Claims
- 1. An electronic driver circuitry for an integrated RF switching diode, comprising:a CMOS integrated circuit diode for RF switching; a first PMOS transistor and a first poly-resistor circuit electrically connected to and for switching ON/OFF said CMOS integrated circuit diode, said first PMOS transistor having an equal current as said CMOS integrated circuit diode; a second poly-resistor in electrically connected with said first polyresistor for compensating variations in resistance; a plurality of cascaded PMOS transistors in circuit connection with said first PMOS transistor for compensating variations in gain and voltage threshold of said CMOS integrated circuit diode; and a plurality of cascaded NMOS transistors in circuit connection with said plurality of PMOS transistors for compensating for variations in supply voltage, wherein all compensation cancels out undesired variations keeping current across the CMOS integrated circuit diode constant.
- 2. The electronic driver circuitry of claim 1 wherein said resistance compensation is due to a connection of a second PMOS transistor to a third PMOS transistor, said second PMOS transistor and said third PMOS transistor connected such that current in said second PMOS transistor follows the current in said third PMOS transistor and said third PMOS transistor is connected to said second poly-resistor through a fourth NMOS transistor.
- 3. The electronic driver circuitry of claim 2 wherein a change of poly-resistor value of said second resistance causes an opposite change of current in said third PMOS transistor with said current in said second PMOS transistor having like current thereby compensating for an increase in resistance of said first poly-resistor wherein source voltage and current of said first PMOS transistor is held constant said current across the CMOS integrated circuit diode constant.
- 4. The electronic driver circuitry of claim 3 wherein said plurality of cascaded PMOS transistors are electrically connected to a fifth PMOS transistor electrically connected to said third PMOS transistor, and said fifth PMOS transistor and said third PMOS transistor connected such that current in said fifth PMOS transistor follows the current in said third PMOS transistor wherein variations in gain and voltage threshold are compensated by the electrical connection of said plurality of cascaded PMOS transistors through said fifth and third PMOS transistors.
- 5. The electronic driver circuitry of claim 4 wherein said plurality of cascaded PMOS transistors is three PMOS transistors connected in series defining a series voltage divider.
- 6. The electronic driver circuitry of claim 4 wherein said cascaded NMOS transistors are electrically connected to said fourth NMOS transistor, said fourth NMOS transistor electrically connected to said fifth PMOS transistor wherein variations in supply voltage are compensated through saidfifth, third and second PMOS transistors said fourth NMOS transistor.
- 7. The electronic driver circuitry of claim 6 wherein said plurality of cascaded NMOS transistors is three NMOS transistors connected in series defining a series voltage divider.
- 8. The electronic driver circuitry of claim 6 wherein a change of poly-resistor value of said second resistance causes an opposite change of current in said third PMOS transistor with said current in said second PMOS transistor having like current thereby compensating for an increase in resistance of said first poly-resistor wherein negative voltage of said first PMOS transistor is held constant said current across the CMOS integrated circuit diode constant.
- 9. An electronic driver circuitry for an integrated RF switching diode, comprising:a CMOS integrated circuit diode for RF switching; a first PMOS transistor and a first poly-resistor circuit electrically connected to and for switching ON/OFF said CMOS integrated circuit diode, said first PMOS transistor having an equal current as said CMOS integrated circuit diode; a second poly-resistor in electrically connected with said first polyresistor for compensating variations in resistance; a plurality of cascaded PMOS transistors in circuit connection with said first PMOS transistor for compensating variations in gain and voltage threshold of said CMOS integrated circuit diode; and a plurality of cascaded NMOS transistors in circuit connection with said plurality of PMOS transistors for compensating for variations in supply voltage, wherein said resistance compensation is due to a connection of a second PMOS transistor to a third PMOS transistor, said second PMOS transistor and said third PMOS transistor connected such that current in said second PMOS transistor follows the current in said third PMOS transistor and said third transistor is connected to said second poly-resistor through a fourth NMOS transistor whereby all compensation cancels out undesired variations keeping current across the CMOS integrated circuit diode constant.
- 10. The electronic driver circuitry of claim 9 wherein a change of poly-resistor value of said second resistance causes an opposite change of current in said third PMOS transistor with said current in said second PMOS transistor having like current thereby compensating for an increase in resistance of said first poly-resistor wherein source voltage and current of said first PMOS transistor is held constant said current across the CMOS integrated circuit diode constant.
- 11. The electronic driver circuitry of claim 10 wherein said plurality of cascaded PMOS transistors are electrically connected to a fifth PMOS transistor electrically connected to said third PMOS transistor, and said fifth PMOS transistor and said third PMOS transistor connected such that current in said fifth PMOS transistor follows the current in said third PMOS transistor wherein variations in gain and voltage threshold are compensated by the electrical connection of said plurality of cascaded PMOS transistors through said fifth and third PMOS transistors.
- 12. The electronic driver circuitry of claim 11 wherein said plurality of cascaded PMOS transistors is three PMOS transistors connected in series defining a series voltage divider.
- 13. The electronic driver circuitry of claim 12 wherein said cascaded NMOS transistors are electrically connected to said fourth NMOS transistor, said fourth NMOS transistor electrically connected to said fifth PMOS transistor wherein variations in supply voltage are compensated through said fifth, third and second PMOS transistors said fourth NMOS transistor.
- 14. The electronic driver circuitry of claim 13 wherein said plurality of cascaded NMOS transistors is three NMOS transistors connected in series defining a series voltage divider.
- 15. An electronic driver circuitry for an integrated RF switching diode, comprising:a CMOS integrated circuit diode for RF switching; a first PMOS transistor and a first poly-resistor circuit electrically connected to and for switching ON/OFF said CMOS integrated circuit diode, said first PMOS transistor having an equal current as said CMOS integrated circuit diode; a second poly-resistor in electrically connected with said first poly-resistor for compensating variations in resistance; a plurality of cascaded PMOS transistors in circuit connection with said first PMOS transistor for compensating variations in gain and voltage threshold of said CMOS integrated circuit diode; and a plurality of cascaded NMOS transistors in circuit connection with said plurality of PMOS transistors for compensating for variations in supply voltage, wherein said resistance compensation is due to a connection of a second PMOS transistor to a third PMOS transistor, said second PMOS transistor and said third PMOS transistor connected such that current in said second PMOS transistor follows the current in said third PMOS transistor and said third transistor is connected to said second poly-resistor through a fourth NMOS transistor wherein a change of resistance value of said second poly-resistor causes an opposite change of current in said third PMOS transistor with said current in said second PMOS transistor having like current thereby compensating for an increase in resistance of said first poly-resistor wherein source voltage and current of said first PMOS transistor is held constant said current across the CMOS integrated circuit diode constant whereby all compensation cancels out undesired variations keeping current across the CMOS integrated circuit diode constant.
- 16. The electronic driver circuitry of claim 15 wherein said plurality of cascaded PMOS transistors are electrically connected to a fifth PMOS transistor electrically connected to said third PMOS transistor, and said fifth PMOS transistor and said third PMOS transistor connected such that current in said fifth PMOS transistor follows the current in said third PMOS transistor wherein variations in gain and voltage threshold are compensated by the electrical connection of said plurality of cascaded PMOS transistors through said fifth and third PMOS transistors.
- 17. The electronic driver circuitry of claim 15 wherein said plurality of cascaded PMOS transistors is three PMOS transistors connected in series defining a series voltage divider.
- 18. The electronic driver circuitry of claim 15 wherein said cascaded NMOS transistors are electrically connected to said fourth NMOS transistor, said fourth NMOS transistor electrically connected to said fifth PMOS transistor wherein variations in supply voltage are compensated through said sixth, fifth, third and second PMOS transistors said fourth NMDS transistor.
- 19. The electronic driver circuitry of claim 15 wherein said plurality of cascaded NMOS transistors is three NMOS transistors connected in series defining a series voltage divider.
CROSS REFERENCE TO RELATED APPLICATION
Attention is directed to copending application Ser. No. 10/025,475, filed herewith, entitled, “Process and Temperature Compensation Circuit for Integrated RF Switching.” The disclosure of this reference is hereby incorporated in its entirety.
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
5757065 |
Buhler et al. |
May 1998 |
A |
5969561 |
McGillan |
Oct 1999 |
A |
6208191 |
Alexander |
Mar 2001 |
B1 |