Amplitude normalization circuit, power supply and electronic apparatus

What is claimed is: 1. An amplitude normalization circuit comprising: a peak detector configured to detect a peak value of a full-wave rectified voltage of an AC voltage; a triangular wave oscillator connected to the peak detector, configured to generate a triangular wave voltage having a peak based on the peak value of the full-wave rectified voltage; a comparator connected to the triangular wave oscillator, configured to compare the triangular wave voltage with the full-wave rectified voltage and output a pulse width modulation signal; and a waveform converter connected to the comparator, configured to convert a waveform of the pulse width modulation signal and output an output voltage with a constant amplitude, wherein the waveform converter includes: a level shifter configured to shift a level of the pulse width modulation signal; and a low pass filter connected to the level shifter, configured to filter the level-shifted pulse width modulation signal. 2. The amplitude normalization circuit of claim 1 , wherein the peak detector includes: a peak detecting part including a diode having an anode to which the full-wave rectified voltage is supplied and a capacitor connected in series between a cathode of the diode and a ground potential; and a buffer connected to a node between the diode and the capacitor, configured to output a voltage with a value equal to the peak value. 3. The amplitude normalization circuit of claim 1 , wherein the triangular wave oscillator includes: a current source connected to the peak detector; a reset capacitor connected in series between the current source and a ground potential; a reset comparator connected to the current source, configured to output a reset signal; and a reset MOS transistor connected in parallel to the reset capacitor and being turned on/off based on the reset signal, wherein the triangular wave oscillator generates a triangular wave voltage having a frequency equal to a sampling frequency of the pulse width modulation signal across the reset capacitor. 4. The amplitude normalization circuit of claim 1 , wherein the comparator includes a pulse width modulation comparator having a positive input terminal to which the full-wave rectified voltage is inputted and a negative input terminal to which the triangular wave voltage is inputted, the pulse width modulation comparator being configured to compare the full-wave rectified voltage with the triangular wave voltage and output a pulse width modulation signal with constant amplitude. 5. The amplitude normalization circuit of claim 1 , wherein the level shifter includes a CMOS circuit including a p-channel MOS transistor that is connected in series between a ground potential and a power supply voltage having a value equal to the constant amplitude and has a source connected to the power supply voltage, and an n-channel MOS transistor having a source connected to the ground potential, wherein the level-shifted pulse width modulation signal is output at a node between a drain of the p-channel MOS transistor and a drain of the n-channel MOS transistor. 6. The amplitude normalization circuit of claim 5 , wherein the low pass filter includes a filter resistor and a filter capacitor that are connected in series between the ground potential and an output of the CMOS circuit, wherein an output voltage having the constant amplitude is generated across the filter capacitor. 7. The amplitude normalization circuit of claim 1 , wherein a sampling frequency of the pulse width modulation signal is higher by three or more orders of magnitude than a frequency of a waveform of the AC voltage. 8. The amplitude normalization circuit of claim 1 , further comprising an attenuator which attenuates the full-wave rectified voltage. 9. The amplitude normalization circuit of claim 8 , wherein an attenuation factor of the attenuator is equal to 1. 10. A power supply comprising an amplitude normalization circuit the amplitude normalization circuit including: a peak detector configured to detect a peak value of a full-wave rectified voltage of an AC voltage; a triangular wave oscillator connected to the peak detector, configured to generate a triangular wave voltage having a peak based on the peak value of the full-wave rectified voltage; a comparator connected to the triangular wave oscillator, configured to compare the triangular wave voltage with the full-wave rectified voltage and output a pulse width modulation signal; and a waveform converter connected to the comparator, configured to convert a waveform of the pulse width modulation signal and output an output voltage with a constant amplitude, wherein the waveform converter includes: a level shifter configured to shift a level of the pulse width modulation signal; and a low pass filter connected to the level shifter, configured to filter the level-shifted pulse width modulation signal. 11. A power supply comprising: a diode bridge connected to an AC voltage; an inductance connected to an AC line via a load; a current sense resistor connected to a ground potential; a MOSFET connected in series between the inductance and the current sense resistor; an amplitude normalization circuit including: a peak detector configured to detect a peak value of a full-wave rectified voltage of an AC voltage; a triangular wave oscillator connected to the peak detector, configured to generate a triangular wave voltage having a peak based on the peak value of the full-wave rectified voltage; a comparator connected to the triangular wave oscillator, configured to compare the triangular wave voltage with the full-wave rectified voltage and output a pulse width modulation signal; and a waveform converter connected to the comparator, configured to convert a waveform of the pulse width modulation signal and output an output voltage with a constant amplitude; and a PFC controller connected to the MOSFET and the current sense resistor, and corrects a power factor of a current flowing into the load, wherein the waveform converter includes: a level shifter configured to shift a level of the pulse width modulation signal; and a low pass filter connected to the level shifter, configured to filter the level-shifted pulse width modulation signal. 12. The power supply of claim 11 , wherein the PFC controller includes: a pulse width modulation signal generator; an error amplifier having a positive input terminal connected to the current sense resistor and a negative input terminal connected to an output of the amplitude normalization circuit; a RS flip-flop connected to an output of the pulse width modulation signal generator and an output of the error amplifier, configured to output a PWM control signal for the MOSFET; and a buffer connected to an output of the RS flip-flop, configured to drive the MOSFET. 13. The power supply of claim 12 , wherein the MOSFET is turned on at a set operation timing of the RS flip-flop and is turned off at a reset operation timing of the RS flip-flop. 14. The power supply of claim 11 , wherein the power supply is one of a PFC step-down LED lighting device, a PFC step-up LED lighting device and a PFC flyback LED lighting device. 15. An electronic apparatus comprising a power supply including an amplitude normalization circuit, the amplitude normalization circuit including: a peak detector configured to detect a peak value of a full-wave rectified voltage of an AC voltage; a triangular wave oscillator connected to the peak detector, configured to generate a triangular wave voltage having a peak based on the peak value of the full-wave recti