A field-effect transistor (FET) driver is provided that includes an input modulator and an isolating capacitor. The input modulator is configured to output an alternating current (AC) signal. The isolating capacitor is configured to receive the AC signal as an input and to store a charge based on th
A field-effect transistor (FET) driver is provided that includes an input modulator and an isolating capacitor. The input modulator is configured to output an alternating current (AC) signal. The isolating capacitor is configured to receive the AC signal as an input and to store a charge based on the AC signal in a filter capacitor. The filter capacitor is configured to drive a capacitor-driven FET based on the stored charge.
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1. A field-effect transistor (FET) driver comprising: an input modulator configured to output an alternating current (AC) signal;an amplifier configured to amplify the AC signal; andan isolating capacitor configured to receive the amplified AC signal as an input, to store a charge based on the ampli
1. A field-effect transistor (FET) driver comprising: an input modulator configured to output an alternating current (AC) signal;an amplifier configured to amplify the AC signal; andan isolating capacitor configured to receive the amplified AC signal as an input, to store a charge based on the amplified AC signal in a filter capacitor, and to drive a capacitor-driven FET based on the stored charge;wherein the amplifier comprises a first resistor, a second resistor, and a transistor;wherein the first and second resistors are coupled to different terminals of the transistor; andwherein the first resistor is configured to receive a clock signal. 2. The FET driver of claim 1, wherein: the capacitor-driven FET comprises a FET coupled between a load and a driver stage, anda first node of a rectifier is coupled to the isolating capacitor, a second node of the rectifier is coupled to a gate of the FET, and a third node of the rectifier is coupled to a source of the FET. 3. A field-effect transistor (FET) driver comprising: an input modulator configured to output an alternating current (AC) signal; andan isolating capacitor configured to receive the AC signal as an input, to store a charge based on the AC signal in a filter capacitor, and to drive a capacitor-driven FET based on the stored charge;wherein the input modulator comprises an AND gate configured to receive a clock signal and a digital signal and to pass the clock signal based on the digital signal to generate the AC signal. 4. A field-effect transistor (FET) driver comprising: an input modulator configured to output an alternating current (AC) signal;an amplifier configured to amplify the AC signal; andan isolating capacitor configured to receive the amplified AC signal as an input, to store a charge based on the amplified AC signal in a filter capacitor, and to drive a capacitor-driven FET based on the stored charge;wherein: the capacitor-driven FET comprises a first FET and a second FET coupled in series between a load and a driver stage, anda first node of a rectifier is coupled to the isolating capacitor, a second node of the rectifier is coupled to a gate of the first FET and a gate of the second FET, and a third node of the rectifier is coupled to a source of the first FET and a source of the second FET. 5. A field-effect transistor (FET) driver comprising: an amplifier configured to receive a clock signal and a digital signal and to generate an amplified output based on the clock signal and the digital signal;a filter capacitor configured to drive a capacitor-driven FET based on a charge; andan isolating capacitor configured to store the charge in the filter capacitor based on the amplified output. 6. The FET driver of claim 5, further comprising: a rectifier configured to rectify an output of the isolating capacitor to generate a rectified output,wherein the filter capacitor is further configured to drive the capacitor-driven FET based on the rectified output. 7. The FET driver of claim 6, wherein the rectifier comprises two diodes. 8. The FET driver of claim 5, further comprising: an input modulator configured to provide the clock signal and the digital signal to the amplifier. 9. The FET driver of claim 5, further comprising: a discharge resistor configured to discharge the charge from the filter capacitor. 10. The FET driver of claim 5, wherein the amplifier comprises a first resistor, a second resistor, and a transistor. 11. The FET driver of claim 10, wherein: the first resistor is coupled between an emitter of the transistor and the clock signal, andthe second resistor is coupled between a high voltage and a collector of the transistor. 12. The FET driver of claim 10, wherein: the first resistor is coupled between an emitter of the transistor and a low voltage, andthe second resistor is coupled between a high voltage and a collector of the transistor. 13. The FET driver of claim 10, wherein a node of the isolating capacitor is coupled between the second resistor and a collector of the transistor. 14. A field device comprising: a capacitor-driven field-effect transistor (FET);a load coupled to a first node of the capacitor-driven FET; anda FET driver coupled to a second node of the capacitor-driven FET, wherein the FET driver comprises an isolating capacitor, and wherein the FET driver is configured to drive the capacitor-driven FET without changing a direct current value of the load;wherein the FET driver further comprises an amplifier configured to receive a clock signal and a digital signal and to generate an amplified output based on the clock signal and the digital signal. 15. The field device of claim 14, wherein the isolating capacitor is configured to receive an alternating current (AC) signal as an input, to store a charge based on the AC signal in a filter capacitor, and to drive the capacitor-driven FET based on the stored charge; and wherein the AC signal comprises the amplified output from the amplifier. 16. The field device of claim 14, wherein the FET driver further comprises: a filter capacitor configured to drive the capacitor-driven FET based on a charge, wherein the isolating capacitor is configured to store the charge in the filter capacitor based on the amplified output. 17. The field device of claim 16, wherein: the FET driver further comprises a rectifier configured to rectify an output of the isolating capacitor to generate a rectified output, andthe filter capacitor is further configured to drive the capacitor-driven FET based on the rectified output. 18. The field device of claim 17, wherein the FET driver further comprises a discharge resistor configured to discharge the charge from the filter capacitor. 19. The field device of claim 14, wherein: the amplifier comprises a first resistor, a second resistor and a transistor,the first resistor is coupled between an emitter of the transistor and a low voltage,the second resistor is coupled between a high voltage and a collector of the transistor, anda node of the isolating capacitor is coupled between the second resistor and the collector of the transistor. 20. The field device of claim 14, wherein: the amplifier comprises a first resistor, a second resistor and a transistor,the first resistor is coupled between an emitter of the transistor and a clock signal,the second resistor is coupled between a high voltage and a collector of the transistor, anda node of the isolating capacitor is coupled between the second resistor and the collector of the transistor.
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이 특허에 인용된 특허 (9)
Thomas, David; Reay, Richard, Capacitively coupled switched current source.
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