SU783730A1 - Device for temperature compensation of hall sensors - Google Patents

Description

one

The invention relates to the field of magnetic measuring technology and can be used to measure constant and alternating magnetic fields and undistorted recording of the shape of magnetic signals in a wide temperature range.

A device is known which contains a Hall sensor, a generator, a circuit. compensation of unbalance voltage t0 sensor, two amplifiers, registering device, two optocouplers connected to the output; 12U of the second amplifier, and two resistors, the first resistor connected to the input of the second amplifier, output- 5 of one of the optocouplers through the second resistor connected to the output of the first amplifier, and the output of the second optocoupler is connected to a voltage sensing, imbalance sensor circuit,

A voltage generator is used as a power source in this device, which in the temperature range stabilizes the magnitude of the parasitic non-equipotential voltage, as a result of which only the sensor unbalance voltage arising due to the non-uniformity of the semiconductor material is compensated. The disadvantages of this device are from i 30

2

There is also a large error in relatively strong magnetic fields.

The aim of the invention is to improve the accuracy of compensation.

The goal is achieved by the fact that in a device containing an adjustable voltage source, an amplifier connected in parallel to a current generator, a recording device and an optocoupler, whose input is connected to the amplifier output, and the output is connected to the sensor unbalance compensation circuit, the sensor input is directly connected to the amplifier input .

A current generator is used to power the Hall sensor.

Claims (1)

The input impedance of the amplifier is much higher than the input impedance of the sensor. In this case, due to the temperature change in the resistance of the sensor, there is a change in the voltage drop at the input of the sensor, which is used to cope the temperature change of the residual voltage. The value of the Hall emf does not change with temperature, since its value is determined in this case by the Hall coefficient, which in the temperature range, high depletion temperature of dopants and lower intrinsic conduction temperatures, is not changed in all semiconductors. The variation in the temperature imbalance voltage is eliminated by the use of a homogeneous semiconductor material. Since changes with the temperature of the other component of the residual voltage Non-equipotential voltage and voltage drop at the sensor input are due to the same reason for the change in the resistivity of the semiconductor, this causes a high accuracy of compensation. The measurement error of induction by a device is described by the formula b.UaaTkb, bjo where d is the magnitude of the temperature variation of the voltage of an unequal potential, t is the error introduced by the electronic compensation circuit and the drawing shows the functional diagram of the device described. The device for temperature compensation of Hall sensors contains an arres nidoglishy Hall sensor 1, a top generation of current 2, a recording device. 3 amplifier 4, the input of which is connected in parallel with sensor 1, and the input of the optocoupler 5 serves as a load. contains a resistor 7 and an output impedance of the optocoupler 5, and the output of the divider is sequentially connected to the output output of the sensor. The device works as follows. At the initial temperature Current sensor 1 and the operating current Od of the generator toKa 2 at the output of amplifier 4, a signal exists, the value of which by selecting the operating mode of amplifier 4 is set so that the operating point of the optocoupler 5 is in the linear part of the transfer characteristic. Changing the voltage of the adjustable source b can be achieved so that the voltage drop across the resistor 7 is equal in magnitude and opposite in sign to the parasitic zero voltage of the non-equipotentiality of the sensor. Compensation of the temperature variation of the non-equipotentiality voltage occurs as follows. When the temperature deviates from TQ, the change in the electrical resistance of sensor 1 sequentially changes the voltage drop on sensor 1 itself, the output resistance of the optocoupler 5 and the magnitude of the compensation for the voltage across the resistor 7. Using the device distinguishes it from the specified prototype when measuring relatively strong magnetic fields when using a precision recording device and a Hall sensor made of gallium arsenide in magnetic fields of the order of 3.000 ° C and a temperature range from 20 to 150 ° C. The use of the described device made it possible to achieve a measurement error of no worse than 0.01%. When using the device, taken as a prototype, the error was about 0.2%. Claims An apparatus for temperature compensation of Hall sensors, comprising an adjustable voltage source, an amplifier connected in parallel with a current generator, a recording device and an optocoupler, whose input is connected to the amplifier output, and the output is included in the sensor unbalance compensation circuit, characterized in that, p. In order to improve the accuracy of compensation, the sensor input: directly connected to the input of the amplifier.