Apparatus and methods for high voltage variable capacitor arrays with body-to-gate diodes
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H03H-007/01
H01G-007/00
H01L-027/08
H03H-007/06
H03H-001/02
H03H-011/04
H03H-011/28
H03H-001/00
출원번호
US-0705429
(2015-05-06)
등록번호
US-9515631
(2016-12-06)
발명자
/ 주소
Madan, Anuj
Gupta, Dev V.
Lai, Zhiguo
출원인 / 주소
TDK Corporation
대리인 / 주소
Nixon Peabody LLP
인용정보
피인용 횟수 :
4인용 특허 :
29
초록▼
Apparatus and methods for high voltage variable capacitors are provided herein. In certain configurations, an integrated circuit (IC) includes a variable capacitor array and a bias voltage generation circuit that biases the variable capacitor array to control the array's capacitance. The variable ca
Apparatus and methods for high voltage variable capacitors are provided herein. In certain configurations, an integrated circuit (IC) includes a variable capacitor array and a bias voltage generation circuit that biases the variable capacitor array to control the array's capacitance. The variable capacitor array includes a plurality of variable capacitor cells electrically connected in parallel between a radio frequency (RF) input and an RF output of the IC. Additionally, each of the variable capacitor cells can include a cascade of two or more pairs of anti-series metal oxide semiconductor (MOS) capacitors between the RF input and the RF output. The pairs of anti-series MOS capacitors include a first MOS capacitor and a second MOS capacitor electrically connected in anti-series. The bias voltage generation circuit generates bias voltages for biasing the MOS capacitors of the variable capacitor cells.
대표청구항▼
1. An integrated circuit comprising: a variable capacitor array including at least three variable capacitor cells electrically connected in parallel between a radio frequency (RF) input and an RF output, wherein each of the at least three variable capacitor cells includes: two or more pairs of anti-
1. An integrated circuit comprising: a variable capacitor array including at least three variable capacitor cells electrically connected in parallel between a radio frequency (RF) input and an RF output, wherein each of the at least three variable capacitor cells includes: two or more pairs of anti-series metal oxide semiconductor (MOS) capacitors electrically connected in series between the RF input and the RF output, wherein a first pair of the two or more pairs of anti-series MOS capacitors comprises a first MOS capacitor and a second MOS capacitor electrically connected in anti-series, and wherein a second pair of the two or more pairs of anti-series MOS capacitors comprises a third MOS capacitor and a fourth MOS capacitor electrically connected in anti-series; anda plurality of diodes configured to control a plurality of body voltages of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells to increase a power handling capability of each of the at least three variable capacitor cells,wherein the integrated circuit does not include any switches along a signal path between the RF input and the RF output through the variable capacitor array. 2. The integrated circuit of claim 1, wherein the plurality of diodes comprises: a first diode including an anode electrically connected to a body of the first MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the first MOS capacitor of each of the at least three variable capacitor cells;a second diode including an anode electrically connected to a body of the second MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the second MOS capacitor of each of the at least three variable capacitor cells;a third diode including an anode electrically connected to a body of the third MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the third MOS capacitor of each of the at least three variable capacitor cells; anda fourth diode including an anode electrically connected to a body of the fourth MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the fourth MOS capacitor of each of the at least three variable capacitor cells. 3. The integrated circuit of claim 2, wherein a third pair of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells includes a fifth MOS capacitor and a sixth MOS capacitor electrically connected in anti-series, wherein the plurality of diodes further comprises: a fifth diode including an anode electrically connected to a body of the fifth MOS capacitor and a cathode electrically connected to a gate of the fifth MOS capacitor; anda sixth diode including an anode electrically connected to a body of the sixth MOS capacitor and a cathode electrically connected to a gate of the sixth MOS capacitor. 4. The integrated circuit of claim 1, wherein the plurality of diodes comprise a plurality of p-n junction diodes. 5. The integrated circuit of claim 1, further comprising two or more drift protection resistors configured to balance a DC operating point across the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells, wherein the two or more drift protection resistors comprise a first drift protection resistor electrically connected in parallel with the first pair of anti-series MOS capacitors of each of the at least three variable capacitor cells and a second drift protection resistor electrically connected in parallel with the second pair of anti-series MOS capacitors of each of the at least three variable capacitor cells. 6. The integrated circuit of claim 1, wherein each of the at least three variable capacitor cells comprises at least three pairs of anti-series MOS capacitors. 7. The integrated circuit of claim 1, further comprising a bias voltage generation circuit configured to bias the at least three variable capacitor cells to control a capacitance of the variable capacitor array. 8. The integrated circuit of claim 7, wherein the bias voltage generation circuit is configured to bias at least a first variable capacitor cell of the at least three variable capacitor cells with a first bias voltage, wherein the bias voltage generation circuit is configured to control the first bias voltage to a voltage level selected from a discrete number of two or more bias voltage levels. 9. The integrated circuit of claim 8, wherein the first MOS capacitor of each of the at least three variable capacitor cells and the second MOS capacitor of each of the at least three variable capacitor cells are electrically connected to one another at a first intermediate node, wherein the third MOS capacitor of each of the at least three variable capacitor cells and the fourth MOS capacitor of each of the at least three variable capacitor cells are electrically connected to one another at a second intermediate node, wherein the at least a first variable capacitor cell further includes: a first control biasing resistor electrically connected between the first bias voltage and the first intermediate node; anda second control biasing resistor electrically connected between the first bias voltage and the second intermediate node. 10. The integrated circuit of claim 9, wherein the at least a first variable capacitor cell further comprises a plurality of DC biasing resistors configured to bias the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells with a reference voltage. 11. The integrated circuit of claim 1, wherein a gate of the first MOS capacitor of each of the at least three variable capacitor cells is electrically connected to a gate of the second MOS capacitor of each of the at least three variable capacitor cells, and wherein a gate of the third MOS capacitor of each of the at least three variable capacitor cells is electrically connected to a gate of the fourth MOS capacitor of each of the at least three variable capacitor cells. 12. The integrated circuit of claim 1, wherein a source and a drain of the first MOS capacitor of each of the at least three variable capacitor cells are electrically connected to a source and a drain of the second MOS capacitor of each of the at least three variable capacitor cells, and wherein a source and a drain of the third MOS capacitor of each of the at least three variable capacitor cells are electrically connected to a source and a drain of the fourth MOS capacitor of each of the at least three variable capacitor cells. 13. The integrated circuit of claim 1, wherein the integrated circuit is formed using a silicon on insulator (SOI) substrate. 14. An apparatus comprising: a radio frequency (RF) input;an RF output;at least three variable capacitor cells electrically connected in parallel between the RF input and the RF output, wherein each of the at least three variable capacitor cells includes: two or more pairs of anti-series metal oxide semiconductor (MOS) capacitors electrically connected in series between the RF input and the RF output, wherein a first pair of the two or more pairs of anti-series MOS capacitors comprises a first MOS capacitor and a second MOS capacitor electrically connected in anti-series, and wherein a second pair of the two or more pairs of anti-series MOS capacitors comprises a third MOS capacitor and a fourth MOS capacitor electrically connected in anti-series; anda plurality of diodes configured to control a plurality of body voltages of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells to increase a power handling capability of each of the at least three variable capacitor cells,wherein each of the at least three variable capacitor cells does not include any switches along a signal path between the RF input and the RF output through the variable capacitor array. 15. The apparatus of claim 14, wherein the plurality of diodes comprises: a first diode including an anode electrically connected to a body of the first MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the first MOS capacitor of each of the at least three variable capacitor cells;a second diode including an anode electrically connected to a body of the second MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the second MOS capacitor of each of the at least three variable capacitor cells;a third diode including an anode electrically connected to a body of the third MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the third MOS capacitor of each of the at least three variable capacitor cells; anda fourth diode including an anode electrically connected to a body of the fourth MOS capacitor of each of the at least three variable capacitor cells and a cathode electrically connected to a gate of the fourth MOS capacitor of each of the at least three variable capacitor cells. 16. A method of providing a variable capacitance in a radio frequency (RF) system, the method comprising: generating a plurality of bias voltages including a first bias voltage using a bias voltage generation circuit;controlling a voltage level of the first bias voltage based on a control signal using the bias voltage generation circuit;biasing a first variable capacitor cell of at least three variable capacitor cells connected in parallel of a variable capacitor array using the first bias voltage, wherein each of the at least three variable capacitor cells includes two or more pairs of anti-series MOS capacitors electrically connected in series between a radio frequency (RF) input and an RF output of the variable capacitor array, the variable capacitor array does not include any switches along a signal path between the RF input and the RF output through the variable capacitor array, wherein a first pair of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells includes a first MOS capacitor and a second MOS capacitor electrically connected in anti-series, and wherein a second pair of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells includes a third MOS capacitor and a fourth MOS capacitor electrically connected in anti-series; andcontrolling a plurality of body voltages of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells using a plurality of diodes to increase a power handling capability of each of the at least three variable capacitor cells. 17. The method of claim 16, wherein controlling the plurality of body voltages comprises: controlling a body voltage of the first MOS capacitor of each of the at least three variable capacitor cells using a first diode electrically connected between a body and a gate of the first MOS capacitor of each of the at least three variable capacitor cells;controlling a body voltage of the second MOS capacitor of each of the at least three variable capacitor cells using a second diode electrically connected between a body and a gate of the second MOS capacitor of each of the at least three variable capacitor cells;controlling a body voltage of the third MOS capacitor of each of the at least three variable capacitor cells using a third diode electrically connected between a body and a gate of the third MOS capacitor of each of the at least three variable capacitor cells; andcontrolling a body voltage of the fourth MOS capacitor of each of the at least three variable capacitor cells using a fourth diode electrically connected between a body and a gate of the fourth MOS capacitor of each of the at least three variable capacitor cells. 18. The method of claim 17, wherein a third pair of the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells includes a fifth MOS capacitor and a sixth MOS capacitor electrically connected in anti-series, wherein biasing the plurality of bodies further comprises controlling a body voltage of the fifth MOS capacitor using a fifth diode electrically connected between a body and a gate of the fifth MOS capacitor and controlling a body voltage of the sixth MOS capacitor using a sixth diode electrically connected between a body and a gate of the sixth MOS capacitor. 19. The method of claim 16, further comprising balancing a DC operating point across the two or more pairs of anti-series MOS capacitors of each of the at least three variable capacitor cells using two or more drift protection resistors.
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