초록

A synchronous voltage regulation circuit having an energy storage circuit for controlling the output signal is disclosed. The voltage regulation circuit includes a circuit which advantageously uses leakage inductance from loose coupling of input and output inductors to control regulator switching.

대표청구항 ▼

1. A synchronous voltage regulation circuit, comprising:an input inductor having an input inductor first terminal coupled to an input signal and an input inductor second terminal;a first switch, having a first switch first terminal coupled to the input inductor second terminal, a first switch second

1. A synchronous voltage regulation circuit, comprising:an input inductor having an input inductor first terminal coupled to an input signal and an input inductor second terminal;a first switch, having a first switch first terminal coupled to the input inductor second terminal, a first switch second terminal, and a first switch control terminal coupled to a control signal;a second switch, having a second switch first terminal coupled to the first switch second terminal, a second switch second terminal coupled to ground, and a second switch control terminal;an output inductor magnetically coupled to the input inductor according to a first coupling coefficient loosely coupled, the output inductor having an output inductor first terminal coupled to the second switch first terminal, and an output inductor second terminal coupled to an output signal;an auxiliary inductor having a first auxiliary inductor terminal coupled to ground via a first capacitor and a second auxiliary inductor terminal coupled to the second switch control terminal via a resistor, wherein the auxiliary inductor is magnetically coupled to the input inductor according to a second coupling coefficient higher than the first coupling coefficient; anda third switch, having a third switch first terminal coupled to the second switch control terminal, a control terminal coupled to the control signal. 2. The circuit of claim 1, wherein the input inductor is loosely magnetically coupled to the output inductor and the input inductor is tightly coupled to the auxiliary inductor. 3. The circuit of claim 1, wherein:the magnetic coupling between the input inductor and the output inductor manifests a leakage inductance;the control signal controls the first switch and the second switch to alternating “on” and “off” states; andswitching transients caused by a shorted path between the first switch and the second switch are absorbed into the leakage inductance and subsequently delivered to the output during the “on” state of the first switch. 4. The circuit of claim 1, wherein the first switch and the second switch, and the third switch are MOSFETs. 5. The circuit of claim 1, wherein:the magnetic coupling between the input inductor and the output inductor manifests a leakage inductance of greater than two nano-henries. 6. The circuit of claim 1, wherein the input inductor, the output inductor, and the auxiliary inductor are wound on a single magnetic core. 7. The circuit of claim 1, further comprising:a diode having a diode first terminal coupled to the input signal and a diode second terminal coupled to the second auxiliary inductor terminal; anda second capacitor having a second capacitor first terminal coupled to the second auxiliary inductor terminal and a second capacitor second terminal coupled to the input inductor second terminal. 8. The circuit of claim 1, wherein the intercoupled input inductor, output inductor, auxiliary inductor, first switch, second switch, third switch, capacitor and resistor together form a first phase voltage regulation circuit, and wherein the circuit further comprises a second phase voltage regulation circuit having:a second phase input inductor having a second phase input inductor first terminal coupled to the input signal and an second phase input inductor second terminal;a first second phase switch, having a first second phase switch first terminal coupled to the second phase input inductor second terminal, a first second phase switch second terminal, and a first second phase switch control terminal coupled to the control signal;a second second phase switch, having a second second phase switch first terminal coupled to the first second phase switch second terminal, a second second phase switch second terminal coupled to ground, and a second second phase switch control terminal;a second phase output inductor magnetically coupled to the second phase input inductor according to a second phase first coup ling coefficient loosely coupled, the second phase output inductor having a second phase output inductor first terminal coupled to the second second phase switch first terminal, and a second phase output inductor second terminal coupled to the output signal;a second phase auxiliary inductor having a first second phase auxiliary inductor terminal coupled to ground via the first capacitor and a second auxiliary inductor terminal coupled to the second second phase switch control terminal via a second phase resistor, wherein the second phase auxiliary inductor is magnetically coupled to the second phase input inductor according to a second phase second coupling coefficient higher than the second phase first coupling coefficient; anda second phase third switch, having a second phase third switch first terminal coupled to the second second phase switch control terminal, a second phase third switch control terminal coupled to the control signal. 9. The circuit of claim 1, wherein:the circuit is at least partially implemented in a circuit board having an aperture; andat least one of the input inductor, the output inductor and the auxiliary inductor are disposed at the periphery of the aperture. 10. The circuit of claim 2, wherein the magnetic coupling between the auxiliary winding and the input inductor is less than 2 nano-henries. 11. The circuit of claim 6, wherein the magnetic core is substantially planar. 12. The circuit of claim 6, wherein at least one of the inductors comprise windings disposed as traces of a printed circuit board.