SU737866A1 - Device for automatic measuring of the resistance and conductivity of biological objects - Google Patents

Description

The invention relates to biophysical research, in particular to electronic-digital devices for measuring the conductivity of biological objects. The invention can be used in long-term experiments with woody plants in order to determine the conductivity parameters as a factor determining the plant's resistance to adverse conditions and damaging factors.

It is advisable to use the meter in medicine in order to determine the suitability of transplants, serum, blood, and cell suspensions.

A device for automatically measuring resistance, containing a current source, two transformers, an amplifier, a detector, an RC circuit, a modulator 20, a buffer element, an indicator device 11].

The disadvantages of the device are the lack of a digital display, and the algorithm of the device does not allow 25 to directly measure the conductivity.

The device has a narrow dynamic range, low accuracy of measuring resistance, high weight, low reliability due to the use of transformers.

Closest to the proposed one is a device that consists of a magnetic amplifier having two control windings, a functional digital-to-resistance converter ¹ , a comparator, a reference generator, an indication unit, a reset unit [2].

Both control windings of the magnetic amplifier are supplied with voltage from one power source.

In the initial state, the weight resistance of the functional converter is minimal, the output signal s. Magnetic amplifier, maximum, counting pulse inhibitor. The measured resistance is connected in series with one of the control windings of the magnetic amplifier ...

When the signal for measurement is applied, the initial state of the display unit and the functional converter is established or confirmed, the generator is started, and the counting pulses begin to arrive: simultaneously in the functional converter and the display unit.

The weight of the functional transducer resistance increases as long as the effects of the first magnetic amplifier control winding will not be offset by the influence of the second coil included Pospelova-, a weight resistance Tel'nykh ³ rational function converter. Then the comparator is tuned to the idle signal of the magnetic amplifier. The signal from the comparator enters the reset unit, where the control flips over ^{and has} a trigger. In this case, the generator is locked, the flow of counting pulses to the functional converter and the display unit is stopped. I'm taking readings. After some 15 time, the control cultivator located in the reset unit again όπρο- <throws the control trigger, sets the functional converter unit of the nation into initial state, starts the generator and the measurement cycle is repeated again.

When measuring a small resistance equal to a unit increment of the weight resistance of the functional transducer (for example, 1 kOhm with the established increment of the weight resistance 1 kOhm / pulse), magnet-. the amplifier receives the most disturbing effect, therefore, the frequency -jq of the counting pulse generator should be sufficiently low.

When measuring resistances of sufficiently high values, for example, 50 kOhm and above, the perturbing effects of the magnetic amplifier jc are small and decrease with increasing value of the measured resistance, so the generator frequency can be quite high.

For the purpose of stable operation when measuring small resistances and reducing the time, when changing large resistances, the counter pulse generator is made of variable frequency. The frequency varies from 0 to 300 Hz in increasing exponent. 45

The disadvantages of the known device are the narrow dynamic range, determined by the properties of the magnetic amplifier, the requirements for high temporal and temperature stability of high resistances of the functional converter, the impossibility of measuring the conductivity, low measurement accuracy, determined by the properties of $$ magnetic amplifier.

The purpose of the invention is the expansion of the dynamic range without compromising measurement accuracy.

To achieve the goal, a device for automatically measuring the resistance and conductivity of biological objects, containing a generator, an amplifier, the output of which is connected to the input of the functional voltage converter is frequency, and the input is connected to a bio-65 logical object and a reset unit connected in series and the indicator is equipped with a controlled current source, a pulse width generating unit and three keys, and the generator output through the first key is connected to the first indicator input and the output of the functional converter caller, the last of which is connected through the second key to the first input of the allocation unit, the output of which is connected to one contact of the third key connected to the second input of the indicator, the last through the other contact of the third key is connected to the first output of the reset unit, while the second output of the reset block is connected to the second input of the selection unit, and the output of the controlled current source is connected to the aforementioned input of the functional converter.

The start-stop circuit is executed on j-κ triggers'.

The reset and indication circuit is executed on a quartz oscillator operating in self-oscillating mode and a digital divider counter with automatic zero-setting.

In FIG. 1 shows a block diagram of a device for automatically measuring the resistance and conductivity of biological objects.

The device has two operating modes, the first is the mode of measuring the resistance value R, the second is the mode of measuring the conductivity G, while in both of these modes a direct digital indication of the measured parameters is carried out in conventional units of measurement. .

The device includes a controlled current source 1, biological ¹ object 2, amplifier 3, functional converter 4, generator 5, indicator 6, reset unit 7, allocation unit 8, keys 9, 10 and 11.

The output of the current source 1 is connected to the biological object 2 and the input of the amplifier 3, the output of which is connected to the converter 4. The output of the generator 5 is connected in the measurement mode of the conductivity G to the signal input of the indicator 6. The output of the functional converter 4 in the measurement mode of the resistance value R is connected to the signal the indicator input b, and in the mode of measuring the conductivity G to the signal input of the selection unit 8, the Reset * indicator 6 is connected to the first output of the reset unit 7, in the measurement mode P R, the second output of the reset unit 7 is connected to the command input of the indicator 6, and the third output of the reset unit 7 is connected to the input “Orientation” of the allocation unit 8. In the measurement mode of the conductivity value G of the biological object 2, unit 8 is highlighted. niya is connected by an output to the command input of indicator 6 and signal inputs to the output of functional converter 4.

The operation of the device in the measurement mode of the resistance value R of the biological object 2 is as follows.

Timing diagrams characterizing this mode of operation are shown in FIG. 2.

The switch is moved to position R. A certain current value is set from the controlled reference current source 1, the value of which does not depend on the resistance of the object and on time, and the absolute value is selected below the damage threshold of the biological object 2.

With the passage of current. 3 _floor through the biological object 2, the last voltage drop ϋ ^ · occurs. _ο ., the value of which varies in time due to the presence of the polarizing capacitance of the object and ultimately reaches a steady-state value (Fig. 2c ^ i.e.

to

At times tg-tf., Etc. (Fig. 2a), the pulse sequence F _{BblK n} (Fig. 2d) from the output of the functional converter 4 is supplied to the signal input of the indicator 6 in accordance with the commands of the reset unit 7. In this case, the counter is reset by a pulse of short duration at time instants t /, tj, t /, etc.

As a result, during the time intervals C — t ₂ , tj—, t ₅ —1 ₆ , etc., the number of pulses (Fig. 2e) is received at the input of the display unit b (Fig. 2e) in accordance with ^p e> exp. ° ' 5 X ~ '

7 ^ - frequency of generation and indication.

Moreover, F ^ is determined by form N by the formula '* 0.0., (1) where Rjo. - dynamic resistance of the object to direct current.

As a rule, the current value is chosen sufficiently small, therefore, for efficient conversion of information about the object’s resistance (voltage Ujq), the output terminal of the object is connected to the input of the buffer scale amplifier 3, the resistance of the gain is goose but has a large input and fixed coefficient the output of the buffer-scale amplifier 3 forms a voltage U, (Fig. 2c) acc. B1 A O 'to the formula ^K 1 · 45.0.' (2) on control 4 voltage This voltage is supplied by the inverter-frequency converter input with a linear modulation characteristic. The frequency at the output of the Converter 4 voltage-frequency _p (Fig. 2d) is determined by the input voltage U _Cbl4 d. (Fig. 2C) and is equal to < ³ >

where K ₂ ~ coefficient characterizing the angle of inclination of the modulation characteristics of the Converter 4 voltage-55 frequency.

At the output of the transducer 4, a pulse sequence is formed (Fig. 2d), the frequency of which varies in accordance with the voltage at the biological object 2, t. e. '' eats ¹ 'after changing its resistance R _ff0 .C, taking into account (1) and (2), transforms (3) so

F ⁴ ry »p

R

0.0.

(4) where F. sa le * ΒΜΐ (.η.'β-5

V N reset circuits (6)

By setting certain values of Ό, _t , K ₄ , K _2, and E (it is easy to obtain an indication of the resistance value directly in conventional units of measurement.

The operation of the device in the mode of measuring the electrical conductivity of a biological object 2 is as follows: (Timing diagrams characterizing this mode of operation are presented in Fig. 3).

The switch is moved to a position in which a certain value is set from the controlled current source 1 — the current value, the value of which, like and. in the first operation mode, it does not depend on the electrical parameters of the object and on time, and the absolute value is chosen below the damage threshold of the biological object 2, the Digital measurement mode of the electrical conductivity of the biological object 2 is reduced to the inverse relationship

i.e., obtaining a digital value that is the inverse resistance of a biological object 2.

As in the first unit operation, when current passes through the _floor Z biological object 2 on the last voltage drop occurs according to the formula (1), _koto-: Roe scaling amplifier amplifies buffer 3 (Figure Sc.) Is input i.dalee functional converter 4 voltage-frequency with a linear modulation characteristic, the output of which is formed by a pulse sequence (Fig. 3d) in accordance with formula (3) and (4). This pulse sequence arrives at the definition (7) is equivalent to 65 to the signal input of the block of 8 allocations, the input of which is Orientation * at the time t ^, t, etc., the orienting pulses from the block from block 8 selection in the initial state. As a result, the pulse T | allowing the passage of a series of pulses F _onreH . (Fig. Ze) of the reference generator 5, through the signal input © until 6 indications on the counter during the duration of the pulses at the command input of the indicator 6.

The duration of the pulse at the output of the start-stop circuit (Fig. 3f) is determined by the instantaneous pulse repetition rate of the converter 4, voltage-frequency, since the role of the start-stop circuit is reduced to the allocation of the period. The pulse sequence ^p _V y < _r , t ° is:

¹ % μΐη '* 4' ^ et '^ 6 о. (θ)

Thus, the pulse duration T _{4 is} inversely proportional to the resistance of the biological object 2 R _tf0 or, which is the same, is proportional to its electrical conductivity G ^ p. At the input of the counter of the indicating unit 6, the number of pulses N ₄ is proportional to the electrical conductivity of the biological "object 2 in accordance with the formula * op gem.

R .. - * _ op.gen (W - Ur «g (Κ -T '* --1 6.0 on gene..' · Κ / 3 · Β _Λ O n r 1 woo...

Choosing the values of the constants included in formula (9), it is easy to directly obtain an indication in units of conductivity. The reset of block 4 of the 4Q indication, as in the first mode of operation, is carried out at time t _? , t ₅ , etc. (Fig. 3). ''

The invention can be used in lengthy experiments with woody plants, in medicine in determining the suitability of transplants and will automate scientific experiments of considerable duration in time with a significant increase in the accuracy of the measured parameters. Along with the application, it is possible to effectively use this electronic device in the industry of polymers and in the food industry. The device is implemented using microelectronics, economically, which allows you to create on the basis of its mobile units for rapid analysis in the field.

Claims (2)

The invention relates to biophysical research, in particular to electronic digital devices for measuring parameters of the conductivity of biological objects. The invention can be used in long-term experiments with woody plants in order to determine the conductivity parameters as a factor determining the resistance of the plant to adverse conditions and damaging factors. It is advisable to use the meter in medicine to determine the suitability of transplants, serum, blood, cell suspensions. A device for automatic measurement of resistance is known, which contains a current source, two transformers, an amplifier, a detector, an RC circuit, a modulator, a buffer element, an indicator device 1. The drawbacks of the device are the absence of a digital display, and the algorithm of the device does not allow There is no direct measurement of the conductivity value. The device has a narrow dynamic range, low resistance measurement accuracy, high weight, low reliability, due to the use of transformers. The closest to the present invention is a device which consists of a magnetic amplifier having two control windings, a digital-resistance functional converter, a comparator, a reference generator, a display unit, a node; reset 2. A voltage from one source is applied to both control windings of a magnetic amplifier nutrition In the initial state, the weight and resistance of the functional converter is minimal; the output signal is c. . Magnetic amplifier, the maximum, the generator of the counting pulses of the ban. The measured resistance is connected in series with one of the control windings of the magnetic amplifier. When a signal is applied to the measurement, the initial state of the display unit and the function converter is established or confirmed, the generator is started, and the counting pulses begin to flow: simultaneously, the function converter and the display unit. The weight resistance of the functional converter is increased until the effect of the first control winding of the magnetic amplifier is compensated for by the influence of the second winding connected in series with the weight resistance of the functional converter. Then it processes the comparator tuned to the idle signal of the magnetic amplifier. The signal from the comparator enters the reset node, where it triggers the control trigger. With eFLM, the generator is detected, the flow of counting pulses to the functional converter and the display unit is stopped. The readings are being taken. After some time, the control cultivator located in the reset node reopens the Control Trigger, initializes the function converter and the indication block, starts the generator and the measurement cycle repeats. When measuring a small resistance equal to a unit increment of the weight resistance of a functional transducer (for example, 1 kOhm with a fixed increment of weighed resistance of 1 kOhm / pulse), the magnetic amplifier receives the greatest distorting effect, therefore the frequency of the gyrometer of the counting pulse must be sufficiently low. When measuring resistances of sufficiently high values, for example 50 kΩ and higher, the disturbing effects of the magnetic amplifier are small and decrease with increasing magnitude of the measured resistance, therefore the generator frequency can be quite high. With the aim of stable operation when measuring small resistances and reducing time when large resistances change. Generator s. pulses made variable frequency. The frequency varies from 0 to 300 Hz in an increasing exponent. The disadvantages of the known devices are the narrow dynamic range 6, the range of properties of the magnetic amplifier, the high temporal and temperature stability of the high resistances of the functional converter, the impossibility of measurable reducibility, the measurement accuracy determined by the properties of the magnetic amplifier. The purpose of the invention is to expand the dynamic range without reducing the measurement accuracy. To achieve a goal device for authbytic measurement of the resistance and conductivity of biological volumes, containing a generator, amplified, connected to the functional converter input, frequency, and the biological object and a serially connected reset unit and indicator , is equipped with a current source control unit, a pulse duration shaping unit and three keys, the generator output being connected via the first key to the first input of the indicator and the output of the functional conversion bodies, the last of which is connected via a second key to the first input of the allocation unit, the output of which is connected to one contact of the third key connected to the second input of the indicator. The latter is connected to the first output of the reset unit through another contact of the third key, at which the second output of the resetting unit is connected to the second input of the allocation unit, and the output of the controlled current source is connected to the above-mentioned input of the function converter. Start-stop circuit is executed on -k triggers-. The reset and indication circuit is made on a quartz oscillator, operating in self-oscillating mode and a digital counter-divider with automatic zero setting,. FIG. 1 shows a block diagram of a device for automatically measuring the resistance and conductivity of biological objects. The device has two modes of operation, the first is the measurement mode of the resistance value T, the second is the measurement mode of the conductivity value G, and in both of these modes, the digital display of the measured parameters is carried out directly in the conventional units. The device includes a controlled current source 1, biological object 2, amplifier 3, functional converter 4, generator 5, indicator 6, reset unit 7, discharge unit 8, keys 9, 10 and 11. The output of current source 1 is connected to a biological object 2 and the input of the amplifier 3, the output of which is connected to the converter 4. The output of the generator 5 is connected in the measurement mode of the Conductance G value to the signal input of the indicator 6. The output of the function converter 4 in the measurement mode of the resistance value R is connected to the signal input control indicator b, and in the measurement mode of the conductivity value G to the signal input of the 8 block, the Input Reset indicator 6 is connected to the first output of the reset block 7, in the resistance measurement mode R the second output of the reset block 7 is connected to the command input of the indicator b, and the third output block 7, the reset is connected to the input. The orientation of the allocation unit 8, In the mode of measuring the conductivity value G of the biological object 2, the unit 8 separation. The output is connected to the command input of the indicator 6 and the signal inputs to the output of the functional converter 4. The operation of the device and the measurement mode of the resistance value R of the biological object 2 are as follows. Timing diagrams characterizing this mode of operation are presented in FIG. 2. The switch is set to position R. A certain current value is set from the controlled reference Current Source 1, the value of which does not depend on the object resistance and time, and the absolute value is selected below the damage threshold of the biological object 2. When the current passes through Biological object 2, at the last there is a voltage drop Uj., the magnitude of which varies over time due to the presence of the polarization capacity of the object and reaches a fixed value at the end of the ends (fig. 2 i.e. bs p 6.0. where rjj-o - dynamic resistance of an object to a direct current. Typically, the value of the current is chosen sufficiently small, therefore, to efficiently convert information about the resistance of an object (voltage UJQ), the output terminal of the object is connected to the INPUT of a buffer scale amplifier 3 having a large input resistance and a fixed coefficient The output of the buffer scale amplifier 3 is the voltage U., -j l (2s) according to the formula This voltage is applied to the control input of the converter 4 voltage-frequency with a linear modulation characteristic. The frequency at the output of the voltage-frequency converter 4. n (2d) is determined by the input voltage U-, (fig, 2c) and is equal to q ". Bmx.x.6. %about. where K 2 is the coefficient characterizing the angle of inclination of the modulation characteristic of converter 4 voltage frequency. The output of the transducer 4 forms a pulse sequence (Fig. 2d), whose frequency varies in accordance with the voltage on the biological object 2 U, t. E. It is following the change in its resistance. With regard to (1) and (2), it transforms (like this, 6.0. K, At times, tg-t4, tf-t, etc. (Fig. 2a), the pulse sequence .C. (Fig. 2d) from the output of the functional converter 4 is fed to the signal indicator 6 in accordance with the commands of the reset unit 7. At the same time, the counter is reset by a short pulse at times tt, t, etc. In the result time intervals, etc., the number of IM pulses N (Fig. 2e) is fed to the input of the display block b, according to the formula, where F is the frequency generating a reset and indication circuit. In this case, P is determined by the formula Given certain values O, y, K, K 2 and K (it is easy to obtain an indication of the resistance directly in conventional units of measurement. Operation of the device in measuring the electrical conductivity value of a biological object 2 is as follows. (Time Diagrams characterizing this mode of operation are shown in FIG. 3). The switch is shifted to the position in which a certain value of current is protected from the controlled reference current source 1, the value of which is, as well as. in the first mode of operation, does not depend on the electrical parameters of the object and on time, and the absolute value is selected below the damage threshold of the biological object 2. The digital measurement mode of the electrical conductivity value of the biological object 2 reduces to determining the inverse relationship, i.e., the digital equivalent of the value , inverse to the resistance of the biological object 2. As in the first mode of operation of the device, when 3yf current passes through biological object 2 at the last, a voltage drop occurs in According to formula (1), which is amplified by a buffer large-scale amplifier 3 (Fig. 3c) and then a voltage-frequency with a linear modulation characteristic is fed to the input of the functional converter 4, the output of which forms a pulse sequence (Fig. 3d) in accordance with formula (3) and (4). This pulse sequence arrives at the signal input of a block of 8 emissions, the input of which at time points, t, t, etc., receives orienting pulses from a reset unit 7, returning from a selection unit 8 to the initial state. As a result, the command input of the indicator 6 receives a pulse T, allowing the passage of a series of pulses Fon gene- (Fig. Ze) of the reference generator 5, through the signal input of the display unit 6 to the counter during the time of action of the pulses T, via the command input of the indicator 6. Duration the pulse at the output of the start-stop circuit T (Fig. 3f) is determined by the instantaneous pulse tracking frequency of the converter 4, voltage-frequency, since the role of the start-stop circuit is reduced to the separation of the period. pulse sequence Fgjj, J, i.e. ; T -L. : t n eh% o. Thus, the duration of the impulse T is inversely proportional to the resistance of the biological object 2 Kd. Iyi, which is the same, is proportional to its electrical conductivity GgQ. The input of the counter of the display unit 6 Receives the number of pulses N, proportional to the value of the electrical transmissibility G of the biological object 2 in accordance with the formula on.rCH on. gsy. t 0 ,. IC -T 6.0. NDnreH. N 9m "6.c ,. By choosing the values of the constant included in formula (9), it is easy to obtain and directly display in units of conductivity. Resetting the display unit 6, as in the first mode of operation, is carried out at the time t, t, tj, etc. (Fig. 3). The invention can be used in long experiments with woody plants, in medicine pr determining the suitability of transplants and will allow automating scientific experiments of considerable duration over time with a significant increase in the accuracy of the measured parameters. Along with the application, it is possible to effectively use this electronic device in the polymer industry and in the food industry. The device is implemented using microelectronics, economically, which makes it possible to create on the basis of its mobile installations for express analysis in field conditions. Apparatus for automatically measuring the resistance and conductivity of biological objects, comprising a generator, an amplifier whose output is connected to the input of a functional converter, and an input to a biological object, and a series-connected reset unit and indicator, characterized in that without reducing the accuracy of the measurement, the device is equipped with a controlled current source, a pulse duration unit and three keys, the generator output through the first key h is connected to the first input of the indicator and the output of the functional converter, the last of which is connected via the second key to the first input of the allocation unit, the output of which is connected to one contact of the third key connected to the second input of the indicator, the last through the other contact of the third key the output of the reset unit, wherein the second output of the reset unit is connected to the second input of the allocation unit, and the output of the controlled current source is connected to the aforementioned input of the function converter. Sources of information taken into account during the examination 1. USSR author's certificate 280646, cl. G 01 R 27/00, 1970. 2. Authors certificate of the USSR 398894, cl. G 01 R 27/02, 1973 (prototype) .. Scheduling ted (Gee), but/ L) et