ACTIVE DISCHARGE SYSTEMS AND METHODS
First Claim
1. An implantable pulse generator for generating electrical pulses for stimulation of tissue of a patient, the implantable pulse generator comprising:
- a controller;
pulse generating circuitry for generating electrical pulses, the pulse generating circuitry comprising (i) a voltage multiplier for providing a plurality of voltages for pulse generation and (ii) at least one variable resistance circuit disposed in a circuit path of the pulse generating circuitry to control a magnitude of a respective electrical pulse;
switching circuitry for delivering electrical pulses from the pulse generating circuitry to outputs of the implantable pulse generator; and
output capacitors disposed between the switching circuitry and the outputs of the implantable pulse generator;
the controller, controlling the pulse generating circuitry and the switching circuitry, to repeatedly generate consecutive first and second pulses to stimulate tissue of a patient using each first pulse and to discharge residual charge left on one or more output capacitors by each first pulse with each second pulse, wherein the controller controls the voltage multiplier to provide a lower voltage and controls the at least one variable resistance circuit to provide a lower resistance for each second pulse relative to each first pulse.
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Abstract
To avoid charge accumulation on capacitive connections to implanted electrodes during delivery of stimulation pulses, stimulation pulses are followed by active discharge pulses having opposite polarity of the stimulation pulses. The active discharge pulses preferably have at least one pulse attribute magnitude (e.g., duration, voltage, and/or current) different than a corresponding stimulation pulse and are preferably programmable. Approximately the same total net current flow is delivered during active discharge pulses as during the stimulation pulses, but in the opposite direction and optionally at a lower amplitude. In addition, by reducing the driving voltage and a variable load within the electrical path for delivery of the pulses, power dissipation during active discharge is preferably reduced.
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Citations
14 Claims
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1. An implantable pulse generator for generating electrical pulses for stimulation of tissue of a patient, the implantable pulse generator comprising:
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a controller; pulse generating circuitry for generating electrical pulses, the pulse generating circuitry comprising (i) a voltage multiplier for providing a plurality of voltages for pulse generation and (ii) at least one variable resistance circuit disposed in a circuit path of the pulse generating circuitry to control a magnitude of a respective electrical pulse; switching circuitry for delivering electrical pulses from the pulse generating circuitry to outputs of the implantable pulse generator; and output capacitors disposed between the switching circuitry and the outputs of the implantable pulse generator; the controller, controlling the pulse generating circuitry and the switching circuitry, to repeatedly generate consecutive first and second pulses to stimulate tissue of a patient using each first pulse and to discharge residual charge left on one or more output capacitors by each first pulse with each second pulse, wherein the controller controls the voltage multiplier to provide a lower voltage and controls the at least one variable resistance circuit to provide a lower resistance for each second pulse relative to each first pulse. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. A method of operating an implantable pulse generator to generate electrical pulses for stimulation of tissue of a patient, the method comprising:
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operating pulse generating circuitry to repeatedly generate first and second electrical pulses, the pulse generating circuitry comprising (i) a voltage multiplier for providing a plurality of voltages for pulse generation and (ii) at least one variable resistance circuit disposed in a circuit path of the pulse generating circuitry to control a magnitude of a respective electrical pulse; operating switching circuitry for delivering the first and second electrical pulses from the pulse generating circuitry to outputs of the implantable pulse generator, wherein output capacitors are disposed between the switching circuitry and the outputs of the implantable pulse generator; and controlling the pulse generating circuitry and the switching circuitry to stimulate tissue of the patient with each first pulse and to discharge residual charge left on one or more output capacitors by each first pulse with each second pulse, wherein the controlling controls the voltage multiplier to provide a lower voltage and controls the at least one variable resistance circuit to provide a lower resistance for each second pulse relative to each first pulse. - View Dependent Claims (9, 10, 11, 12, 13, 14)
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Specification