Optimization methods for amplifier with variable supply power

US 9,219,445 B2
Filed: 03/14/2013
Issued: 12/22/2015
Est. Priority Date: 12/28/2012
Status: Active Grant

First Claim

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1. A circuit comprising:

an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement;

a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement; and

an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement, the optimizing circuital arrangement comprising;

a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal, the feedback network comprising;

a switch adapted to operatively connect and disconnect the feedback path between the RF output and the RF input based on the value of the first input control signal; and

a resistive-capacitive (R-C) series network operatively connected in series with the switch, wherein;

the feedback path is operatively connected when the amplifying arrangement operates in the linear region, andthe feedback path is operatively disconnected when the amplifying arrangement operates in the compression region.

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Abstract

Optimization methods via various circuital arrangements for amplifier with variable supply power are presented. In one embodiment, a switch can be controlled to include or exclude a feedback network in a feedback path to the amplifier to adjust a response of the amplifier dependent on a region of operation of the amplifier arrangement (e.g. linear region or compression region).

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14 Claims

1. A circuit comprising:
- an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement;
  
  a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement; and
  
  an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement, the optimizing circuital arrangement comprising;
  
  a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal, the feedback network comprising;
  
  a switch adapted to operatively connect and disconnect the feedback path between the RF output and the RF input based on the value of the first input control signal; and
  
  a resistive-capacitive (R-C) series network operatively connected in series with the switch, wherein;
  
  the feedback path is operatively connected when the amplifying arrangement operates in the linear region, andthe feedback path is operatively disconnected when the amplifying arrangement operates in the compression region.
- View Dependent Claims (4)
- - 4. The circuit according to claim 1 or claim 2, wherein the dynamic supply power is configured to vary as a time varying function of an envelope signal of an RF input signal of the amplifying arrangement.

2. A circuit comprising:
- an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement;
  
  a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement; and
  
  an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement, the optimizing circuital arrangement comprising;
  
  a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal, the feedback network comprising;
  
  a variable resistor adapted to operatively affect the response of the amplifying arrangement according to the value of the first input control signal wherein;
  
  a resistance value of the variable resistor is varied by the first input control signal within a first range of resistance values when the amplifying arrangement operates in the linear region, andthe resistance value of the variable resistor is varied by the first input control signal within a second range of resistance values when the amplifying arrangement operates in the compression region.
- View Dependent Claims (3)
- - 3. The circuit according to claim 2, wherein the resistance value of the variable resistor is:
    - a) continuously variable, or b) variable in discrete steps.

5. A circuit comprising:
- an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement, the amplifier arrangement comprising stacked transistors having a plurality of bias terminals configured to operatively provide a plurality of variable bias supplies to a plurality of gates of the stacked transistors, wherein the plurality of variable bias supplies are configured to further affect the response of the amplifying arrangement;
  
  a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement;
  
  an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement; and
  
  a circuital arrangement adapted to provide one or more variable bias supplies from the plurality of variable bias supplies to the one or more gate terminals, wherein the circuital arrangement comprises at least one of;
  
  a) a plurality of resistors configured as a voltage divider network, b) a transceiver unit, c) a variable power supply unit, and d) a lookup table,wherein the lookup table comprises current gain characteristic curve data of the stacked transistors.
- View Dependent Claims (6, 7, 8, 14)
- - 6. The circuit according to claim 5, wherein one or more of the plurality of variable bias supplies vary as a function of an envelope signal of an RF input signal of the amplifying arrangement.
  - 7. The circuit according to claim 6, wherein one or more of the plurality of variable bias supplies do not vary.
  - 8. The circuit according to claim 5, wherein at least one of the one or more of the plurality of variable bias supplies varies as a function of an envelope signal of the RF input signal when the amplifying arrangement operates in the compression region, and wherein at least one of the one or more of the plurality of variable bias supplies does not vary when the amplifying arrangement operates in the linear region.
  - 14. The circuit of claim 5, wherein the optimizing circuital arrangement comprises one or more of:
    - a) a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal,b) a first tunable matching network operatively coupled to the RF output of the amplifying arrangement such as to affect an output load to the amplifying arrangement in correspondence of an impedance value of the first tunable matching network, said first tunable matching network not included within a feedback path of the amplifying arrangement, wherein the impedance value of the first tunable matching network is adjustable based on a variable value of a second input control signal, andc) a second tunable matching network operatively coupled to an RF input of the amplifying arrangement such as to affect an input load to the amplifying arrangement in correspondence of an impedance value of the second tunable matching network, said second tunable matching network not included within the feedback path of the amplifying arrangement, wherein the second tunable matching network is adjustable based on a variable value of a third input control signal.

9. A circuit comprising:
- an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement;
  
  a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement;
  
  an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement; and
  
  a circuital arrangement configured to impress an effect upon an RF input signal of the amplifying arrangement such as to compensate for an undesired effect impressed upon the RF output of the amplifying arrangement in correspondence of affecting the response of the amplifying arrangement,wherein the effect impressed upon the RF input signal to the amplifying arrangement comprises one or more of;
  
  a) phase pre-distortion and b) amplitude pre-distortion.
- View Dependent Claims (10, 11, 12)
- - 10. The circuit of claim 9, wherein the optimizing circuital arrangement comprises one or more of:
    - a) a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal,b) a first tunable matching network operatively coupled to the RF output of the amplifying arrangement such as to affect an output load to the amplifying arrangement in correspondence of an impedance value of the first tunable matching network, said first tunable matching network not included within a feedback path of the amplifying arrangement, wherein the impedance value of the first tunable matching network is adjustable based on a variable value of a second input control signal, andc) a second tunable matching network operatively coupled to an RF input of the amplifying arrangement such as to affect an input load to the amplifying arrangement in correspondence of an impedance value of the second tunable matching network, said second tunable matching network not included within the feedback path of the amplifying arrangement, wherein the second tunable matching network is adjustable based on a variable value of a third input control signal.
  - 11. The circuit according to claim 9 or claim 10, wherein the further circuital arrangement comprises one or more of:
    - a) a lookup table comprising pre-distortion coefficients, and b) a transceiver unit.
  - 12. The circuit according to claim 11, wherein the pre-distortion coefficients are in correspondence of the undesired effects impressed upon the output of the amplifying arrangement.

13. A circuit comprising:
- an amplifying arrangement configured to operate in a compression region of the amplifying arrangement and/or in a linear region of the amplifying arrangement, the amplifying arrangement comprising a cascaded series-combination of amplifiers;
  
  a variable power supply operatively coupled to the amplifying arrangement and adapted to provide a dynamic supply power to the amplifying arrangement; and
  
  an optimizing circuital arrangement operatively coupled to the amplifying arrangement and configured to operatively affect a response of the amplifying arrangement depending on the region of operation of the amplifying arrangement thus impressing a desired effect upon a radio frequency (RF) output of the amplifying arrangement,wherein;
  
  i) at least one amplifier of the cascaded series-combination of amplifiers is configured to operate in a compression region of the amplifier and/or in a linear region of the amplifier and is adapted to receive a dynamic supply power from the variable power supply,ii) the RF input signal of the amplifying arrangement is operatively coupled to an input of a first amplifier of the cascaded series-combination of amplifiers and the RF output signal of the amplifying arrangement is in correspondence of an output of a last amplifier of the cascaded series-combination of amplifiers,iii) the optimizing circuital arrangement comprises one or more of;
  
  a) a feedback path operatively connected between the RF output of the amplifying arrangement and an RF input of the amplifying arrangement, the feedback path comprising a feedback network configured to operatively affect the response of the amplifying arrangement according to a variable value of a first input control signal,b) a first tunable matching network operatively coupled to the RF output of the amplifying arrangement such as to affect an output load to the amplifying arrangement in correspondence of an impedance value of the first tunable matching network, said first tunable matching network not included within a feedback path of the amplifying arrangement, wherein the impedance value of the first tunable matching network is adjustable based on a variable value of a second input control signal, andc) a second tunable matching network operatively coupled to an RF input of the amplifying arrangement such as to affect an input load to the amplifying arrangement in correspondence of an impedance value of the second tunable matching network, said second tunable matching network not included within the feedback path of the amplifying arrangement, wherein the second tunable matching network is adjustable based on a variable value of a third input control signal, andiv) the optimizing circuital arrangement further comprises one or more tunable matching networks, each operatively coupled in a series configuration between an output of an amplifier and an input of a next amplifier of the cascaded series-combination of amplifiers, such as each tunable matching network to affect an output load of the corresponding amplifier.

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Current Assignee
pSemi Corporation (Murata Manufacturing Co Limited)
Original Assignee
Peregrine Semiconductor Corporation (Murata Manufacturing Co Limited)
Inventors
Nobbe, Dan William, Dykstra, Jeffrey A., Olson, Chris, Cable, James S.
Primary Examiner(s)
Nguyen, Patricia T

Application Number

US13/830,070
Publication Number

US 20140184334A1
Time in Patent Office

1,013 Days
Field of Search

330/297, 330/296, 330/127
US Class Current

1/1
CPC Class Codes

H03D 1/18   of semiconductor devices

H03F 1/0205   in transistor amplifiers

H03F 1/0216   Continuous control

H03F 1/0222   by using a signal derived f...

H03F 1/0227   using supply converters

H03F 1/0244   Stepped control

H03F 1/025   by using a signal derived f...

H03F 1/0277   Selecting one or more ampli...

H03F 1/223   with MOSFET's

H03F 1/3247   using feedback acting on pr...

H03F 1/3282   Acting on the phase and the...

H03F 1/56   Modifications of input or o...

H03F 2200/102   A non-specified detector of...

H03F 2200/108   A coil being added in the d...

H03F 2200/129   there being a feedback over...

H03F 2200/15   the supply or bias voltage ...

H03F 2200/18   the bias of the gate of a F...

H03F 2200/213   A variable capacitor being ...

H03F 2200/222   A circuit being added at th...

H03F 2200/336   A I/Q, i.e. phase quadratur...

H03F 2200/387 : A circuit being added at th...

H03F 2200/408 : the output amplifying stage...

H03F 2200/411 : the output amplifying stage...

H03F 2200/451 : the amplifier being a radio...

H03F 2200/534 : Transformer coupled at the ...

H03F 2200/537 : A transformer being used as...

H03F 2200/541 : Transformer coupled at the ...

H03F 2200/546 : A tunable capacitance being...

H03F 2200/78 : A comparator being used in ...

H03F 2201/3233 : Adaptive predistortion usin...

H03F 2203/45112 : the biasing of the differen...

H03F 2203/45366 : the AAC comprising multiple...

H03F 2203/45544 : the IC comprising one or mo...

H03F 2203/45638 : the LC comprising one or mo...

H03F 2203/45731 : the LC comprising a transfo...

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

H03F 3/193 : with field-effect devices H...

H03F 3/195 : in integrated circuits

H03F 3/21 : with semiconductor devices ...

H03F 3/211 : using a combination of seve...

H03F 3/24 : of transmitter output stages

H03F 3/45179 : using MOSFET transistors as...

H03F 3/45183 : Long tailed pairs H03F3/452...

H03F 3/45188 : Non-folded cascode stages

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Optimization methods for amplifier with variable supply power

First Claim

2 Assignments

0 Petitions

Accused Products

Abstract

129 Citations

14 Claims

Specification

Solutions

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Optimization methods for amplifier with variable supply power

First Claim

2 Assignments

Subscription Required

Subscription Required

0 Petitions

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Accused Products

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Abstract

129 Citations

14 Claims

Specification

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Solutions

Use Cases

Quick Links