DK163385B - DEVICE FOR MEASUREMENT AND / OR DISPLAY OF ELECTRIC RESISTANCE - Google Patents

Description

DK 163385 B

The invention relates to a device of the kind specified in the preamble of claim 1.

For numerous physiological and psychological studies, it is necessary to be able to measure and show changes in electrical resistance or resistance in a living body. The apparatus or devices known from the conventional measuring technique are usually not suitable or only poorly suited for this purpose. Such known devices, for example, have a measuring source network with different branches of resistance interconnected (Kronert "Messbrucken und Kompensatoren" Vol. 1, 1935, 10 pp. 79-82, DE-AS 23 19 785). Thus, rapid resistance changes cannot be measured or recorded. Furthermore, to increase the sensitivity of such measurement source networks, it is known to use amplifiers (DE OS 25 03 515). However, with this known construction, satisfactory results cannot be obtained by measuring resistances in living bodies.

Furthermore, an apparatus specially designed for measuring and displaying changes in resistance in a living body is already known, which apparatus has a very high sensitivity and is also capable of determining small resistance changes (US 3,290,589).

The object of the invention is to further increase the sensitivity of this known apparatus.

This object is achieved with the non-endowments stated in the characterizing part of the independent claim 1.

Embodiments of the invention are set forth in subclaims 2-6.

The particular advantage of the invention is that a quick display of a resistance change is obtained.

In a particular embodiment of the device or apparatus according to the invention, an open and thus non-conductive frame is used as a carrier for a pointer coil.

in

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The invention will now be explained in more detail with reference to the drawing, in which: FIG. 1 shows a schematic diagram of the circuit for the device; FIG. 2 is a front view of the device; FIG. 3 is a perspective view of the coil frame and FIG. 4 shows the moving part of the measuring device in perspective and showing the coil frame in use.

The FIG. 1 shows a DC amplifier (DC amplifier) which contains three transistors Q1, Q2 and Q3, 10 which are supplied with their operating voltage from a battery B1 and each of the present embodiment are each of the type 2N1303. In FIG. 1, the input of the DC amplifier is applied between the base of the first transistor Q1 and the emitter, the emitter of Q1 being coupled back through a 4.7 kfl resistor R5. This voltage difference is 15 equal to the battery voltage, so that the circuit behaves exactly as if it were in fact connected as a simple measuring bridge.

The transistor Qi in the first amplifier stage is an emitter follower having a fairly large input resistance, since it is necessary to keep the amplifier input resistance at a relatively large value relative to the resistance of the measuring bridge to prevent load, since load is especially important when the measuring bridge is working. in an unbalanced state.

For connecting the object or measuring electrodes to the instrument, there is a telephone jack J1 which has spring loaded contacts arranged to be connected. By inserting a (not shown) connector which is appropriately connected to the electrodes, contact 2 is connected to the slider of the area control potentiometer VR2. In addition, the telephone jack is operably connected to a single-pole switch S3 in such a way that this switch is connected for connection over the telephone jack contacts 1 and 2 of a 5 kfi resistor R1 instead of the body of the object when the plug is pulled out.

In the present embodiment, the resistance branches R3 and R2 are resistors with values of 22 kfl and 3.9 kfl, respectively.

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The range control potentiometer VR2 is connected at one end to the negative side of the battery Bi via a switch SIA, and the potentiometer is connected at the other end to an outlet on the battery B1 via a 5 kO resistor VR4 and a switch SID. In addition, the base of transistor Q1 via resistors R12, R13 or R14, depending on the desired sensitivity range selected by a switch S2A, is connected to the negative side of an instrument M1 and the transistor Q1's collector is via switch SIA The emitter of the battery B1 is connected via a 470 O resistor R6 to a base 10 of transistor Q2 in the second amplifier stage, which is arranged as a conventional common emitter stage, which provides most of the current gain. VR5 of 5 kfl is connected to the positive side of the battery B1, and in addition, this emitter is via a sensitivity control VR5, which comprises a reverse logarithmic variable resistance of 10 kO, and via the switch SID connected to the outlet of the battery B1.

The Q2's collector is directly connected to the emitter of Q3 and in addition via a 5.6 kfl's resistance R8 as well as the switch SIA connected to the negative side of the battery B1. The base of Q3 is connected to the node 20 of resistors R10 and Ril, each of 22 kO, of which resistors R10 are connected to the negative side of the battery B1 through the switch SIA, and of which resistors Ril are connected to the slider of the VR5. The collector of Q3 is connected to a switch S1C in such a way that, by operating the switch, the collector can be connected to the positive side of the instrument. The instrument is shunted with a 5.6 kO resistor R16 and a variable resistor VR7 of 5 kfl, connected in series, and the negative side of the instrument is connected through a 22 kfl resistor R15 and the switches S1B and SIA connected to the negative side of the battery B1.

30 The switches S1C and SIA as well as the switch S1B connect when SI is in the third position, respectively, the positive side of the instrument to the positive side of the battery B1 and the negative side of the instrument to the negative side of the battery B1 via a resistance 90 kfl of R19. With SI in the third position, the instrument is shunted with a variable resistance VR8 35 of 5 kQ.

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The output stage transistor Q3 is connected in common base configuration and forms an impedance matching device that feeds the display instrument.

Resistors R12, R13 and Ri4 constitute counter-coupling resistors which determine the total gain. Their value depends on the position of S2A.

The switch S2 is a two-pole three-position switch. In position 1, a 470 kfl resistor is connected. In position 2, a 1 Mfi resistor R13 is connected. In position 3, two series-connected 1 Mfl's resistors R13 and R14 are connected.

10 To compensate for the change in voltage on the base of Q1, as a result of the change in resistance by means of S2A, a variable opposite voltage is connected to the base of Q1 using the switch S2B. In position 1, between the base of Q1 and the negative side of the battery B1 is connected a resistor R4 of 200 kQ and a resistance of Rk 75 kfl. In position 15 2, between 200 base of Q1 and negative side of battery B1 is a 200 kfi resistance R4 and a 17.5 kfi resistance R20. In position 3, a resistance of 200 Kohm is connected between the base of Q1 and the negative side of B1; R4.

This represents a new and unknown improvement in that it provides an enhancement of sensitivity which is not obtainable in devices already known in the art.

The switch SIA, B, C, D, E and F is a five-pole three-position switch operated by a button B '(Fig. 2). The pointer instrument M1 is a pivot coil instrument capable of displaying from 0 to 25 100 pA for full scale oscillation, which instrument has an arcuate scale H '(Fig. 2) which is divided into sections. At about. a third scale fluctuation exists a small area of the arc, which areas are marked "SET". At the full scale swing end of the arch there is another small section marked "TEST". Between these two small areas 30 the scale is marked "FALL". A 5 kfl variable preset resistor VR1 is located between the connection terminals and the amplifier detector to allow compensation for component value variations. The resistance value of the optimal female subject

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5 is 5 Kohm and the instrument is therefore standardized to this value.

To adjust VR1, there is a control button C '(Fig. 2), which is marked "TRIM". The range control potentiometer VR2 is provided with a control knob E 'and a linear scale I', marked 5 with "1" to "6", extending over an arc of 240 °, which arc is divided into regions of 48 °. In the initial adjustment of the instrument, VR1 is adjusted in such a way that when the input jack plug is removed and when the 5 kfl resistor R1 is thus connected over the input, balance is established when the area controller VR2 10 is set to "2" on its scale. Once this adjustment has been made, the balance point should be at "3" on the VR2's area control scale 1 'with a resistance of 12.5 kfl connected across the input. Thus, when the instrument is correctly adjusted, the instrument needle G 'must indicate the center of the "SET" range of the scale when VR2's control control E' on its scale is set to "2". In order to perform the calibration, it is only necessary to set the controller E 'to "2", extract the jack J1's connector and adjust VR1 by means of the controller C' to cause the instrument needle to give the correct fluctuation.

With the subject's body connected to the electrodes and with the rotary controller VR2 adjusted to balance, a decrease in the subject's body resistance will cause the base current of transistor Q1 to change in a negative direction. This increases the current in R5 in such a way that the base of Q2 becomes negative as well. This in turn makes the Q3 emitter more positive. The Q3 collector current is then increased, thereby increasing the instrument needle fluctuation. If, instead, the subject's body resistance increases, the base current of Q1 will change in a positive direction, and consequently a reduction in instrument needle fluctuation will occur.

When the measuring bridge is in a balanced state, a voltage of 1.5 volts will be applied on the base of Q1 and the instrument needle G 'should indicate 30 centers on the "SET" range of the scale. The amplifier must be adjusted so that it becomes a virtual zero state. That is, when this condition prevails, a change in amplifier gain should not change the instrument display. However, if there is an imbalance so that the instrument indication is above or below this virtual zero display, an increase in gain will move the needle further up or down relative to the zero condition, depending on the conditions. For-

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6, the amplification of the amplifier is adjusted by means of the button D '(Fig. 2) of the sensitivity controller VR5, which varies the negative feedback supplied to the transistor Q2, with part of the emitter current of Q2 running through VR5 and part through the variable preset mode VR6. . The latter is adjusted to such a value that the voltage drop across it is equal to the battery voltage when the instrument needle is at the center of the "SET" range of the scale. Accordingly, for this view and only for this view, there is no current in VR5, and its adjustment therefore does not affect the view of the instrument.

10 Since the instrument is primarily intended for detecting changes in a subject's body resistance, precautions must be taken to minimize changes in instrument display due to other reasons. Changes due to unstable or noisy transistors are avoided by careful selection thereof, but a change in gain due to a change in temperature, which is one of the fundamental characteristics of all transistors, can cause an increase in constant operation , which can be misleading. To correct for this type of instability, transistor Q3 connected to an outlet on battery B1 and across transistor Q2 is inserted. The emitter of transistor Q3 is connected to the collector of transistor Q2, which is why an operation in the voltage of the collector of transistor Q2 will produce a compensation voltage change on the emitter of transistor Q3. Thus, transistor Q1 is an emitter follower whose output signal is transmitted to the base of transistor Q2 via a resistor R6.

25 The bias for the Q2 emitter is obtained from the resistors VR6 and VR5 and is adjusted by VR5. The bias of the base of transistor Q3 is obtained from the resistors R10 and Ril.

The output of the amplifier runs from the collector of Q3 and through the pointer instrument M1 with compensation for voltage operation provided by the connection of the collector of Q2 and the emitter of Q3, as described above.

In FIG. 1, the first stage of the amplifier is an emitter follower, and the second and third stages are cascaded in a manner to provide operating compensation, as described above.

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7 When the switch S1, operated by the button B ', is turned to "TEST" (position 3), the instrument is switched off from the amplifier and a resistor R19 and the instrument M1 are connected over the batteries.

With the switch SI in this position, only a 5-point instrument scale shift to the "TEST" range is achieved when the batteries supply their correct voltage.

Switching the SI to position 3 also connects a half-wave rectifier and charging unit supplied from J2 with 220 volts AC voltage. The rectifier consists of diodes D1 and D2, which only allow the alternating current to pass in one direction. A sluggish fuse F1 protects the device in case of excessive voltage. A resistance R17 of 27 Ω protects the batteries from overvoltage. A capacitor Cl of 0.68 μ ¥ determines the charging rate. A resistance R18 of 470 kfl discharges Cl when the device is not charging. This is an improvement as 15 NI-CD batteries can now be charged in the device, whereas the batteries in the original device often had to be replaced.

In the new device, much of the static noise has been eliminated by the use of wirewound potentiometers as well as metal film resistors instead of ball-bearing resistors, which tend to become poor and cause internal currents that have no connection to the measurements.

The movable part used in the device known from United States Patent No. 3,290,589 for measuring and indicating changes in resistance in a living being is a 1450 ohm wire coil wound 25 on an electrically closed metal frame. The improvement is based on the fact that the inductance of the electrically closed metal frame absorbs a substantial part of any sudden current change in the coil. The absorbed energy is lost in the build-up of a current in the metal frame, this being an negligible resistance induction coil. Thus, substantially less energy is available for needle fluctuation.

In the new moving part, a small piece of the frame is cut away to prevent the energy of the impulse from being lost in the form of current in the frame, since it now has infinite resistance. This provides maximum utilization of the energy for instantaneous oscillation of the needle. This

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8 thus responds more quickly and more perfectly to sudden power changes.

The device contains a device shown in FIG. 3, which is designed for retaining a wirewound coil and which at B has a 5 slot for reducing the conductivity of the frame to zero, thus preventing energy loss in the form of magnetically induced currents in the frame.

In FIG. 4 is shown a 1450 ohm wire wound coil C, one end of which is electrically connected to a wire D, which is used both as one of the electrical connections to the coil C and as one of the axis of rotation of the frame A and the needle G. The other end of the coil C is electrically connected to a wire E, which is used both as the electrical connection to the coil C and as the other axis of rotation of the frame A and the needle G.

The needle G is physically connected to the frame A and constitutes the indicator in the device for measuring and indicating changes in resistance in a living being. A counterweight H is used to balance the needle G around the point where the needle is connected to the frame A. An iron cylinder F remains motionless and serves to concentrate the magnetism by which the device acts.

A stationary housing (not shown) is used for connecting the moving part electrically, magnetically and physically with the device for measuring and indicating changes in resistance in living beings.

A coil wound coil without any frame at all has also been used, which coil was made rigid by varnish (a non-conductor). The end product is very similar to the former, ie. a coil without the extra inductance and therefore without the current flowing in the frame, and it has shown similar results.

Claims (6)

Device for measuring and / or displaying an electrical resistance value using a measuring source network or circuit and an amplifier 20 (Q1, Q2, Q3), said measuring source network having a first resistor branch (R3) coupled in series with a a second resistor branch (R2), connecting the electrical resistor to be measured or displayed to the measuring source network, the measuring source network additionally having a first and a second voltage branch (B1, B2) connected in series to amplify the Furthermore, the current (Q1, Q2, Q3) and a current measurement or display apparatus (M1) are connected between the connection point between the first resistor branch (R3) and the second resistor branch (R2) and the connection point between the first voltage branch (B1) and the second voltage source. branch (B2), wherein the device has two electrodes (1, 2) which are connected to one of the resistor branches (R2, R3) and can be connected to a live body and the device has a resistor backbone switching branch (R12, R13, R14, S2A) connecting the output of the amplifier (Q1, Q2, Q3) to the base of the emitter follower (Q1), characterized in that the counter-tooth feedback branch has a switch (S2A), with three settings for switching on the resistors (R12, R13, R14) of the resistor feedback branch, the switch (S2A) being connected to the base of the first transistor (Q1) of the amplifier (Q1, Q2, Q3), Device according to claim 1, characterized in that the device has six switches (A, B, C, D, E and F) with each three switch positions, the six switches always occupying a first, a second or a third switch position simultaneously. which switches are connected between the resistance branches (R2, R3) and the voltage branches (B1, B2). Device according to claim 1, characterized in that an adjustable resistor (VR7) is coupled parallel to the current measuring and display apparatus (M1). Device according to claim 1, 20, characterized in that the base and collector of the second transistor (Q2) in the amplifier (Q1, Q2, Q3) are connected via resistors (R7, R8) to the point of the switch (A) in the other switching gear. Device according to claim 1, characterized in that the current measuring and display apparatus 25 (M1) has the following components: a) a split metal frame (A, B), b) a measuring coil (C) wound around the split metal frame, (A, B), (c) a cylinder (F) connected to the metal frame (A, B) and d) a needle (G) connected to the metal frame (A, B). DK 163385 B Device according to claim 5, characterized in that the coil (C) has no support frame and is instead stiffened by a non-conductive lacquer.