KR20050121943A - Triangle wave oscillation circuit with temperature compensation function - Google Patents

Abstract

An object of the present invention is to provide a temperature compensated triangular wave oscillation circuit implemented to provide a constant triangular wave oscillation signal without a change in frequency even with a temperature change.

The triangular wave oscillation circuit of the present invention comprises: a capacitor (C1) connected between the triangular wave output terminal and ground; A first comparator 110 providing a charging start signal when the voltage of the capacitor is lower than the charging reference voltage Vref1; A second comparison unit 120 providing a discharge start signal when the voltage of the capacitor is higher than the discharge reference voltage Vref2; A clock signal generator 130 which provides a clock signal when one of the charge or discharge start signals is input from the first and second comparators 110 and 120; A charging control unit 140 outputting a charging start signal from the first comparison unit 110 when a clock signal is input from the clock signal generation unit 130; A discharge controller 150 outputting a discharge start signal from the second comparator 120 when a clock signal is input from the clock signal generator 130; And a first current source 161 and a first switch 162, wherein the first switch is turned on according to the charging start signal of the charging control unit 140 so that the first current source supplies a constant current to the capacitor C1. Providing a charging current switching unit 160; And a second current source 171 and a second switch 172, wherein the second switch is turned on according to the discharge start signal of the discharge controller 150 so that the second current source has a constant current. It characterized in that it comprises a discharge current switching unit 170 for discharging the charging voltage of.

Description

TRIANGLE WAVE OSCILLATION CIRCUIT WITH TEMPERATURE COMPENSATION FUNCTION}

The present invention relates to a triangular wave oscillation circuit applied to a backlight inverter such as an LCD, and in particular, by implementing to provide a constant triangular wave oscillation signal without a change in frequency even with a temperature change, it is possible to reduce the deviation of the oscillation frequency due to temperature changes The present invention relates to a temperature compensated triangular wave oscillation circuit which can ensure the reliability of the applied system.

In general, a backlight inverter such as an LCD drives a lamp applied to a backlight, and PWM control using a triangular wave is used to control the lamp of the backlight with a constant brightness. The triangular wave used in the PWM method must be maintained at a constant frequency even in a temperature change to enable accurate PWM control.

One of the conventional triangular wave oscillation circuits generating such a triangular wave will be described with reference to FIG.

1 is a conventional oscillation circuit diagram.

Referring to FIG. 1, a conventional oscillation circuit includes a charge / discharge circuit part 11 including a resistor R1 and a capacitor C1 connected in series from the operating voltage Vcc to ground, and the charge / discharge circuit part 11 of the conventional oscillation circuit. It is connected in parallel with the comparator 12 for comparing the voltage charged in the capacitor (C1) and the preset reference voltage (Vref) to provide a switching signal, and the capacitor (C1) of the charge and discharge circuit portion 11, The switch 13 is configured to switch on / off by a switching signal from the comparator 12 to provide a discharge path of a voltage charged in the capacitor C1 of the charge / discharge circuit unit 11.

In the conventional triangular wave oscillation circuit, a current (i) is supplied to the capacitor (C1) through the resistor (R1) of the charge and discharge circuit unit 11, and a voltage is charged to the capacitor (C1). The output voltage will gradually increase. After that, when the voltage charged in the capacitor C1 becomes higher than the reference voltage Vref, the comparison unit 12 turns on the switch 13 to discharge the voltage charged in the capacitor C1. Through the discharge process, the output voltage is gradually lowered.

Through this charging and discharging process, a triangular wave oscillation signal having a constant frequency is output.

However, in the conventional triangular wave oscillation circuit, since the resistance included in the charge / discharge circuit part is a temperature sensitive device, the resistance of the resistor varies according to temperature, and thus, the time for charging the capacitor varies. Accordingly, there is a problem that the output frequency is changed due to the change of the charging time.

The present invention has been proposed to solve the above problems, and its object is to provide a constant triangular wave oscillation signal without a change in frequency even with a temperature change, thereby reducing the deviation of the oscillation frequency due to the temperature change, application It is to provide a temperature compensated triangular wave oscillation circuit that can ensure the reliability of the system.

In order to achieve the above object of the present invention, the triangular wave oscillation circuit of the present invention,

A capacitor connected between the triangular wave output terminal and ground to charge a voltage by an input current;

A first comparing unit configured to provide a charging start signal when the voltage of the capacitor is lower than a preset charging reference voltage;

A second comparing unit configured to provide a discharge start signal when the voltage of the capacitor is higher than a preset discharge reference voltage;

A clock signal generator configured to provide a clock signal when one of a charge start signal and a discharge start signal is input from the first and second comparators;

A charging control unit which outputs a charging start signal from the first comparison unit when a clock signal is input from the clock signal generation unit;

A discharge controller which outputs a discharge start signal from the second comparison unit when a clock signal is input from the clock signal generator;

And a first current source and a first switch connected in series between the operating voltage terminal and the capacitor, wherein the first switch is turned on according to a charging start signal of the charging control unit so that the first current source provides a constant current to the capacitor. Charge current switching unit to; And

And a second current source and a second switch connected in series between the capacitor and the ground, wherein the second switch is turned on according to a discharge start signal of the discharge control unit so that the second current source supplies a constant current to the charging voltage of the capacitor. Discharge current switching unit to discharge

Characterized in having a.

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

2 is an oscillation circuit diagram according to the present invention.

2, in the triangular wave oscillation circuit according to the present invention, C1 is a capacitor, and the capacitor C1 is connected between the triangular wave output terminal and the ground to charge the voltage by the input current.

The first comparator 110 of the present invention provides a charging start signal when the voltage of the capacitor is lower than a preset charging reference voltage Vref1. The second comparator 120 of the present invention provides a discharge start signal when the voltage of the capacitor is higher than a predetermined discharge reference voltage Vref2.

Here, the charging reference voltage Vref1 of the first comparator 11 is set to a voltage lower than the discharge reference voltage Vref2 of the second comparator 12.

The clock signal generator 130 of the present invention provides a clock signal to the charge controller 140 and the discharge controller 150 when one of the charge start signal or the discharge start signal is input from the first and second comparators 110 and 120. do.

Specifically, the clock signal generator 130 delays the discharge start signal from the first delay unit 131 and the second comparison unit 120 to delay the charge start signal from the first comparator 110. The second delay unit 132 may include a logical sum element 133 for performing a logical sum of the signals delayed by the first and second delay units 131 and 132 to output a clock signal.

The charging controller 140 outputs a charging start signal from the first comparator 110 to the charging current switching unit 160 when a clock signal is input from the clock signal generator 130. The discharge controller 150 outputs a discharge start signal from the second comparator 120 to the discharge current switching unit 170 when the clock signal is input from the clock signal generator 130.

The charging current switching unit 160 includes a first current source 161 and a first switch 162 connected in series between the operating voltage (Vcc) terminal and the capacitor (C1), the first switch is the charge The first current source is turned on according to the charging start signal of the controller 140 to provide a constant current to the capacitor C1.

The discharge current switching unit 170 includes a second current source 171 and a second switch 172 connected in series between the capacitor C1 and the ground, and the second switch is connected to the discharge controller 150. In response to a discharge start signal, the second current source discharges the charging voltage of the capacitor C1 at a constant current.

In this case, the first current source 161 and the second current source 171 are current sources for generating a constant current regardless of the temperature change.

3 is a waveform diagram of the switching signal and the oscillation signal of FIG. 2, where SC is a charge start signal, SD is a discharge start signal, and STW is a triangle wave signal.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3, when the voltage of the capacitor C1 is lower than a preset charging reference voltage Vref1, the first comparator 110 of the triangular wave oscillation circuit according to the present invention may have a charge start signal SC. ) And the second comparator 120 provides a discharge start signal SD when the voltage of the capacitor is higher than a predetermined discharge reference voltage Vref2.

For example, when the charging reference voltage (Vref1) is 1V and the discharge reference voltage (Vref2) is 3V, the first comparison unit 110 charges as shown in FIG. 3 when the voltage of the capacitor is lower than 1V. The start signal SC is provided, and the second comparator 120 provides the discharge start signal SD as shown in FIG. 3 when the voltage of the capacitor is higher than 3V.

Next, the clock signal generator 130 provides a clock signal when one of the charge start signal SC or the discharge start signal SD is input from the first and second comparators 110 and 120. The first delay unit 131 of the generator 130 delays the charge start signal SC from the first comparator 110, and the second delay unit 132 of the clock signal generator 130 The discharge start signal SD is delayed from the second comparator 120.

Thereafter, the logical sum element 133 of the clock signal generation unit 130 logically sums the signals delayed by the first and second delay units 131 and 132 to the charge control unit 140 and the discharge control unit 150 as clock signals. Output

Next, when the clock control unit 140 inputs a clock signal from the clock signal generation unit 130, the charging control unit 140 transmits the charging start signal SC from the first comparison unit 110 to the charging current switching unit 160. The discharge controller 150 outputs the discharge start signal SD from the second comparator 120 to the discharge current switching unit 170 when the clock signal is input from the clock signal generator 130. Output

In this case, the first switch 161 of the charging current switching unit 160 is turned on in accordance with the charging start signal of the charging control unit 140 to be constant by the first current source 162 of the charging current switching unit 160. Current is provided to the capacitor C1.

In addition, the second switch 171 of the discharge current switching unit 170 is turned on according to the discharge start signal of the discharge control unit 150 to the constant current by the second current source of the discharge current switching unit 170. The charging voltage of the capacitor C1 is discharged.

In this case, the first current source 161 and the second current source 171 are current sources for generating a constant current regardless of the temperature change.

The present invention as described above, by allowing the first current source and the second current source to perform the charge and discharge regardless of the temperature change, it is possible to provide a triangular wave oscillation signal having a constant frequency regardless of the temperature change.

According to the present invention as described above, by implementing a triangular wave oscillation circuit applied to a backlight inverter, such as LCD, to provide a constant triangular wave oscillation signal without a frequency change even if the temperature changes, the deviation of the oscillation frequency due to the temperature change It is possible to reduce, and to ensure the reliability of the applied system.

1 is a conventional oscillation circuit diagram.

2 is an oscillation circuit diagram according to the present invention.

3 is a waveform diagram of a switching signal and an oscillation signal of FIG. 2.

Explanation of symbols on main parts of drawing

110: first comparator 120: second comparator

130: clock signal generation unit 131: first delay unit

132: second delay unit 133: logical sum element

140: charge control unit 150: discharge control unit

160: charging current switching unit 161: first current source

162: first switch 170: discharge current switching unit

171: second current source 172: second switch

C1: Capacitor Vref1: Charge Reference Voltage

Vref2: discharge reference voltage

Claims (3)

A capacitor C1 connected between the triangle wave output terminal and the ground to charge a voltage by an input current; A first comparator 110 providing a charging start signal when the voltage of the capacitor is lower than a preset charging reference voltage Vref1; A second comparison unit 120 providing a discharge start signal when the voltage of the capacitor is higher than a preset discharge reference voltage Vref2; A clock signal generator 130 which provides a clock signal when one of a charge start signal and a discharge start signal is input from the first and second comparators 110 and 120; A charging control unit 140 outputting a charging start signal from the first comparison unit 110 when a clock signal is input from the clock signal generation unit 130; A discharge controller 150 outputting a discharge start signal from the second comparator 120 when a clock signal is input from the clock signal generator 130; And a first current source 161 and a first switch 162 connected in series between the operating voltage Vcc terminal and the capacitor C1, and the first switch is connected to a charge start signal of the charging control unit 140. A charging current switching unit 160 turned on to provide a constant current to the capacitor C1 by the first current source; And And a second current source 171 and a second switch 172 connected in series between the capacitor C1 and the ground, wherein the second switch is turned on according to the discharge start signal of the discharge controller 150. 2 discharge current switching unit 170 for discharging the charge voltage of the capacitor (C1) at a constant current source current Triangle wave oscillation circuit having a temperature compensation function characterized in that it comprises a. The method of claim 1, wherein the charging reference voltage (Vref1) of the first comparison unit 11 is Triangular wave oscillation circuit having a temperature compensation function, characterized in that the voltage set lower than the discharge reference voltage (Vref2) of the second comparator (12). The method of claim 1, wherein the clock signal generator 130 A first delay unit 131 for delaying a charging start signal from the first comparison unit 110; A second delay unit 132 for delaying a discharge start signal from the second comparison unit 120; And An OR element 133 for ORing the signals delayed by the first and second delay units 131 and 132 and outputting them as a clock signal; Triangle wave oscillation circuit having a temperature compensation function, characterized in that it comprises a.