.

FIG. 5 is an explanatory diagram showing the third embodiment, which differs from the first embodiment in that a shunt resistor 37 is connected to the output side of the SQUID 31.

FIG. 6 is an explanatory diagram showing the fourth embodiment, in which the point where the shunt resistor 37 is connected to the feedback coil 36 is the first point.
This is different from the embodiment.

Note that the above embodiments may be combined and the shunt resistor 37 may be connected to a plurality of parts.

Further, in the above embodiment, an up/down counter and a D/A converter were used as the feedback circuit (detection section), but the present invention uses a digital SQU equipped with a feedback circuit consisting of a write gate and a superconducting inductance.
It can be applied in exactly the same way to an ID flux meter.

〔Effect of the invention〕

The present invention has a configuration in which the damping shunt resistor is in an oven state when a bias current is applied to the SQUID, which prevents resonance in the input/output circuit portion of the SQUID, and which is based on the shunt resistor. Generation of noise magnetic flux can be suppressed.

[Brief explanation of the drawing]

Fig. 1 is an explanatory diagram of the principle of the present invention, Fig. 2 is an explanatory diagram showing bias current and switching signals, Fig. 3 is an explanatory diagram showing the first embodiment, and Fig. 4 is an explanatory diagram showing the second embodiment. FIG. 5 is an explanatory diagram showing the third embodiment, and FIG. 6 is an explanatory diagram showing the fourth embodiment.
FIG. 7 is an explanatory diagram showing an example of the conventional digital SQ
It is an explanatory view showing a UID flux meter. In Fig. 1, ゛1...SQUID 2...Pulse generator 3...Pickup coil 4...Input coil 5...Detector 6...Feedback coil 7...Shunt resistor 8... ... Switch 21 ... Bias current 22 ... Switching signal

Claims (6)

[Claims] (1) By supplying a pulsed bias current to the SQUID and transmitting the external magnetic flux picked up by the pickup coil via the input coil, it outputs pulses according to this external magnetic flux, and also In a digital SQUID magnetometer in which a shunt resistor is provided at a predetermined portion, a switch is provided to switch the shunt resistor between an operating state and a non-operating state, and a switching signal that changes in synchronization with the pulsed bias current is created, A digital SQ device characterized in that the shunt resistor is switched to a non-operating state by this switching signal during a period when the bias current is supplied to the SQUID.
UID flux meter. (2) The digital SQUID magnetometer according to claim 1, wherein the predetermined portion is an input coil. (3) The digital SQUID magnetometer according to claim 1, wherein the predetermined portion is a coupling coil that magnetically couples with the input coil. (4) Claim 1, wherein the predetermined portion is the output side of the SQUID.
Digital SQUID magnetometer as described. (5) The digital SQUID magnetometer according to claim 1, wherein the predetermined portion is a feedback coil provided on the output side of the SQUID in order to cancel the magnetic field of the SQUID with its magnetic field. (6) The digital SQ according to claim 1, wherein the value of the shunt resistance satisfies critical damping conditions.
UID flux meter.