POWER AMPLIFIER (PA) EFFICIENCY WITH LOW CURRENT DC TO DC CONVERTER

US 20050285681A1
Filed: 06/25/2004
Published: 12/29/2005
Est. Priority Date: 06/25/2004
Status: Active Grant

First Claim

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1. A power amplifier (PA) circuit comprising:

a PA output stage having a first amplifying portion having a first amplification and disposed in parallel with a second amplifying portion having a second amplification portion, the PA output stage having an output stage input port for receiving of a RF input signal, an output stage output port for providing of an amplified RF signal, and an output stage amplification being the amplification from the output stage input port to the output stage output port;

at least a biasing circuit for biasing of at least one of the first amplifying portion and the second amplifying portion;

a DC to DC converter circuit coupled with the second amplifying portion for providing of a second converted output voltage to the second amplifying portion;

a first control port coupled with the DC to DC converter and for receiving a first control signal to control the DC to DC converter second converted output voltage in dependence upon a predetermined signal strength of the amplified RF signal at the output stage output port; and

, a second control port coupled with the at least a biasing circuit and for receiving a second control signal to control the at least a biasing circuit in such a manner that a ratio of RF input signal amplification between the first amplification and the second amplification varies in dependence upon the predetermined signal strength at the output stage output port.

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Abstract

A novel method and apparatus is disclosed for reducing power dissipation of RF power amplifiers when a reduced output power level is required. The mechanism has the specific purpose of optimizing the collector terminal voltage on portions of the amplifier'"'"'s RF chain for maintaining linearity while minimizing power consumption. The apparatus permits a smaller DC to DC converter to be used than in prior art, such that it is implemented in the same semiconductor die or module. Furthermore, the invention eliminates the amplification and phase continuity issues that arise from switched state power amplifiers and envelope-following approaches.

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23 Claims

1. A power amplifier (PA) circuit comprising:
- a PA output stage having a first amplifying portion having a first amplification and disposed in parallel with a second amplifying portion having a second amplification portion, the PA output stage having an output stage input port for receiving of a RF input signal, an output stage output port for providing of an amplified RF signal, and an output stage amplification being the amplification from the output stage input port to the output stage output port;
  
  at least a biasing circuit for biasing of at least one of the first amplifying portion and the second amplifying portion;
  
  a DC to DC converter circuit coupled with the second amplifying portion for providing of a second converted output voltage to the second amplifying portion;
  
  a first control port coupled with the DC to DC converter and for receiving a first control signal to control the DC to DC converter second converted output voltage in dependence upon a predetermined signal strength of the amplified RF signal at the output stage output port; and
  
  , a second control port coupled with the at least a biasing circuit and for receiving a second control signal to control the at least a biasing circuit in such a manner that a ratio of RF input signal amplification between the first amplification and the second amplification varies in dependence upon the predetermined signal strength at the output stage output port.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. A PA circuit according to claim 1 comprising:
    - a second RF power detector for detecting a signal power of the RF input signal and for providing a second detected signal based on the detected signal power; and
      
      , an automatic bias control circuit coupled with the second detector circuit for receiving of the second detected signal therefrom and coupled to the at least a biasing circuit for adjusting the ratio of RF input signal amplification between the first amplifying portion and the second amplifying portion.
  - 3. A PA circuit according to claim 2 wherein the at least a biasing circuit comprises:
    - a first biasing circuit for biasing of the first amplifying portion; and
      
      a second biasing circuit different from the first biasing circuit for biasing of the second amplifying portion.
  - 4. A PA circuit according to claim 2 comprising:
    - an input amplification stage having an input amplification and an input port for receiving of the RF input signal and an output port for providing of the amplified version of the RF input signal to the input port of the output amplification stage, the input amplification stage comprising;
      
      a first amplification stage; and
      
      , a first RF power detector circuit coupled with the input port of the input amplification stage for detecting a signal power of the RF input signal for providing a first detected signal to the automatic bias control circuit in dependence upon the detected signal power, wherein the DC to DC converter circuit is coupled with the first amplification stage for providing a first converted output voltage to the first amplification stage.
  - 5. A PA circuit according to claim 1 comprising:
    - a semiconductor die, wherein the DC to DC converter is integrated with the power amplifier circuit on the semiconductor die.
  - 6. A PA circuit according to claim 1 wherein the first amplifying portion comprises a third transistor and the second amplifying portion comprises a second transistor, wherein the third transistor is approximately 2 to 10 times larger than the size of the second transistor.
  - 7. A PA circuit according to claim 1 wherein the second amplifying portion comprises a second bipolar transistor having one of the emitter and collector terminals coupled with the DC to DC converter for receiving of the converted output voltage.
  - 8. A PA circuit according to claim 1 wherein the first amplifying portion comprises a third bipolar transistor having one of the emitter and collector terminals coupled with the first supply voltage port and comprises other than a direct coupling with the DC to DC converter.

9. A method of controlling PA linearity and power consumption comprising:
- providing of a PA output stage having a first amplifying portion having a first amplification and a second amplifying portion having a second amplification that is greater than the first amplification, where the first amplification and the second amplification together form an output stage amplification;
  
  providing of a DC to DC converted for providing a converted output voltage;
  
  receiving of a RF input signal by the PA output stage;
  
  determining whether a signal power of the RF input signal is one of below a threshold signal power level and above the threshold signal power level;
  
  when the signal power of the RF input signal is below the threshold signal power level;
  
  biasing of the first amplifying portion with a low bias voltage;
  
  when the signal power of the RF input signal is above the threshold signal power level;
  
  biasing of the first amplifying portion with a high bias voltage that is higher than the low bias voltage;
  
  biasing of the second amplifying portion using the converted output voltage received from the DC to DC converter; and
  
  , amplifying of the RF input signal to form a RF output signal that is an amplified version of the RF input signal.
- View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 10. A method according to claim 9 wherein when the first amplifying portion is biased with the low bias voltage it other than contributes first amplification to the output stage amplification.
  - 11. A method according to claim 9 wherein when the first amplifying portion is biased at low bias voltage it does not significantly contribute to the power consumption of the PA output stage.
  - 12. A method according to claim 9 comprising:
    - detecting a power of the RF input signal to determine whether the signal power of the RF input signal is one of below a threshold signal power level and above the threshold signal power level.
  - 13. A method according to claim 12 wherein when the signal power of the RF input signal is above the threshold signal power level the second amplifying portion operates in a saturation mode of operation.
  - 14. A method according to claim 9 comprising increasing a linearity of the output stage by increasing a second converted output voltage that is provided to the second amplifying portion.
  - 15. A method according to claim 9 comprising:
    - determining a power consumption of the PA output stage in order to determine the threshold signal power level for reducing of the power consumption of the PA output stage.
  - 16. A method according to claim 15 comprising:
    - varying of the threshold signal power level for reducing of the power consumption of the PA output stage.
  - 17. A method according to claim 9 comprising:
    - receiving of a first amplified signal from the first amplifying portion having the first amplification;
      
      receiving of a second amplified signal from the second amplifying portion having the second amplification; and
      
      , summing the first and second amplified signals to form the output signal having the output stage amplification.
  - 18. A method according to claim 9 comprising:
    - other than providing of the converted output voltage to the first amplifying portion.

19. A power amplifier (PA) comprising:
- a PA output stage having a first amplifying portion having a first amplification and disposed in parallel with a second amplifying portion having a second amplification, the PA output stage having an output stage input port for receiving of a RF input signal, an output stage output port for providing of an amplified RF signal, and an output stage amplification being the amplification of the RF input signal from the output stage input port to the output stage output port;
  
  a DC to DC converter circuit comprising a first control port for receiving a first control signal for controlling the DC to DC converter for providing of a second converted output voltage to the second amplifying portion in dependence upon a predetermined signal strength of the amplified RF signal at the output stage output port; and
  
  , at least a biasing circuit for biasing the first amplifying portion in dependence upon the first control signal for amplifying the RF input signal such that for the output stage amplification a ratio between the first amplification and the second amplification varies in dependence upon the first control signal.
- View Dependent Claims (20, 21, 22, 23)
- - 20. A PA according to claim 19 wherein the at least a biasing circuit comprises:
    - a first biasing circuit for biasing of the first amplifying portion; and
      
      , a second biasing circuit different from the first biasing circuit for biasing of the second amplifying portion.
  - 21. A power amplifier circuit according to claim 20 comprising:
    - an input amplification stage having an input amplification and an input port for receiving of the RF input signal and an output port for providing of the amplified version of the RF input signal to the input port of the output amplification stage, the input amplification stage comprising;
      
      a first amplification stage, wherein the DC to DC converter circuit is for providing a first converted output voltage to the first amplification stage.
  - 22. A PA according to claim 19 comprising:
    - a same semiconductor substrate, wherein the DC to DC converted is integrated with the PA output stage on the same semiconductor substrate.
  - 23. A PA according to claim 19 wherein the first amplifying portion comprises a third transistor and the second amplifying portion comprises a second transistor, wherein the third transistor is approximately 2 to 10 times the size of the second transistor.

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Current Assignee
Skyworks Solutions Incorporated
Original Assignee
SIGE Semiconductor Incorporated (Skyworks Solutions Incorporated)
Inventors
Doherty, Mark, Harrison, Jose, Quaglietta, Anthony

Granted Patent

US 7,091,790 B2
Time in Patent Office

Days
Field of Search
US Class Current

330/297
CPC Class Codes

H03F 1/02   Modifications of amplifiers...

H03F 1/0205   in transistor amplifiers

H03F 1/0227   using supply converters

H03F 3/191   Tuned amplifiers H03F3/193,...

H03F 3/21   with semiconductor devices ...

POWER AMPLIFIER (PA) EFFICIENCY WITH LOW CURRENT DC TO DC CONVERTER

First Claim

3 Assignments

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Abstract

34 Citations

23 Claims

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POWER AMPLIFIER (PA) EFFICIENCY WITH LOW CURRENT DC TO DC CONVERTER

First Claim

3 Assignments

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0 Petitions

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Accused Products

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Abstract

34 Citations

23 Claims

Specification

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Solutions

Use Cases

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