Boost converter for driving a capacitive load
First Claim
1. A two-way boost converter circuit for driving a capacitive load, for operation from first and second power supply connections, comprising:
- an inductor connected between said first and second power supply connections to pass current in a first direction;
a first switch connected in series between said inductor and said first power supply connection, said first switch receiving a high frequency signal during a first phase to negatively charge said capacitive load;
a second switch connected in series between said inductor and said second power supply connection, said second switch receiving a high frequency signal during a second phase to positively charge said capacitive load;
a third switch connected to a first terminal of said inductor, and a fourth switch connected to a second terminal of said inductor; and
a first diode connected in series with said third switch between an output terminal and said first terminal of said inductor, and a second diode connected in series with said fourth switch between said output terminal and said second terminal of said inductor, wherein said first and second diodes are connected to said output terminal with opposite respective orientations.
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Accused Products
Abstract
A DC--DC boost converter for directly driving a capacitive load employs four switches for cyclically commuting the connection configuration of an energy storing inductor. First and second switches are driven at a relatively high frequency and provide an impulsive charge path of the inductor by connecting one or the other end to a power supply rail. Third and fourth switches are driven in phase opposition to each other at a relatively low frequency and provide a discharge path from one and the other end of the inductor, respectively, toward an output node of the circuit to which the capacitive load is connected.
23 Citations
34 Claims
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1. A two-way boost converter circuit for driving a capacitive load, for operation from first and second power supply connections, comprising:
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an inductor connected between said first and second power supply connections to pass current in a first direction; a first switch connected in series between said inductor and said first power supply connection, said first switch receiving a high frequency signal during a first phase to negatively charge said capacitive load; a second switch connected in series between said inductor and said second power supply connection, said second switch receiving a high frequency signal during a second phase to positively charge said capacitive load; a third switch connected to a first terminal of said inductor, and a fourth switch connected to a second terminal of said inductor; and a first diode connected in series with said third switch between an output terminal and said first terminal of said inductor, and a second diode connected in series with said fourth switch between said output terminal and said second terminal of said inductor, wherein said first and second diodes are connected to said output terminal with opposite respective orientations. - View Dependent Claims (2, 3, 4, 5)
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6. A two-way boost converter circuit, for operation from first and second power supply connections, comprising:
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an inductor; a first switching circuit having an input receiving a high frequency signal during a first phase, the first switching circuit operatively connected to source current from said first power supply connection to a first terminal of said inductor; a second switching circuit having an input receiving a high frequency signal during a second phase, the second switching circuit operatively connected to sink current from a second terminal of said inductor to said second power supply connection; a third switching circuit operatively connected to source current from an output terminal to said first terminal of said inductor such that said first switching circuit negatively pumps the voltage at said output terminal responsive to said high frequency signal during said first phase; and a fourth switching circuit operatively connected to sink current from said second terminal of said inductor to said output terminal such that said second switching circuit positively pumps the voltage at said output terminal responsive to said high frequency signal during said second phase. - View Dependent Claims (7, 8, 9, 10, 11, 12, 13)
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14. A two-way boost converter circuit for driving a capacitive load, for operation from first and second power supply connections, comprising:
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first and second terminals for connection to an external inductor; a first switch connected in series between said first terminal and said first power supply connection, said first switch receiving a high frequency signal during a first phase to negatively charge said capacitive load; a second switch connected in series between said second terminal and said second power supply connection, said second switch receiving a high frequency signal during a second phase to positively charge said capacitive load; a third switch connected to said first terminal and a fourth switch connected to said second terminal; and a first diode connected in series with said third switch between an output terminal and said first terminal, and a second diode connected in series with said fourth switch between said output terminal and said second terminal;
wherein said first and second diodes are connected to said output terminal with opposite respective orientations. - View Dependent Claims (15, 16, 17, 18)
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19. An integrated two-way boost converter circuit, for operation from first and second power supply connections, comprising:
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first and second terminals for connection to an external inductor; a first switching circuit having an input receiving a high frequency signal during a first phase, the first switching circuit operatively connected to source current from said first power supply connection to said first terminal; a second switching circuit having an input receiving a high frequency signal during a second phase, the second switching circuit operatively connected to sink current from said second terminal to said second power supply connection; a third switching circuit operatively connected to source current from an output terminal to said first terminal such that said first switching circuit negatively pumps the voltage at said output terminal responsive to said high frequency signal during said first phase; and a fourth switching circuit operatively connected to sink current from said second terminal to said output terminal such that said second switching circuit positively pumps the voltage at said output terminal responsive to said high frequency signal during said second phase. - View Dependent Claims (20, 21, 22, 23, 24, 25, 26)
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27. A method for driving a capacitive load, comprising the steps of:
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a) driving current through an inductor in a first direction, the inductor having first and second terminals; b) chopping current to said inductor; c) connecting said first terminal of said inductor to said capacitive load to negatively charge said capacitive load; d) repeating steps a) to c) to progressively charge said capacitive load to a first voltage; e) driving current through said inductor in said first direction; f) chopping current to said inductor; g) connecting said second terminal of said inductor to said capacitive load to positively charge said capacitive load; and h) repeating steps e) to g) to progressively charge said capacitive load to a second voltage. - View Dependent Claims (28, 29)
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30. A boost converter for driving an output node connected to a terminal of a capacitive load having a second terminal connected to ground, the boost converter comprising:
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a first switch connected between a first terminal of the inductor and a supply rail; a second switch connected between a second terminal of the inductor and ground; a first discharge path between said first terminal of the inductor and said output node, and including a first diode and a third switch connected in series with each other; a second discharge path between said second terminal of the inductor and said output node, and including a second diode and a fourth switch connected in series with each other; said third and fourth switches being driven in phase opposition at a first control frequency and said first and second switches being driven in phase opposition at a second switching frequency substantially higher than said first frequency during a first semiperiod of closure of said third switch and during a second semiperiod of closure of said fourth switch. - View Dependent Claims (31, 32, 33, 34)
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Specification