KR102506841B1 - Apparatus for controlling duty rate of PWM - Google Patents

Abstract

The present invention relates to a circuit technology in which a charging or discharging setting method is changed in order to improve a PWM duty ratio, and provides a PWM duty ratio control device that allows an external device to set a charging or discharging time in a triangular waveform. .
An apparatus for controlling a PWM duty ratio according to an embodiment of the present invention includes an output control unit receiving detection of upper and lower limit values of a triangle wave voltage for PWM generation from an operational amplifier provided in a semiconductor, and a charging constant current unit supplying a charging current of an external capacitor. and a discharge constant current unit supplying a discharge current of the external capacitor.

Description

PWM duty rate control device {Apparatus for controlling duty rate of PWM}

The present invention relates to a PWM duty ratio control device, and more particularly, to a circuit technology in which a method of setting a time during charging or discharging is changed in order to improve a PWM duty ratio.

An LED is a device whose brightness changes in proportion to a forward current. As a method of controlling the amount of light of the LED, analog dimming-a method of controlling the amount of forward current and a method of digital dimming-a method of controlling the PWM duty of forward current are used. .

The analog dimming method alone has a problem in that the chromaticity of the LED light varies depending on the amount of current, so digital dimming is used. .

The simplest way to generate PWM is to use a sawtooth wave generated by charging and discharging a capacitor in a resistor and capacitor circuit (RC circuit). It is not possible to obtain an accurate PWM duty ratio.

In general, in order to obtain an accurate PWM duty ratio, a microcomputer or a highly precise timer generator must be used to generate a precise square wave. However, adding such a device to the LED complicates the configuration, increases the size of the device, and increases the price of the device. There are increasing disadvantages.

[Patent Document] Korean Patent Registration No. 1272595.

The present invention relates to a circuit technology in which a charging or discharging setting method is changed in order to improve a PWM duty ratio, and to improve the accuracy of a PWM duty ratio that allows an external device to set a charging or discharging time in a triangular waveform. provides a device for

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the examples of the present invention. It will be readily seen that the objects and advantages of the present invention may be realized by means of the instrumentalities and combinations indicated in the claims.

An apparatus for controlling a PWM duty ratio according to an embodiment of the present invention includes an output control unit for receiving detection of upper and lower limit values of a triangular wave voltage (V _PWMI ) for PWM generation from an operational amplifier provided in a semiconductor, and supplying a charging current for an external capacitor. A charge constant current part and a discharge constant current part supplying discharge current of the external capacitor are included.

In addition, a first switch for controlling on or off of the charge constant current part and a second switch for controlling on or off of the discharge constant current part may be included in the semiconductor.

In addition, the first switch may be turned on when the triangle wave voltage for PWM generation is less than or equal to the reference voltage (H), and turned off when the triangle wave voltage for PWM generation is greater than the reference voltage (H).

In addition, the second switch may be turned on when the triangle wave voltage for PWM generation is greater than or equal to the reference voltage (L), and may be turned off when the triangle wave voltage for PWM generation is less than the reference voltage (L).

In addition, an external resistor may be further included to control the magnitudes of the charging current and the discharging current, respectively.

The operational amplifier unit may include a first operational amplifier comparing an upper limit value of the triangle wave voltage for generating the PWM and a second operational amplifier comparing a lower limit value of the triangle wave voltage for generating the PWM.

This technology relates to a circuit technology in which a setting method during charging and discharging is changed in order to improve the accuracy of a PWM duty ratio, and allows external devices to set charging and discharging times in triangular waveforms.

In addition, this technology is a technology capable of reducing costs by not using elements such as timers or microcomputers in order to improve the accuracy of the PWM duty ratio.

In addition, this technology is a technology capable of reducing the PCB package by simply configuring the circuit of the device.

1 is a diagram illustrating a circuit diagram of a PWM duty ratio control device according to an embodiment of the present invention.
2 is a diagram illustrating a graph in which accuracy is improved over time in a PWM duty ratio according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them, will be explained in detail through the following embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. However, the present embodiments are provided to explain in detail enough to easily implement the technical idea of the present invention to those skilled in the art to which the present invention belongs.

In the drawings, embodiments of the present invention are not limited to the specific forms shown and are exaggerated for clarity. Although certain terms are used in this specification. This is used for the purpose of explaining the present invention, and is not used to limit the scope of the present invention described in the meaning or claims.

In this specification, the expression 'and/or' is used to mean including at least one of the elements listed before and after. In addition, the expression 'connected/coupled' is used as a meaning including being directly connected to another component or indirectly connected through another component. In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. In addition, components, steps, operations, and elements referred to as 'comprising' or 'including' used in the specification mean the presence or addition of one or more other components, steps, operations, and elements.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a diagram illustrating a circuit diagram of a PWM duty ratio control device according to an embodiment of the present invention.

Referring to FIG. 1, the output control unit 100 provided inside the semiconductor 105 includes a first operation amplification unit 110 (OP AMP) that compares the upper limit value of the triangle wave voltage for PWM generation and the triangle wave voltage for PWM generation. A charging constant current unit (130, IPWM_SET) and a discharge constant current unit (140) receiving a signal from the second operational amplifier (120, OP AMP) that compares the lower limit value of and supplying the charging current and the discharging current of the external capacitor 170. , IPWM-RST) is controlled on or off with two switches, respectively.

Here, one of the two switches may be referred to as a first switch 150 and the other switch may be referred to as a second switch 160 .

At this time, the first switch 150 is turned on when the triangle wave voltage for PWM generation (VPWMI) ≤ reference voltage (H) (VPWMI (H)), and the triangle wave voltage for PWM generation (VPWMI) > reference voltage (H) In the case of (VPWMI(H)), it is turned off.

In addition, the second switch 160 is turned on when the triangle wave voltage for PWM generation (VPWMI) ≥ the reference voltage (L) (VPWMI(L)), and the triangle wave voltage for PWM generation (VPWMI) < the reference voltage (L). It is off in case of (VPWMI(L)).

Here, the reference voltage (H) refers to an upper limit (maximum) reference voltage, and the reference voltage (L) refers to a lower limit (minimum) reference voltage.

The first operational amplifier 110 (OP AMP) sets the upper limit reference voltage and compares the charging voltage of the external capacitor 170 with the upper limit reference voltage VPWMI(H) to reach the upper limit value of the triangle wave for PWM generation. detect

The second operational amplifier 120 (OP AMP) sets the lower limit reference voltage and compares the discharge voltage of the external capacitor 170 with the lower limit reference voltage VPWMI(L) to reach the lower limit value of the triangular wave for PWM generation. detect

The charging constant current unit 130 (IPWM-SET) serves to charge the external capacitor 170 element with constant current. On/off is controlled by the first switch 150 inside the semiconductor 105 by the output controller 100, and the magnitude of the current is set by the first external resistor 200 (RPWM_SET).

The discharge constant current unit 140 (IPWM-RST) serves to discharge the external capacitor 170 with a constant current. On/off is controlled by the second switch 160 inside the semiconductor 105 by the output controller 100, and the magnitude of the current is set by the second external resistor 210 (RPWM_RST).

The charging reference voltage 180 (VREF_SET) controls the size of the charging constant current unit 130 (IPWM-SET) and the maximum PWM current value in association with the first external resistor 200 (RPWM_SET).

The discharge reference voltage 190 (VREF_RST) controls the size of the discharge constant current unit 140 (IPWM-RST) in association with the second external resistor 210 (RPWM_RST).

Here, the charging time and the discharging time are adjusted according to the size values of the charging constant current unit 130 (IPWM-SET) and the discharge constant current unit 140 (IPWM-RST). The larger the size value of the charging constant current unit (130, IPWM-SET) and the discharging constant current unit (140, IPWM-RST), the faster it is charged or discharged, and the charging constant current unit (130, IPWM-SET) and the discharge constant current unit (140, IPWM -RST) is charged or discharged more slowly as the value of magnitude is smaller.

The external capacitor 170 is charged or discharged in a triangular waveform by the charging constant current unit 130 (IPWM-SET) and the discharge constant current unit 140 (IPWM-RST). The charge/discharge time and the PWM frequency are determined according to the size of the capacitance of the external capacitor 170 .

The external resistors (RPWM_SET and RPWM_RST) are classified into a first external resistor (200, RPWM_SET) and a second external resistor (210, RPWM_RST), and in conjunction with the first external resistor (200, RPWM_SET), a charging constant current unit (130, IPWM) -SET) and the PWM maximum current value are adjusted, and the size of the discharge constant current unit (140, IPWM-RST) is controlled in conjunction with the second external resistor (210, RPWM_RST).

Here, the external resistors (RPWM_SET and RPWM_RST) can set the upper and lower limit values of the triangle wave voltage for PWM generation, and can set the maximum analog output current value of the LED driver.

2 is a diagram illustrating a graph in which accuracy is improved over time in a PWM duty ratio according to an embodiment of the present invention.

Referring to FIG. 2 , it can be seen that the PWM duty ratio improves accuracy with time since the charge value or discharge value is initiated as a linear triangular waveform with time in the PWM duty ratio.

As described above, the present technology relates to a circuit technology in which a setting method during charging and discharging is changed in order to improve the accuracy of the PWM duty ratio, and a technology that allows external devices to set the charging and discharging time in a triangular waveform. am.

In addition, this technology is a technology capable of reducing costs by not using elements such as timers or microcomputers in order to improve the accuracy of the PWM duty ratio.

In addition, this technology is a technology capable of reducing the PCB package by simply configuring the circuit of the device.

In the above, although the present invention has been described with limited configurations and drawings, the technical spirit of the present invention is not limited to these, and those skilled in the art to which the present invention pertains, the technical spirit and the following Various modifications and variations will be possible within the scope of equivalents of the claims to be described.

Claims (6)

an output control unit configured to receive detection of upper and lower limit values of a triangle wave voltage for PWM generation from an operation amplification unit provided in a semiconductor;
a charging constant current unit supplying a charging current of an external capacitor; and
a discharge constant current unit supplying a discharge current of the external capacitor;
a charging reference voltage for adjusting the size of the charging constant current unit;
a discharge reference voltage for adjusting the size of the discharge constant current part;
a first external resistor connected to the charging constant current unit and the charging reference voltage to adjust a size of the charging constant current unit; and
a second external resistor connected to the discharge constant current part and the discharge reference voltage to adjust the size of the discharge constant current part;
PWM duty ratio control device comprising a. The method of claim 1,
and a first switch for controlling on or off of the charging constant current part and a second switch for controlling on or off of the discharge constant current part, respectively, in the semiconductor. The method of claim 2,
The first switch is turned on when the triangle wave voltage for PWM generation is less than or equal to the reference voltage (H), and is turned off when the triangle wave voltage for PWM generation is greater than the reference voltage (H). controller. The method of claim 2,
The second switch is turned on when the triangle wave voltage for PWM generation is greater than or equal to the reference voltage (L), and is turned off when the triangle wave voltage for PWM generation is less than the reference voltage (L). controller. delete The method of claim 1,
the operational amplifier
a first operation amplification unit comparing an upper limit value of the triangle wave voltage for generating the PWM; and
The PWM duty ratio control device comprising a second operational amplifier for comparing a lower limit value of the triangle wave voltage for generating the PWM.

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