KR880000781Y1 - Electronic circuits for electro cardiograph - Google Patents

Abstract

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Description

Drift elimination circuit of electrocardiograph

1 is a schematic structural block diagram of an electrocardiograph according to the present invention.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

100: weighting circuit portion 200: input separation circuit portion

300: differential amplifier and reference voltage generator 400: drift cancellation circuit

500: signal processing unit

600: galvanometer driving circuit section

700: galvanometer section 800: ECG recording sheet

10: human body 20: contact electrode

30: signal input terminal R ₁ , R ₂ : resistance

D ₁ , D ₂ : Diode C: Condenser

The present invention relates to a circuit for eliminating drift that degrades the characteristics of the main elements of the signal processor in an electrocardiogram that converts a biosignal generated from the heart into an electrical signal and records the electrical signal.

In general, since a biological signal obtained from a living body is small in size and low in frequency components, a signal error due to a measurement error caused by the manufacturing process of the device itself or an influence of power and temperature is accompanied by a drift phenomenon. There was a problem that the characteristics they have is lowered. Conventionally, in order to alleviate such drawbacks, a double field effect transistor is installed in a differential amplifier that amplifies a signal obtained from a living body, thereby removing the drift effect.

However, according to such a conventional method, although the drift due to the temperature can be removed or compensated, there is a defect that the electric disturbance signal, that is, the drift due to the DC component cannot be removed.

The purpose of the present invention is to provide a drift cancellation circuit configured by connecting a resistor, a capacitor, and a diode to the front end of a signal processing unit having gain adjustment, filtering, and instantaneous grounding functions to solve the above-mentioned defects. It is to provide a new electrocardiographic drift elimination circuit that can eliminate the effects of drift.

Referring to the configuration of the present invention in detail according to the accompanying drawings as follows.

First, the overall configuration of the electrocardiograph using the present invention will be described according to FIG.

The contact electrode 20 attached to the main part of the human body 10 to extract the ECG signal is connected to the signal pressure terminal 30, and randomly selects a plurality of ECG signals coming through the signal input terminal 30. The weighting circuit unit 100 is connected to the signal input terminal 30, and the output terminal of the weighting circuit unit 100 is connected to the input terminal of the input separation circuit unit 200 to remove the adverse effect on the human body by the leakage current of the electrocardiograph itself. Amplify the signal from the input separation circuit unit 200, generate a reference voltage to compensate for temperature drift, and differential amplification and reference voltage generator 300 that provides a high in-phase signal removal ratio and high input impedance is separated from the input It is connected to the rear end of the circuit unit 200, and the drift by direct current accompanying the amplified signal from the differential amplification and the reference voltage generator 300 such as The drift elimination circuit unit 400, which is a circuit of the present invention, which serves to serve, is connected behind the differential amplification and reference voltage generating unit 300, and at the rear end of the drift elimination circuit unit 400, the gain adjustment, filtering, and instantaneous signal A signal processing unit 500 having a grounding function is connected, and a galvanometer driving circuit unit 600 for driving a galvanometer is connected to an output terminal of the signal processing unit 500.

The galvanometer driving circuit unit 600 is connected to a galvanometer unit 700 and an electrocardiogram recording paper 800.

As such, the drift elimination circuit 400 according to the present invention is installed and configured between the differential amplification and reference voltage generator 300 and the signal processor 500 as shown in FIG. 1 showing a schematic configuration of an electrocardiograph. When described in detail based on the accompanying drawings, Figure 2 as follows.

A grounding connection point 40 is connected to the differential amplification and reference voltage generator 300, and a connection point 40 is connected to a neutral point C that discharges a direct current, and a neutral point to which the capacitor C is connected. A resistor R ₂ connected to the negative power supply unit (-Vcc), a cathode terminal of the diode D ₁ , and an output terminal output to the signal processing unit 500 are commonly connected to the power supply unit (+). The resistor (R ₁ ) connected to Vcc) is connected to the anode terminal of the diode (D ₁ ), while the anode terminal of the diode (D ₂ ) with the cathode terminal grounded is connected to the electrostatic source (+ Vcc). It is.

When described in detail the operation and operation of the drift elimination circuit 400 according to the present invention configured as described above.

When a DC component that causes a drift is loaded on the signal output through the differential amplification and reference voltage generator 300, and is input to the connection point 40 of the input terminal of the drift elimination circuit 400, the capacitor C first discharges the DC. do.

When the residual DC component below the baseline passes when the signal compensated to some extent by the capacitor C passes the neutral point 50, the power supply of the electrostatic source unit (+ Vcc) is the resistance (R ₁ ) and the diode (D). This residual DC component is removed because it is applied through ₁ ), and the residual DC component is removed because the power is applied from the negative power supply (-Vcc) through the resistor (R ₂ ) when the DC component above the baseline passes. Done. At this time, when the negative power source (-Vcc) is applied, the current from the electrostatic source unit (+ Vcc) is applied to the input terminal 40 grounded via the diode D ₂ to wait for the next operation.

By repeating the above process, the DC component causing the drift can be easily removed, thereby eliminating the drift phenomenon.

In this way, the present invention consists of a RC coupling circuit and a diode coupled with a capacitor and a resistor to remove an electric disturbance signal caused by an error caused by the power supply itself or the manufacturing process of the device, that is, to easily remove the drift. It is a useful design that works.

Claims (1)

The contact electrode 20, the signal input terminal 30, the weighting circuit unit 100, the input separation circuit unit 200, the differential amplification and reference voltage generation unit 300, the signal processing unit 500, and the galvanometer driving circuit unit 600. In the electrocardiograph consisting of a galvanometer portion 700 and an electrocardiogram recording paper 800, The grounded connection point 40 and the capacitor C are connected to the output terminal of the differential amplification and reference voltage generator 300, and one side end of the capacitor C and the negative power supply unit (-Vcc) are centered around the neutral point 50. sikimyeo connected to the cathode terminal of the resistor (R ₂₎ and a diode (D ₁₎ with connection in common, the diode (D ₁₎ connected to a resistor (R ₁₎ connected to the node terminal to the positive power supply (+ Vcc) to the And the anode terminal of the diode (D ₂ ) whose cathode terminal is grounded to the electrostatic source unit (+ Vcc), and the center point 50 to the input terminal of the signal processing unit 500. Removal circuit.