High frequency MOSFET switch

US 6,396,325 B2
Filed: 02/09/2001
Issued: 05/28/2002
Est. Priority Date: 12/03/1999
Status: Expired due to Term

First Claim

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1. A high frequency switch circuit for allowing or preventing the transfer of an electrical signal between a first node and a second node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first node when the switch circuit allows the transfer, and wherein the electrical signal is not transferred when the switch circuit prevents the transfer, wherein the high-frequency switch circuit is powered by a high-potential supply rail and a low-potential supply rail, the switch circuit comprising:

an enable signal node for receiving a switch circuit activation signal, the switch circuit activation signal defines an ON condition and an OFF condition of a MOS transfer transistor, the MOS transfer transistor having a source coupled to the first node and a drain coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said first impedance element is constructed to substantially negate low-parasitic shunt capacitance associated with said MOS transfer transistor, and. a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance element is constructed to substantially negate low-parasitic shunt capacitance associated with said MOS transfer transistor.

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Abstract

A high-frequency switch circuit having an MOS pass gate or transfer transistor. The switch circuit of the invention includes a first impedance element coupled to the gate of the transfer transistor and, preferably, an alternative second impedance element coupled to the bulk of the transfer transistor. One or both of the impedance elements substantially negates the low-parasitic shunt capacitance associated with the transfer transistor that controls signal attenuation under high frequency operation. The impedance element is coupled in series with that parasitic capacitance to increase substantially the impedance of that pathway, thereby increasing substantially the passable bandwidth. The impedance element may simply be a resistor. The switch circuit is suitable for use in an array of applications, including signal propagation in computing systems, routers, and flat panel screen displays.

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28 Claims

1. A high frequency switch circuit for allowing or preventing the transfer of an electrical signal between a first node and a second node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first node when the switch circuit allows the transfer, and wherein the electrical signal is not transferred when the switch circuit prevents the transfer, wherein the high-frequency switch circuit is powered by a high-potential supply rail and a low-potential supply rail, the switch circuit comprising:
- an enable signal node for receiving a switch circuit activation signal, the switch circuit activation signal defines an ON condition and an OFF condition of a MOS transfer transistor, the MOS transfer transistor having a source coupled to the first node and a drain coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said first impedance element is constructed to substantially negate low-parasitic shunt capacitance associated with said MOS transfer transistor, and. a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance element is constructed to substantially negate low-parasitic shunt capacitance associated with said MOS transfer transistor.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
- - 2. The switch circuit as claimed in claim 1 wherein said MOS transfer transistor is a PMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the high-potential supply rail.
  - 3. The switch circuit as claimed in claim 1 wherein said MOS transfer transistor is an NMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the low-potential supply rail.
  - 4. The switch circuit as claimed in claim 1 further comprising an inverter stage formed of one or more inverters coupled between said enable signal node and said first and second impedance elements.
  - 5. The switch circuit as claimed in claim 4 wherein said second impedance element includes an impedance PMOS transistor having a gate coupled to an output of said inverter stage, a source and a bulk coupled to the high-potential supply rail, and a drain coupled to said bulk of said PMOS transfer transistor.
  - 6. The switch circuit as claimed in claim 4 wherein said first and second impedance elements include a resistor having a high-potential node coupled to an output of said inverter stage and a low-potential node coupled to said gate of said PMOS transfer transistor.
  - 7. The switch circuit as claimed in claim 6 wherein said resistor of said impedance elements has a resistance of one kilo ohm or greater.
  - 8. The switch circuit as claimed in claim 6 wherein said inverter stage includes a first inverter coupled in series with a second inverter each having an input and an output, wherein said enable signal node is coupled to said input of said first inverter and said output of said second inverter is coupled to said high-potential node of said resistor, said impedance element further comprising an impedance PMOS transistor having a gate coupled to said output of said first inverter, a source coupled to the high-potential supply rail, and a drain coupled to said gate of said PMOS transfer transistor.
  - 9. The switch circuit as claimed in claim 4 wherein the second impedance element includes a second resistor having a high-potential node coupled to the high-potential supply rail and a low-potential node coupled to said bulk of said PMOS transfer transistor.
  - 10. The switch circuit as claimed in claim 9 wherein said second resistor of said second impedance element has a resistance of one kilohm or greater.
  - 11. The switch circuit as claimed in claim 9 wherein said inverter stage includes a first inverter coupled in series with a second inverter each having an input and an output, wherein said enable signal node is coupled to said input of said first inverter and said output of said second inverter is coupled to said high-potential node of said resistor of said impedance element, said second impedance element further comprising a PMOS transistor having a gate coupled to said output of said first inverter, a source coupled to the high-potential supply rail, and a drain coupled to said bulk of said PMOS transfer transistor.
  - 12. The switch circuit as claimed in claim 4, wherein the said first impedance element includes an impedance NMOS transistor having a gate coupled to an output of said inverter stage, a drain coupled to said gate of said PMOS transfer transistor, and a source and a bulk coupled to the low-potential supply rail.
  - 13. The switch circuit as claimed in claim 12 wherein said inverter stage includes a first inverter coupled in series with a second inverter each having an input and an output, wherein said enable signal node is coupled to said input of said first inverter and said output of said first inverter is coupled to said gate of said impedance NMOS transistor, said impedance element further comprising an impedance PMOS transistor having a gate coupled to said output of said first inverter, a source coupled to the high-potential supply rail, and a drain coupled to said gate of said PMOS transfer transistor.
  - 14. The switch circuit as claimed in claim 5 herein said inverter stage includes a first inverter coupled in series with a second inverter each having an input and an output, wherein said enable signal node is coupled to said input of said first inverter and said output of said second inverter is coupled to said gate of said impedance PMOS transistor of said second impedance element, said second impedance element further comprising a second impedance PMOS transistor having a gate coupled to said output of said first inverter, a source coupled to the high-potential supply rail, and a drain coupled to said bulk of said PMOS transfer transistor.

15. A high frequency switch circuit for allowing or preventing the transfer of an electrical signal between a first node and a second node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first node when the switch circuit defines an ON condition, and wherein the electrical signal is not transferred when the switch circuit defines an OFF condition, wherein the high-frequency switch circuit is powered by a high-potential supply rail and a low-potential supply rail, the switch circuit comprising:
- a MOS transfer transistor having a source coupled to the first node and a drain Coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said first impedance element serves to decouple said gate from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor, and a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance element responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance element serves to decouple said bulk from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor.

16. A computing system including switch circuits to allow or prevent the transfer of an electrical signal between a first signal transmission node and a second signal transmission node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first thereby defining an ON condition and defining an OFF condition when not transferred, wherein the switch circuit may be powered by a high-potential supply rail and a low potential supply rail, the computer system comprising:
- a MOS transfer transistor having a source coupled to the first node and a drain coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a light impedance, wherein said first impedance element serves to decouple said gate from either of the supply rails by substantially negating low-parasilic shunt capacitance associated with said MOS transfer transistor, and a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance element, responsive to the ON and Off conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance element serves to decouple said bulk from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor.
- View Dependent Claims (17, 18)
- - 17. The computer system as claimed in claim 16, wherein the MOS transfer transistor is an NMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the low-potential supply rail.
  - 18. The computer system as claimed in claim 16 wherein the MOS transfer transistor is an PMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the high-potential supply rail.

19. A router Including switch circuits to allow or prevent the transfer of an electrical signal between a first signal transmission node and a second signal transmission node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first thereby defining an ON condition and defining an OFF condition when not transferred, wherein the switch circuit may be powered by a high-potential supply rail and a low potential supply rail, the router comprisinga MOS transfer transistor having a source coupled to the first node and a drain coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance clement, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance wherein said first impedance element serves to decouple said gate from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS tansfer transistor, and a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance clement, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance clement serves to decouple said bulk from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor.
- View Dependent Claims (20, 21)
- - 20. The router as claimed in claim 19 wherein the MOS transfer transfer transistor is an NMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the low-potential supply rail.
  - 21. The router as claimed in claim 19 wherein the MOS transfer transistor is an PMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the high-potential supply rail.

22. A flat panel screen system including switch circuits to allow or prevent the transfer of an electrical signal between a first signal transmission node and a second signal transmission node, wherein the electrical signal is transferred from the first node to the second node or from the second node to the first thereby defining an ON condition and defining an OFF condition when not transferred, wherein the switch circuit is powered by a high-potential supply rail and a low potential supply rail, the flat panel screen system comprising:
- a MOS transfer transistor having a source coupled to the first node and a drain coupled to the second node, a first impedance element coupled between the high and the low potential supply rails and a gate of said MOS transfer transistor, wherein the first impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said first impedance clement serves to decouple said gate from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor, and a second impedance element coupled between the high and the low potential supply rails and a bulk of said MOS transfer transistor, wherein the second impedance element, responsive to the ON and OFF conditions, defines two states, where one state is a low impedance and the second state a high impedance, wherein said second impedance element serves to decouple said bulk from either of the supply rails by substantially negating low-parasitic shunt capacitance associated with said MOS transfer transistor.
- View Dependent Claims (23, 24)
- - 23. The computer system as claimed in claim 22 wherein the MOS transfer transistor is an NMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the low-potential supply rail.
  - 24. The computer system as claimed in claim 22 wherein the MOS transfer transistor is an PMOS transistor and said second impedance element is coupled between said bulk of said MOS transfer transistor and the high-potential supply rail.

25. A process for allowing or preventing the transfer of an electrical signal between a first signal transmission node and a second signal transmission node, wherein the electrical signal is transferred from the first node to the second or from the second node to the first, when allowed, the process comprising the steps of:
- coupling a MOS transfer transistor between the first node and the second node, said MOS transfer transistor having a gate and a bulk, and establishing a first impedance pathway configured to negate substantially low-parasitic shunt capacitance associated with said MOS transfer transistor and connecting said first impedance pathway to said gate of said MOS transfer transistor, and establishing a second impedance pathway con figured to negate substantially low-parasitic shunt capacitance associated with said MOS transfer transistor and connecting said second impedance pathway to said bulk of said MOS transfer transistor.
- View Dependent Claims (26, 27, 28)
- - 26. The process as claimed in claim 25 wherein said MOS transfer transistor is an NMOS and said second impedance is coupled between said bulk of said MOS transfer transistor and a low-potential supply rail.
  - 27. The process as claimed in claim 25 wherein said MOS transfer transistor is an PMOS and said second impedance is coupled between said bulk of said MOS transfer transistor and a high-potential supply rail.
  - 28. The process as claimed in claim 25 wherein said first impedance pathway and said second impedance pathway establish impedances that are sufficient to keep said MOS transfer transistor on when enabled without developing a shunting parasitic impedance pathway between said MOS transfer transistor and a power supply rail.

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Current Assignee
Semiconductor Components Industries LLC (ON Semiconductor Corporation)
Original Assignee
Fairchild Semiconductor Corporation (ON Semiconductor Corporation)
Inventors
Goodell, Trenor F.
Primary Examiner(s)
Cunningham, Terry D.
Assistant Examiner(s)
Nguyen, Hai L.

Application Number

US09/780,199
Publication Number

US 20010007430A1
Time in Patent Office

473 Days
Field of Search

327/308,374,376,377,382,383,427,434,435,404,327 326/17
US Class Current

327/308
CPC Class Codes

H03K 17/04123   in field-effect transistor ...

H03K 17/162   without feedback from the o...

H03K 17/687   the devices being field-eff...

H03K 2217/0018   Special modifications or us...

High frequency MOSFET switch

First Claim

7 Assignments

0 Petitions

Accused Products

Abstract

86 Citations

28 Claims

Specification

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High frequency MOSFET switch

First Claim

7 Assignments

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Subscription Required

0 Petitions

Subscription Required

Accused Products

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Abstract

86 Citations

28 Claims

Specification

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Solutions

Use Cases

Quick Links