SU1078370A1 - Digital magnetic induction meter - Google Patents

Description

The invention relates to magnetic measurements and can be used for precision measurements over a wide range of induction of constant magnetic fields. A digital magnetic induction meter is known that includes a DC source, a voltage-code converter, a counter, a dividing unit, a control unit, and a digital indicator tl. The disadvantage of this meter is the low accuracy of the measurement due to the presence of additive error, mainly due to the non-equipotentiality of the Hall sensor. The closest to the invention to the technical essence is a digital magnetic induction meter containing a current stabilizer, a Hall sensor, the current electrodes of which are connected to a current stabilizer, a voltage converter, a counter and a digital indicator connected through a counter to a voltage-code converter 2, A disadvantage of the known device is the low measurement accuracy, due to the presence of switching surges, which is especially evident when measuring weak magnetic fields, when the level ahodnyh Hall sensor signal commensurate with the level of switching bursts. In addition, when excluding switching bursts, the measurement time is very long, on the order of 2 seconds, due to the fact that in order to achieve high accuracy, the measurement must be carried out after the end of transients, and therefore the current through another pair of opposite electrodes of the Hall sensor can be passed approximately one second. Therefore, the meter cannot be used to analyze rapidly changing magnetic fields. The aim of the invention is to improve the accuracy of measurements in a wide range of operating temperatures. The goal is achieved in that a digital magnetic induction meter containing a current regulator, a Hall sensor, current electrodes K9 orgo are connected to a voltage regulator, a voltage-code converter, a counter, and a digital indicator connected through a counter with a converter. switch, dividing unit, constant unit and control unit,. connected to a switch, voltage-code converter, dividing unit, constant block, digital indicator and second counter input, the third input of which is connected via a dividing unit to the second voltage-code converter output, the second input of which is connected to the output of the switch connected by the second and the third inputs with potential electrodes of the Hall sensor, and the fourth and fifth, inputs with current electrodes of the Hall sensor, and the third input of the division unit is connected to the output of the block of constants. The high accuracy of the measurement of the EMF of the Hall voltage is due to the fact that this digital magnetic induction meter uses automatic compensation of non-equipotentiality voltage and there is no switching of the current and potential electrodes of the Hall sensor, leading to switching surges, the level of which is commensurate with the Hall EMF. As is well known, due to the temporal and temperature instability of the parameters of the Hall sensor, the non-equipotentiality voltage Uj is measured, which is the main cause of the additive error of the Hall effect devices. Automatic compensation of non-equipotentiality voltage is achieved by subtracting from the output signal of the Hall sensor id (+ Uris variable calibration signal equal to the non-equipotential voltage determined at each time instant. To find the non-equipotentiality voltage at each time Uj, 3 (t), use the following Hall sensor feature. Non-equipotential stress and non-equipotential resistance, with a stable supply current, varies in proportion to the voltage Hall electrode out electrodes and .., 1л1п А hall sensor resistance, because at each moment of time Hall sensor resistance r (t) is proportional to non-equipotential resistance r.3 (t)) .. Therefore, how much percent will change Hall sensor resistance rrt (t) , the voltage on the current electrodes of the Hall sensor U .. and the voltage of the non-equipotentiality and -the voltage of the compensation (variable calibration signal), which at each moment of time is subtracted from the output signal of the Hall sensor, will change by the same percentage of U (t) K-U,. (t) ./. , (t) .Un3 (t), where K is the compensation coefficient. Thus, the output signal of the attendee Hall at any time. neither will depend on the voltage

Claims (1)

(54 / DIGITAL MAGNETIC INDUCTION METER, containing a current stabilizer, a Hall sensor, the current electrodes of which are connected to a current stabilizer, a converter * voltage code, a counter and a digital indicator connected through a counter to a voltage code converter, which differs in that, for the purpose of increasing the accuracy of measurements in a wide range of operating temperatures, it additionally includes a switch, a division unit, a constant block and a control unit connected to the switch, a voltage-code converter, a division unit, ohms of constants, a digital indicator and a second input counter.a, the third input of which is connected through the division unit to the second output of the voltage-code converter, the second input of which is connected to the output of the switch connected by the second and third inputs to the potential electrodes of the Hall sensor, and the fourth and fifth inputs - with current electrodes of the Hall sensor, and the third f input of the division block is connected to the output of the constant block. (,