KR0154845B1 - Current detecting circuit with noise filter - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current sensing circuit having a noise filter, the switching means being turned on / off by a control signal, the current sensing means for sensing the current flowing through the switching means, and the voltage applied across the current sensing means. In order to completely remove the turn-on noise component of the switching means included in the control section, the control signal is 'low' during the period where the turn-on noise is present and 'high' during the period when the turn-on noise is not present. Error compensating means designed to compensate for errors caused by noise, and voltages applied across the current sensing means and secondary feedback input terminal voltages as non-inverting and inverting inputs, respectively, and then compared with each other. A first comparison means designed to output a comparison result signal only when the control signal is 'high' by the output control signal. The present invention relates to a current sensing circuit having a noise filter designed to eliminate abnormal operation caused by noise and to compensate for an error sensing voltage caused by an RF filter designed for noise removal.

Description

Current Sense Circuit with Noise Filter

1 is a circuit diagram showing a current sensing circuit having a conventional noise filter,

2 is a circuit diagram illustrating a current sensing circuit having a noise filter according to an embodiment of the present invention.

3A to 3D are control waveform diagrams of a current sensing circuit having a noise filter according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current sensing circuit having a noise filter, and more specifically, to a noise filter designed to eliminate abnormal operation caused by noise and to compensate for an error sensing voltage caused by an Al filter designed for noise removal. The present invention relates to a current sensing circuit.

Hereinafter, a current sensing circuit having a conventional noise filter will be described with reference to the accompanying drawings.

1 is a circuit diagram showing a current sensing circuit having a conventional noise filter.

As shown in FIG. 1, the configuration of a current sensing circuit having a conventional noise filter includes: a power switch 10 turned on / off by a gate control signal; A current sensing resistor Rs for sensing a current flowing through the power switch 10; An RF filter (20) designed as a resistor and a capacitor to remove noise components included in the voltage (Vs) applied across the current sense resistor (Rs); Receive the voltage from the noise filter passed through the RF filter 20 as the non-inverting (+) input, and receives the voltage (Vfb) of the secondary feedback input terminal as the inverting (-) input, and compares the two input signals Comparator 30 to output.

The power switch 10 includes a power transistor turned on / off by a gate control signal and a diode connected between a drain terminal and a source terminal of the power transistor.

The current sensing circuit having a conventional noise filter configured as described above is configured to receive current flowing through a power switch for driving a pulse width modulation (PWM) controller, which is a type of a general switching mode power supply system. It is a circuit for sensing. In other words, comparing the sensing of the secondary voltage Vfb with the sensing of the current of the MOS transistor used as the switching element in the power switch 10 to control the MOS transistor again so that the stable secondary voltage can be controlled. do.

In the current sensing circuit having the conventional noise filter, since the turn-on noise is applied to the current sensing resistor Rs, such as the voltage Vs at the turn-on of the power switch 10, the resistor Rf and the capacitor Cf Noise is filtered by using the filter 20 consisting of ().

However, since the RF filter 20 does not completely transmit a main sense voltage without noise, an error component increases as the magnitude of the sense voltage Vs increases.

Accordingly, an object of the present invention is to solve the conventional problems as described above, noise filter designed to remove the abnormal operation caused by noise, and compensate for the error detection voltage caused by the RF filter designed for noise removal It is to provide a current sensing circuit having.

The configuration of the present invention for achieving the above object, the switching means is turned on / off by a control signal; Current sensing means for sensing a current flowing through the switching means; During the period in which the turn-on noise is present to completely remove the turn-on noise component of the switching means included in the voltage applied across the current sensing means, the signal is 'low' and during the period in which the turn-on noise is not present. An error compensating means designed to generate a 'high' state control signal to compensate for an error due to noise; After comparing the voltages applied across the current sensing means and the secondary feedback input terminal voltage as non-inverting and inverting inputs, respectively, and comparing the result signal only when the control signal is 'high' by the control signal output from the error compensating means. It consists of a first comparison means designed to output the.

The configuration of the error compensation means may include: an offset power supply for adding an offset voltage to a voltage applied across the current sensing means; Filtering means for gently adjusting a noise component included in the voltage to which the offset voltage is added; The signal voltage passed through the filtering means and the voltage applied across the current sensing means are respectively received as non-inverting and inverting inputs, and thus, 'low' and turn-on noise are not present during the period in which the turn-on noise is present. The second comparison means generates a control signal of a 'high' state during the non-interval period.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention in detail.

2 is a circuit diagram illustrating a current sensing circuit having a noise filter according to an embodiment of the present invention.

As shown in FIG. 2, the configuration of the current sensing circuit having the noise filter according to the embodiment of the present invention includes: a power switch 10 turned on / off by a gate control signal; A current sensing resistor Rs for sensing a current flowing through the power switch 10; In order to completely remove the turn-on noise component of the power switch 10 included in the voltage Vs applied across the current sense resistor Rs, 'low', turn An error compensation circuit 40 designed to generate a control signal Vco1 in a 'high' state during the period where no on-noise exists and compensate for errors due to noise; Non-inverting voltages Vs1 and Vfb1 n times the voltage Vs applied across the current sense resistor Rs and the secondary feedback input terminal voltage Vfb through the respective amplifiers Amp2 and Amp1, respectively. +) Compared to the terminal input and the inverting (-) terminal input, and compares, and outputs the comparison result signal Vco2 only when the control signal is 'high' by the control signal Vco1 output from the error compensating circuit 40. It consists of a main control comparator 50 which is designed to.

The error compensation circuit 40 includes an offset power supply for adding an offset voltage Voff to an n times amplified voltage of the voltage Vs applied across the current sense resistor Rs through an amplifier Amp3; A capacitor (C-filter) for gently adjusting a noise component included in the voltage to which the offset voltage (Voff) is added; The non-inverted (+) and inverted (-) voltages of the signal voltage Vs2 through the capacitor C-filter and the voltage Vs1 amplified n times of the voltage Vs applied across the current sensing resistor Rs are respectively. A comparator 41 generating a control signal Vco1 of a 'low' state during a period where turn-on noise is present and a 'high' state during a period where there is no turn-on noise Consists of

Operation of the current sensing circuit having a noise filter according to the embodiment of the present invention made as described above is as follows.

The current sensing circuit having the noise filter according to the embodiment of the present invention generates a control signal Vco1 for completely removing the turn-on noise component instead of the Al filter used in the current sensing circuit having the conventional noise filter. An error compensation circuit 40 designed to compensate for errors due to noise by controlling the output of the comparator 50 is used.

As shown in (a) of FIG. 3, the voltage Vs applied across the current sensing resistor Rs is a voltage including turn-on noise of the power switch 10, and a pulse width modulator (PWM) controller. If the secondary feedback voltage Vfb is greater than the turn-on noise of the voltage Vs during the driving, normal operation may be performed even without the error compensation circuit 40. However, when the secondary feedback voltage Vfb is less than the turn-on noise of the voltage Vs in the absence of the error compensation circuit 40, the comparison result voltage of the 'high' state in the main control comparator 50 is obtained. Is generated and input to the reset (R) input terminal of the RS latch circuit, which is a typical configuration of the pulse width modulation (PWM) controller, thereby making it impossible to fully perform the original function of the controller.

Next, a detailed operation process will be described with reference to the control waveform diagrams shown in FIGS. 3A to 3D.

First, the main control comparator 50 is a comparator for comparing the secondary feedback voltage Vfb purely with the voltage Vs applied across the current sense resistor Rs, which is in the error compensation circuit 40. The comparator 41 is a comparator for detecting the noise component of the voltage Vs and controlling the output of the main control comparator 50 and the output of the amplifier Amp1.

To this end, in the comparator 41 in the error compensation circuit 40, the voltage Vs1 and the voltage Vs2 are compared, and the comparison target voltage Vs1 is a voltage applied across the current sensing resistor Rs. Vs) is an amount amplified by the amplifier Amp2, and the other comparison target voltage Vs2 is an amount obtained by filtering the value obtained by adding the offset voltage Voff to the voltage Vs by a capacitor C-filter. The signal waveform is shown in (b) of FIG.

Therefore, the output Vco1 of the comparator 41 outputs a control signal of a 'low' state in the section A where turn-on noise occurs as shown in (c) of FIG. In the sections B and C, except for the generated section A, the signal of the 'high' state is output. This is because the voltage Vs2 is larger than the voltage Vs1 except for the section A in which turn-on noise occurs due to the forced offset voltage Voff.

As a result, in a section A where turn-on noise occurs, the output signal of the comparator 41 makes the output Vco2 of the main control comparator 50 'low' regardless of the input to remove noise. It becomes possible.

If the output Vco1 of the comparator 41 is not generated, a dotted line output shown in (d) of FIG. 3 may be generated at the output terminal of the main control comparator 50 to cause a malfunction due to noise.

Therefore, the effect of the current sensing circuit having a noise filter according to the embodiment of the present invention operating as described above, eliminates the abnormal operation due to noise, and compensates for the error sensing voltage generated by the RF filter designed for noise removal It was made to be possible.

Claims (5)

Switching means turned on / off by a control signal; Current sensing means for sensing a current flowing through the switching means; During the period in which the turn-on noise is present to completely remove the turn-on noise component of the switching means included in the voltage applied across the current sensing means, the signal is 'low' and during the period in which the turn-on noise is not present. An error compensating means designed to generate a 'high' state control signal to compensate for an error due to noise; After comparing the voltages applied across the current sensing means and the secondary feedback input terminal voltage as non-inverting and inverting inputs, respectively, and comparing the result signal only when the control signal is 'high' by the control signal output from the error compensating means. A current sensing circuit having a noise filter, characterized in that it comprises a first comparison means designed to output a. A current sensing circuit with a noise filter as claimed in claim 1, wherein said current sensing means consists of a resistor. 2. The apparatus of claim 1, wherein the error compensating means comprises: an offset power supply for adding an offset voltage to a voltage applied across the current sensing means; Filtering means for gently adjusting a noise component included in the voltage to which the offset voltage is added; The signal voltage passed through the filtering means and the voltage applied across the current sensing means are respectively received as non-inverting and inverting inputs, and thus, 'low' and turn-on noise are not present during the period in which the turn-on noise is present. And a second comparing means for generating a control signal in a 'high' state during a period of time not being used. 4. A current sensing circuit with a noise filter as claimed in claim 3, wherein said filtering means consists of a capacitor. 4. The current sensing circuit according to claim 1 or 3, further comprising amplifying means having an n-fold amplifying function at each input terminal of the first comparing means and the second comparing means.