This invention relates in general to DC-DC voltage converters, and more particularly, to a soft-start circuit for a converter that generates a voltage ramp with a certain slope.
A typical DC-DC converter is depicted in
A tank capacitor Cout is charged through an inductance Lout, that is initially discharged, thus an uncontrolled overshoot of the current through the inductor Lout and a consequent uncontrolled overshoot of the output voltage VOUT with respect to the pre-established regulation value, determined by the voltage VREF, is generated.
The first effect may cause a breach of the specifications of maximum value of the current that can be absorbed from the line VIN or of the power consumption in the high-side of the half-bridge. The second effect may damage the circuits supplied by the regulator.
In order to address this, DC-DC regulators may include a so-called “soft-start” circuit, illustrated in
The slope of the ramp is established as a function of the characteristics of the regulator and of the desired maximum current during the soft-start phase. Typically, the voltage ramp is generated by injecting a constant current through the tank capacitor. The slope is generally of about 1V/ms and this may be hard to obtain with a fully integrated architecture.
For example, U.S. Pat. No. 5,917,313 discloses a stepwise voltage ramp generator based on a switched capacitor circuit. U.S. Pat. No. 6,316,926 discloses a digital soft-start circuit for a DC-DC converter.
Other voltage ramp generators may, however, be desirable.
A stepwise voltage ramp generator having a simple architecture, fully integrable on a small silicon area, has now been found by the applicant.
The generator comprises a storage capacitor on which the voltage ramp is produced, and coupled to a supply line through a transistor connected to a diode-connected transistor biased with a certain current to form a current mirror. A by-pass switch driven by an externally generated PWM timing signal is electrically in parallel with the diode-connected transistor of the current mirror.
When the by-pass switch is open, the bias current through the diode is mirrored and injected through the tank capacitor, that is charged. When the by-pass switch is closed, the current mirror is by-passed and the voltage on the tank capacitor remains substantially constant. In this way, the mean slope of the voltage ramp that is produced may be determined by adjusting the duty-cycle of an externally generated PWM timing signal.
An exemplary embodiment of the voltage ramp generator of this disclosure is depicted in
When the by-pass switch is off, the circuit mirrors a bias current Iramp through the tank capacitor Cramp. When the by-pass switch is on, current may not flow through the current mirror and a charge current may not be injected in the tank capacitor Cramp.
The graph of
The mean slope of the voltage ramp is given by the ratio between the amplitude Vstep and the duration of a switching period T:
thus it can be adjusted by adjusting the duty-cycle of the signal Ck.
The generator may not need a digital-to-analog converter, and can be realized using a current mirror, a capacitor and a transistor. The generator of this disclosure has the versatility of a digital architecture and the ability of implementing even tiny voltage steps without using complex hardware, such as a high resolution DAC.
Optionally, the generator may be equipped with a discharge transistor of the tank capacitor, depicted in
An exemplary logic circuit for generating a PWM timing signal Ck with a duty-cycle of 50% is depicted in
The generator of this disclosure can be realized either in MOS or BJT technology. In the exemplary embodiment of
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VA08A0039 | Jul 2008 | IT | national |
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