JP4871003B2 - Oscillator circuit - Google Patents

Description

  The present invention relates to an oscillation device that oscillates a rectangular wave.

  Conventionally, an oscillator that obtains a duty ratio of a rectangular wave from an output of a comparator that compares a sawtooth wave (or triangular wave) with a fixed reference voltage is known. By changing a fixed reference voltage, a rectangular wave having an arbitrary duty ratio can be generated.

For example, an oscillator using a crystal resonator, a capacitor, and a resistor described in JP-A-7-221548 is an example. In this oscillator, the duty ratio is set by the reference voltage. Here, the rectangular wave output from the oscillator is compared with a reference voltage by a comparator, and the result is integrated by an integrator. The duty ratio of the oscillation wave is controlled to be constant by using feedback of the output voltage of the integrator.
JP-A-7-221548

  However, in an oscillator, the sawtooth wave (triangular wave) waveform and the delay rate of the response of the comparator change due to changes in the set frequency, power supply voltage, temperature, and the like. Since the reference voltage is fixed, the duty ratio changes depending on the variation of the above various conditions. Therefore, in order to obtain a constant duty ratio regardless of the conditions, it is necessary to change the reference voltage in accordance with the change of the conditions.

  An object of the present invention is to provide an oscillation device that always generates a rectangular wave having a constant duty ratio.

An oscillation circuit according to the present invention generates a sawtooth wave , compares the sawtooth wave with a reference voltage, oscillates a rectangular wave, and inputs the rectangular wave to generate a DC voltage corresponding to the duty ratio. And a negative feedback circuit that amplifies the difference between the DC voltage and the set voltage and feeds back to the oscillator as a reference voltage. The oscillator oscillates a rectangular wave so that the DC voltage corresponding to the duty ratio becomes equal to the set voltage.

  In the oscillation circuit, the negative feedback circuit includes, for example, a first circuit that inputs a rectangular wave of the oscillator to generate a DC voltage corresponding to the duty ratio, and the DC voltage generated by the first circuit. And a second circuit that compares the result with the set voltage and feeds the result back to the oscillator as the reference voltage.

  In the oscillation circuit, the oscillator includes, for example, a capacitor, a hysteresis comparator that compares a comparison voltage higher than the reference voltage and a comparison voltage lower than the reference voltage with a voltage of the capacitor, and a response according to an output voltage of the hysteresis comparator. A first constant current means which is turned on or off and charges the capacitor in the on state; and a second constant current means which is turned off or on according to the output voltage of the hysteresis comparator and which discharges the charge from the capacitor in the on state It comprises constant current means and a comparator for comparing the voltage of the capacitor with the reference voltage.

  In the oscillation circuit, for example, the first circuit operates using a constant voltage as a power source, receives a rectangular wave of the oscillator, and shifts the level of the rectangular wave voltage to the constant voltage; and the level shifter It comprises a low-pass filter that integrates the output and converts it into a DC voltage corresponding to the duty ratio.

  By applying a feedback loop so that the reference voltage is a voltage that generates a rectangular wave having a desired duty ratio, a constant duty ratio can always be obtained.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
The oscillation circuit according to the present invention includes an oscillator that oscillates a rectangular wave by comparing a sawtooth wave with a reference voltage. Further, the oscillation circuit receives the rectangular wave, generates a DC voltage corresponding to the duty ratio, and generates the DC voltage. A negative feedback circuit is provided that amplifies the difference between the voltage and the set voltage and feeds it back to the oscillator as a reference voltage. Thus, the reference voltage for generating a rectangular wave having a desired duty ratio is supplied by the feedback loop formed by the negative feedback circuit. By controlling the reference voltage to be constant in the negative feedback circuit, this oscillator oscillates a rectangular wave having a constant duty ratio. This negative feedback circuit, for example, compares the generated voltage with a set voltage and a first circuit that generates a voltage according to the duty ratio by inputting a rectangular wave from an oscillator, and uses the result as a reference voltage for the oscillator. And a second circuit for feedback.

FIG. 1 is a block diagram of an embodiment of the oscillation device of the present invention, and FIG. 2 shows the waveform thereof. The oscillation device includes an oscillator 100, an integrator 200, and an error amplifier 300. The oscillator 100 includes a circuit portion that generates a sawtooth wave and a comparator that compares the generated sawtooth wave with a reference voltage V _REF and outputs a rectangular wave V10. In the comparator of the oscillator 100, the duty ratio of the rectangular wave V10 is set by the reference voltage _VREF . The integrator 200 outputs a voltage V1 corresponding to the duty ratio of the rectangular wave using an integration circuit having a long time constant. The error amplifier 300 compares the voltage V1 generated by the integrator 200 with the set voltage V2, and outputs the output to the oscillator 100 as a reference voltage V _REF so that the output voltage V1 of the integrator becomes equal to the set voltage V2. Return.

According to this oscillation device, the integrator 200 and the error amplifier 300 always monitor the duty ratio of the oscillator 100 and apply feedback so as to obtain a desired duty ratio. Therefore, even if the triangular wave, sawtooth wave waveform or the response delay rate of the circuit in the oscillator changes due to fluctuations in the set frequency, power supply voltage, temperature, etc., refer to the fluctuations. Since the voltage V _REF is changed, a rectangular wave with a constant duty ratio can always be output.

  Explaining the oscillator 100, the capacitor 102 generates a voltage V3 corresponding to the electric charge. One terminal of the capacitor 102 is grounded. The MOSFET 108P operating as the first constant current means charges the capacitor 102 with a charge to increase the voltage V3, and the MODFET 108N operating as the second constant current means discharges the charge from the capacitor 102 to decrease the voltage V3. .

The output voltage V3 of the capacitor 102 is input to the + input terminal of the comparator 104 and further output to the hysteresis comparator 106. On the other hand, a reference voltage V _REF for determining the duty ratio of the rectangular wave 10 is input to the − input terminal of the comparator 104. Comparator 104 compares the reference voltage V _REF and the output voltage V3, when the output voltage V3 is higher than the reference voltage V _REF, and generates a high level voltage, when the output voltage V3 is lower than the reference voltage V _REF Generate low level voltage.

Hysteresis comparator 106 a reference voltage V reference higher with the comparison voltage V4 than _REF voltage V lower comparison voltage than _REF V5, is compared with the input voltage V3 of the capacitor 102. The output voltage V6 of the hysteresis comparator 106 is input to the gates of a pair of MOSFETs 108P and 108N connected in series. The hysteresis comparator 106 uses the voltage V3 as a non-inverting input and the comparison voltages V4 and V5 as inverting inputs. The hysteresis comparator 106 compares the high comparison voltage V4 and the input voltage V3 when the output V6 is at a low level. When the input voltage V3 exceeds the high comparison voltage V4, the output V6 becomes a high level, and then the low comparison voltage. V5 is compared with input voltage V3, and when voltage V3 becomes lower than lower comparison voltage V5, output V6 becomes low level. Thereafter, this operation is repeated. Therefore, the output V6 is a rectangular wave.

  A pair of MOSFETs 108P and 108N connected in series are connected between a power supply voltage supplied to the oscillator 100 and a ground voltage. The MOSFETs 108P and 108N are turned on / off by the output of the hysteresis comparator 106. If the output of the hysteresis comparator 106 is at a low level, the first MOSFET 108P is on and the second MOSFET 108N is off. At this time, a constant current flows through the first MOSFET 108P, the capacitor 102 is charged, and the voltage V3 increases. On the other hand, if the output of the hysteresis comparator 106 is at a high level, the first MOSFET 108P is off and the second MOSFET 108N is on. At this time, a low current flows through the second MOSFET 108N, the electric charge is discharged from the capacitor 102, and the voltage V3 decreases. Thus, as shown in FIG. 2, the voltage V3 becomes a sawtooth wave.

The comparator 104 compares the voltage V3 that is a sawtooth wave with the reference voltage V _REF fed back by the error amplifier 300, thereby generating a rectangular wave V10 that is an output of the oscillator 100. The duty ratio of the rectangular wave V10 is adjusted by the voltage value of the reference voltage _VREF . When the reference voltage V _REF is high, the duty ratio is small, and when the reference voltage V _REF is low, the duty ratio is large.

  According to the oscillator 100, the frequency of the oscillation wave and the shape of the sawtooth wave can be changed by changing the current values of the high comparison voltage V4, the low comparison voltage V5, and the MOSFETs 108P and 108N.

  Integrator 200 includes a level shifter circuit and a low-pass filter. The level shifter circuit is a buffer circuit 202 that operates using a constant voltage V7 different from a power supply voltage used for other circuit portions as a power supply. A rectangular wave V10 output from the comparator 104 of the oscillator 100 is input to the buffer circuit 202. As shown in FIG. 2, the level shift circuit 202 shifts the voltage when the rectangular wave V10, which is the output of the oscillator 100, is at a high level to the constant voltage V7. The output terminal of the buffer circuit 202 is grounded via a resistor 204 and a capacitor 206 connected in series. The low-pass filter including the resistor 204 and the capacitor 206 has a large time constant and integrates the output of the buffer circuit 202. By passing the rectangular wave V10 of the oscillator 100 through a low-pass filter having a large time constant, a DC voltage corresponding to the duty ratio can be generated. Then, the DC voltage V 1 at the connection point between the resistor 204 and the capacitor 206 is output to the error amplifier 300. Here, by passing through a low-pass filter having a sufficiently large time constant, constant voltage V1 = power supply voltage (constant voltage) V7 × duty ratio.

The error amplifier 300 includes a comparator 302. The voltage V1 from the integrator 200 is input to the + input terminal of the comparator 302, and the set voltage V2 is input to the − input terminal. The error amplifier 300 adjusts the reference voltage V _REF so that an arbitrary set voltage V2 and the output V1 of the integrator 200 become equal by applying negative feedback to the oscillator 100. Therefore, an oscillation circuit that generates a desired duty ratio can be designed by setting an arbitrary voltage V2 = constant voltage V7 × a desired duty ratio.

  The arbitrary voltage V2 is set by, for example, a voltage dividing resistor 304 using the constant voltage V7 as a power supply voltage. Since the absolute value of the voltage dividing resistor 304 varies when the temperature varies, the resistance ratio does not vary, so that a constant voltage can always be generated. Here, if the voltage V2 to be set is set by a resistance ratio using the constant voltage V7 as a power supply voltage, the resistance ratio = the duty ratio. It is desirable that the resistance ratio can be finely adjusted by trimming.

As described above, a DC voltage corresponding to the duty ratio can be generated by passing the rectangular wave V10 of the oscillator 100 through a low-pass filter having a large time constant. However, the duty ratio of the rectangular wave is obtained by using the reference voltage V _REF . This is set by inputting to the oscillator 100. By applying a feedback loop so that this reference voltage is a voltage that generates a rectangular wave having a desired duty ratio, a constant duty ratio can always be obtained. Here, the variation of the duty ratio due to the frequency, power supply voltage, temperature, etc. can be suppressed.

Circuit diagram of oscillation circuit Waveform diagram of signal in oscillation circuit

Explanation of symbols

100 oscillator, 102 capacitor, 104 comparator, 106 hysteresis comparator, 108P, 108N MOSFET, 200 integrator, 202 buffer circuit, 204 resistor, 206 capacitor, 300 error amplifier, 302 comparator, 304 voltage dividing resistor.

Claims (2)

An oscillator that generates a sawtooth wave and oscillates a square wave by comparing the sawtooth wave with a reference voltage;
Input the rectangular wave of the oscillator, generate a DC voltage according to its duty ratio,
A negative feedback circuit that amplifies the difference between the DC voltage and the set voltage and feeds back to the oscillator as the reference voltage,
The oscillator oscillates a rectangular wave so that a DC voltage corresponding to the duty ratio is equal to the set voltage ,
The negative feedback circuit is
A first circuit that inputs a rectangular wave of the oscillator and generates a DC voltage corresponding to the duty ratio;
The DC voltage generated by the first circuit is compared with the set voltage, and consists of a second circuit that feeds back the result to the oscillator as the reference voltage,
The oscillator is
A capacitor,
A hysteresis comparator for comparing a comparison voltage higher than the reference voltage and a comparison voltage lower than the reference voltage with the voltage of the capacitor;
A first constant current means that is turned on or off according to the output voltage of the hysteresis comparator, and charges the capacitor in the on state;
A second constant current means that is turned off or on according to the output voltage of the hysteresis comparator, and discharges the charge from the capacitor in the on state;
An oscillation device comprising: a comparator that compares the voltage of the capacitor with the reference voltage . The first circuit includes:
A level shifter that operates using a constant voltage as a power source, inputs a rectangular wave of the oscillator, and shifts the level of the rectangular wave voltage to the constant voltage;
The oscillation device according to claim 1 , further comprising: a low-pass filter that integrates an output of the level shifter and converts the output to a DC voltage corresponding to the duty ratio.

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