Ultra linear high speed operational amplifier output stage

Information

  • Patent Grant
  • 6794943
  • Patent Number
    6,794,943
  • Date Filed
    Monday, December 3, 2001
    23 years ago
  • Date Issued
    Tuesday, September 21, 2004
    20 years ago
Abstract
The present invention provides an ultra linear, high speed operational amplifier output stage (100). The advantages of the operational amplifier output stage disclosed is significantly higher linearity for the same supply current, or equivalent linearity using a lower supply current. The present invention achieves this using an pre-driver sub-stage (122) having a plurality of translinear loops so that there is no net signal loss to the final sub-stage (123). The output of the disclosed operational amplifier output stage takes the form; δIo≈βn*βp*δIin. When used with a localized feedback circuitry, bandwidth is extended.
Description




TECHNICAL FIELD OF THE INVENTION




This invention generally relates to electronic systems and in particular to operational amplifier output stages.




BACKGROUND OF THE INVENTION




Operational amplifiers are used in many electronic circuits to condition, manipulate and amplify signals. The operating characteristics of a particular operational amplifier are dependent upon its circuit topology. Generally, the operational amplifier consists of a number of stages, each containing internal sub-stages.




Crossover distortion is an important parameter op-amp performance and is largely correlated to bias current. It occurs, for example, when a signal being processed in a class AB amplifier transitions from the positive portion of a cycle to the negative portion of a cycle, and the reverse. This distortion is primarily generated in output transistors. To minimize crossover distortion, transistors within operational amplifier output stage circuits are sometimes biased slightly above cut-off. The class AB biasing arrangement consumes more power than if the transistors are biased in a class B configuration, but result in less cross-over distortion. The class AB biasing arrangement has more cross-over distortion than a class A biasing arrangement, but uses less current for proper operation.




SUMMARY OF THE INVENTION




The present invention achieves technical advantages as an ultra linear high speed operational amplifier output stage using a localized feedback system in which current gains are close to β


n





p


, where β


n


refers to the beta of either the pre-driver npn transistor, output driver npn transistor or an average of both, depending on the current signal and β


p


refers to the beta of either the pre-driver pnp transistor, output pnp transistor or an average of both. Where signal current is large and positive, load conduction is through the output npn transistor and pre-driver pnp transistor. Where signal current is large and negative, load conduction is through the pre-driver npn transistor and output pnp transistor. Where the signal is small, load conduction varies in tandem through the output npn transistor and pre-driver pnp transistor and the output pnp transistor and pre-driver npn transistor.




The output stage can be seen to comprise a pre-driver sub-stage and final sub-stage. The pre-driver sub-stage is further comprised of a first and a second pre-driver sub-stage circuit. In addition, the final sub-stage is further comprised of a first and a second final sub-stage circuit. The input to the present invention comprises a transconductance (“g


m


”) cell which, when a voltage is applied thereto, an error voltage appears across the input gm cell and an error current is produced at the output of the input g


m


cell. The error current (δI


in


) flows into the emitters of two pre-driver sub-stage transistors and flows out of their collectors into the bases of two other pre-driver transistors. Through this translinear loop, no net signal is lost. The gained up error currents then flow into the final sub-stage translinear loop, specifically, into the bases of two final sub-stage transistors. Effectively, in the small signal context, the first pre-driver sub-stage circuit amplifies a positive portion of the current signal for output to the first final sub-stage circuit while the second pre-driver sub-stage circuit amplifies a negative portion of the current signal for output to the second final sub-stage circuit. The first and second final sub-stages further amplify the positive portion and negative portion, respectively, of the current signal.




The first and second final sub-stage circuits are interconnected at an output terminal of the operational amplifier output stage such that the amplified positive portion of the signal and amplified negative portion of the signal are joined substantially in phase with improved crossover distortion characteristics.











BRIEF DESCRIPTION OF THE DRAWINGS




For a more complete understanding of the present invention, reference is made to the detailed description taken in conjunction with the following drawings:





FIG. 1

is a circuit diagram of a first conventional operational amplifier output stage;





FIG. 2

is a circuit diagram of a second conventional operational amplifier output stage;





FIG. 3

is a graph illustrating the linearity characteristics of the first conventional operational amplifier. This figure shows the first derivative (δV


o


/δV


i


) of the amplifier's DC transfer characteristic;





FIG. 4

is a graph illustrating the linearity characteristics of the second conventional operational amplifier. This figure shows the first derivative (δV


o


/δV


i


) of the amplifier's DC transfer characteristic;





FIG. 5

shows the single ended and differential linearity characteristics of the first conventional operational amplifier output stage using a discrete multi-tone (“DMT”) signal with missing tones;





FIG. 6

is a graph illustrating the typical linearity characteristics of the first conventional operational amplifier output stage in harmonic distortion form;





FIG. 7

is a circuit diagram of a first embodiment of the present invention with a g


m


cell input;





FIG. 8

is a circuit diagram of a second embodiment of the present invention with a g


m


cell input;





FIG. 9

is a graph illustrating the linearity characteristics of the first embodiment of the present invention. This figure shows the first derivative (δV


o


/δV


i


) of the amplifier's DC transfer characteristic;





FIG. 10

is a graph illustrating the linearity characteristics of the first embodiment of the present invention using a DMT signal with missing tones;





FIG. 11

is a graph illustrating the linearity characteristics of the first embodiment of the present invention in harmonic distortion form;





FIG. 12

illustrates the translinear loop formed by the first, second, third and fourth transistors;





FIG. 13

illustrates the translinear loop formed by the fifth, sixth, seventh and eight transistors;





FIG. 14

is a circuit diagram of the final sub-stage of the first embodiment of the present invention using type I biasing of the output transistors in a no-load configuration;





FIG. 15

is a circuit diagram of the final sub-stage of the first embodiment of the present invention using type I biasing of the output transistors with a load;





FIG. 16

is a graph illustrating the current gain of the final sub-stage of thee first embodiment of the present invention;





FIG. 17

is a circuit diagram of the final sub-stage of the second embodiment of the present invention using type II biasing of the output transistors in a no load configuration;





FIG. 18

is a circuit diagram of the final sub-stage of the second embodiment of the present invention using type II biasing of the output transistors with a signal applied to such final sub-stage's input;





FIG. 19

is a graph illustrating the DC current transfer characteristic of the final sub-stage of

FIG. 18

;





FIG. 20

is a graph illustrating the DC current transfer characteristic of the final sub-stage of

FIG. 15

;





FIG. 21

is a graph illustrating the linearity characteristic of the final sub-stage of FIG.


15


and FIG.


18


. This figure shows the first derivative (δI


o


/δI


i


) of the amplifiers' DC current transfer characteristics;





FIG. 22

is a circuit diagram of a conventional operational amplifier illustrating bias setup for the output transistors;





FIG. 23

is a graph illustrating the DC current transfer characteristics of circuit depicted in

FIG. 22

;





FIG. 24

is a circuit diagram of the first embodiment of the present invention with current feedback circuitry;





FIG. 25

is a circuit diagram of the first embodiment of the present invention with voltage feedback circuitry;





FIG. 26

is a circuit diagram of the second embodiment of the present invention with current feedback;





FIG. 27

is a circuit diagram of the second embodiment of the present invention with voltage feedback;





FIG. 28

is a graph comparing the linearity characteristics between the two conventional operational amplifiers and the first and second embodiments of the present invention. The figure shows the first derivative of the amplifiers' gain.





FIG. 29

is a circuit diagram of the first embodiment of the present invention with a compound darlington output stage using type I biasing;





FIG. 30

is a circuit diagram of the first embodiment of the present invention with a compound darlington output stage using type I biasing and a differential pair input g


m


cell;





FIG. 31

is a circuit diagram illustrating a current feedback stability loop;





FIG. 32

is a circuit diagram implementing conventional Miller compensation using a current feedback with the embodiments of the present invention;





FIG. 33

is a circuit diagram illustrating a voltage feedback stability loop;





FIG. 34

is a circuit diagram illustrating implementation of conventional Miller compensation using voltage feedback to achieve right-half-plane zero is (“RHPZ”) cancellation with the embodiments of the present invention; and





FIG. 35

is a circuit diagram illustrating a method for achieving low frequency precision in either of the first or second embodiments of the present invention.











DESCRIPTION OF CONVENTIONAL AMPLIFIER OUTPUT STAGES





FIG. 1

is a circuit diagram of a first conventional operational amplifier output stage.

FIG. 2

is a circuit diagram of a second conventional operational amplifier output stage.

FIG. 3

illustrates the linearity characteristics of such first conventional operational amplifier by showing the first derivative of the DC transfer characteristic.

FIG. 4

illustrates the linearity of such second conventional operational amplifier by showing the first derivative of the DC transfer characteristic.

FIG. 5

illustrates the single ended and differential linearity of such first conventional operational amplifier with a discrete multi tone (“DMT”) signal with missing tones. DMT signal is a broadband signal containing many sinusoids spaced at equal intervals. The missing tone performance looks for intermodulation products from the broadband DMT signal in at a frequency where there is no sinewave present in the DMT signal. DMT is a rigorous test of an amplifier's linearity.

FIG. 6

illustrates the typical linearity of such first and second conventional operational amplifiers in harmonic distortion form.




Detailed Description of the Present Invention




Two embodiments of the present invention are shown in

FIGS. 7 and 8

. As compared to the conventional operational amplifier output stages as disclosed in

FIGS. 1 and 2

, the disclosed embodiments of an operational amplifier output stage as shown in

FIGS. 7 and 8

, has higher linearity using the equivalent biasing current, or alternatively, the same linearity with lower biasing current. The operational amplifier output stage disclosed herein significantly reduces crossover distortion and reduces current use during operation. Further, because frequency response of a conventional amplifier output stage is sometimes reduced to lower the amount of biasing current needed during operation, the disclosed invention also has the advantage of extended bandwidth. The disclosed operational amplifier output stage comprises a pre-driver sub-stage utilizing translinear current loops and a final sub-stage. The final sub-stage of the operational amplifier output stage disclosed herein comprises a complementary set of compound darlington transistors enclosed in a localized feedback system.




As used herein, translinearity refers to the characteristics of non-linear circuits whose operation is based on the exponential current-voltage relationship of the bipolar junction transistor; β refers to the ratio of DC collector current to DC base current in a bipolar junction transistor or current gain from base to collector; α represents the fraction of signal current going into one half of the pre-driver sub-stage, λ refers to the fraction of signal current going into the other half of the pre-driver sub-stage, and A refers to the emitter area of the BJT in consideration.





FIG. 7

is a circuit diagram of the first embodiment of an operational amplifier output stage having reduced supply current and high linearity constructed according to the teachings of the present invention. The circuit


100


includes an input g


m


cell


121


, pre-driver sub-stage comprised of eight pre-driver sub-stage transistors


101


,


102


,


103


,


104


,


105


,


106


,


107


and


108


, a final sub-stage comprising four final sub-stage transistors


109


,


110


,


111


and


112


, and four current sources


131


,


132


,


133


and


134


. The input g


m


cell


121


is configured to accept an input voltage signal, produce an error voltage across its input, and produce an output error current (δI


in


).




As shown therein, a first voltage supply rail


41


is coupled to a first node


51


, a second voltage supply rail


42


is coupled to a fifth node


55


.




The first pre-driver sub-stage circuit consists of four transistors


101


,


102


,


103


and


104


. In the first pre-driver sub-stage circuit, the emitter of the first transistor


101


is coupled to the first voltage supply rail


41


at the first node


51


, and the base of the first transistor


101


is coupled to a second node


52


. The emitter of the second transistor


102


is also coupled to the second node


52


; and its base is coupled to a third node


53


. The base and collector of the third transistor


103


are also coupled to the third node


53


. The collector and base of the fourth transistor


104


are each coupled to a fourth node


54


. The emitter of the fourth transistor


104


is coupled to the voltage supply rail


41


at the first node


51


.




The second pre-driver sub-stage circuit comprises four transistors


105


,


106


,


107


and


108


. The second voltage supply rail


42


is coupled to the fifth node


55


. The emitter of the fifth transistor


105


is coupled to the second voltage supply rail


42


at the fifth node


55


and its base is coupled to a the sixth node


56


. The emitter of the sixth transistor


106


is coupled to the sixth node


56


and its base is coupled to a seventh node


57


. The collector of the sixth transistor


106


is coupled to the second node


52


. The base and collector of the seventh transistor


107


are coupled to a seventh node


57


and its emitter is coupled to an eighth node


58


. The collector and base of the eighth transistor


108


are coupled to the eighth node


58


, and the emitter of the eighth transistor


108


is coupled to the second voltage supply rail


42


at the fifth node


55


.




The collector of the second transistor


102


and the emitter of the sixth transistor


106


are coupled to a common sixth node


56


. The emitter of the second transistor


102


and the emitter of the sixth transistor


106


are coupled to a common second node


52


. The cross connection advantageously results in no error current being lost in the translinear loops.




A first current source


131


is coupled to the first voltage supply rail


41


at the first node


51


and at the second node


52


. A second current source


132


is coupled to the first voltage supply rail


41


at the first node


51


and at the seventh node


57


. A third current source


133


is coupled to the second voltage supply rail


42


at the fifth node


55


and at the third node


53


. A fourth current source


134


is coupled to the voltage supply rail


42


at the fifth node


55


and at the sixth node


56


.




The final sub-stage


123


comprises a complementary pair of darlington transistors. The first set of darlington transistors is comprised of the ninth and tenth transistors


109


and


110


. The emitter of the ninth transistor


109


is coupled to the collector of the first transistor


101


at a ninth node


59


. The base and collector of the ninth transistor


109


are coupled at a tenth node


60


. The base of the tenth transistor


110


is coupled to the ninth node


59


, and the collector of the tenth transistor


110


is coupled to the first voltage supply rail


41


at the first node


51


.




The second set of darlington transistors is comprised of the eleventh and twelfth transistors


111


and


112


. The emitter of the eleventh transistor


111


is coupled to the collector of the fifth transistor


105


at an eleventh node


61


. The base and collector of the eleventh transistor


111


are coupled to the base and collector of the ninth transistor


109


at the tenth node


60


. The base of the twelfth transistor


112


is coupled to the eleventh node


61


, and the collector of the twelfth transistor


112


is coupled to the second voltage supply rail


42


at the fifth node


55


. The twelfth node


62


couples the emitter of the tenth transistor


110


to the emitter of the twelfth transistor


112


. An output terminal


91


is coupled to the twelfth node


62


. The twelfth node


62


also interconnects the output terminal


91


to the g


m


cell input


121


. The configuration of the ninth transistor


109


and eleventh transistor


111


of the first embodiment of the present invention is also referred to as type I biasing.




A second embodiment of the present invention is disclosed in FIG.


8


. The second embodiment is also referred to as type II biasing of the output transistors. In this second embodiment, the collectors of the ninth transistor


109


and the eleventh transistor


111


are not coupled at the tenth node


60


. The collector of the ninth transistor


109


is coupled to the second voltage supply rail V


ee




42


at the fifth node


55


and the collector of the eleventh transistor


111


is coupled to the first voltage supply rail V


cc




41


at the first node


51


. In this case the current gain from the collectors of


101


or


105


to the output node


91


is the average of β


n


and β


p


. This arrangement minimizes crossover distortion in the output signal. As used herein, β


n


refers to the beta of transistor


110


and β


p


refers to the beta of transistor


101


, where α=1 and λ=1; or β


n


refers to the beta of transistor


105


and β


p


refers to the beta of transistor


112


, where α=0 and λ=0, or, in the small signal context, where α=0.5 and λ=0.5, β


n


refers to the average of the beta of transistor


110


and transistor


105


and β


p


refers to the beta of the average of transistor


101


and transistor


112


, the relative contribution of each such pnp transistor and npn transistor to B


n


and B


p


varying proportionally with the variation in α and λ.





FIGS. 9

,


10


and


11


illustrate different performance aspects of the present invention. Specifically,

FIG. 9

shows the linearity characteristics of the first embodiment of the present invention, specifically the first derivative (δV


o


/δV


i


) of the amplifier's DC transfer characteristic.

FIG. 10

shows the linearity characteristics of the first embodiment of the present invention using a DMT signal with missing tones.

FIG. 11

shows the linearity characteristics of the first embodiment of the present invention in harmonic distortion form.




As shown in

FIG. 12

, in the first embodiment of the present invention a translinear loop is formed by the third transistor


103


, fourth transistor


104


, second transistor


102


and first transistor


101


. In operation, two sets of current flow into this first translinear loop which sets up a quiescent current through a branch


170


connected at the collector of the first transistor


101


. In addition, as shown in

FIG. 13

, a translinear loop is formed by the seventh transistor


107


, the eighth transistor


108


, the sixth transistor


106


and the fifth transistor


105


. Two sets of current flow in this second translinear loop which sets up a quiescent current through a branch


171


connected at a collector of the fifth transistor


105


. These two quiescent currents establish the bias currents for the respective tenth transistor


110


and for the twelfth transistor


112


by means of translinear principles in the loop formed by the ninth transistor


109


, eleventh transistor


111


, tenth transistor


110


and twelfth transistor


112


.




When an input voltage is applied to the input g


m


cell


121


, an error voltage appears across the output of the input g


m


cell


121


and an error current is produced. Advantageously, the cross-connection of the collector of the second transistor


102


to the emitter of the sixth transistor


106


, and the collector of the sixth transistor


106


to the emitter of the second transistor


102


ensures that whatever proportion of the error current flowing into the emitters of the second transistor


102


and sixth transistor


106


also flows back out through the collectors of the second transistor


102


and the sixth transistor


106


into the bases of the first transistor


101


and the fifth transistor


105


. Advantageously, there is no net signal loss in the pre-driver sub-stage translinear loops.




The error currents into the bases of the first transistor


101


and the fifth transistor


105


, are thus gained up by the pre-driver sub-stage contribution of β


p


and β


n


. These error currents flow into the translinear loop formed by the ninth transistor


109


, eleventh transistor


111


, tenth transistor


110


and twelfth transistor


112


. These amplified error currents can only flow into the bases of the tenth transistor


110


and twelfth transistor


112


, where they are amplified by the final sub-stage contribution of β


n


and β


p


respectively. Thus, irrespective of whether the error current flows through the top or the bottom route through the circuit it appears at the output terminal


91


amplified by approximately β


n


multiplied by β


p


, where it develops a correction voltage across the load resistor to move the output to a point of minimum error of the feedback into the input g


m


cell


121


.




Output Transistor Biasing





FIG. 14

is a circuit diagram of the final sub-stage


123


of the first embodiment of the operational amplifier output stage in a no load configuration.

FIG. 14

illustrates type I biasing of the output transistors as follows: Current is flowing into the collector of the tenth transistor


110


, referred to as I


Q110C


, and current is flowing out of the collector of the twelfth transistor


112


, referred to as I


Q112C


. The emitter area of the ninth transistor


109


is referred to as A


Q109


and the emitter area of the eleventh transistor


111


is referred to as A


Q111


. The emitter area of the tenth transistor


110


is referred to as A


Q110


and the emitter area the twelfth transistor


112


is referred to as A


Q112


. Two current sources I


135


and I


136


are shown thereon:







I
135

=


I
+



δ






I
sig


2






and






I
136



=

I
-


δ






I
sig


2







Therefore


:







I
135
2



A
Q109

*

A
Q111



=



I
Q110C

*

I
Q112C




A
Q112

*

A
Q110









for






β
n






and






β
p


>>

1





and





V






A
n






and





V






A
p


>>
1

,






 I


Q110C


=I


Q112C


=I


C


.




Therefore,









I
135
2



A
Q109

*

A
Q111



=


I
C
2



A
Q112

*

A
Q110




;










and further







I
C

=


I
135

·




A
Q110

*

A
Q112




A
Q109

*

A
Q111
















FIG. 15

is a circuit diagram of the final sub-stage


123


of the first embodiment of the present invention with a load


43


. Type I biasing of the output transistors is thus described as follows: When a load


43


is connected to the output terminal


91


and the following do not hold:






β


n


and β


p


>>1, or








VA


n


and VA


p


>>1, or






there is an imbalance between current I


Q110C


and I


Q112C


.




Since current I


Q110C


is not equal to I


Q112C


, an error current flows in the load


43


thus developing an offset voltage V


error


across the load


43


.




When the difference in current in the final sub-stage transistors


110


and


112


, are taken care of by a localized feedback system, the characteristics of the final sub-stage can be seen as follows: The signal current changes the bias currents by increasing the current through the top circuit and decreasing the current through the bottom circuit. In the limiting case for large current through the top circuit and miniscule current through the bottom circuit, and α is equal to one (1), the translinear loop cuts off the twelfth transistor


112


and all of the signal current flows into the base of the tenth transistor


110


where it appears in the load


43


as follows:






β


n


*(δI


sig


).






Conversely, for large signal current through the bottom circuit and miniscule current at the top circuit, and where α is equal to 0, the translinear loop is again cut off and all of the signal current flows into the base of the twelfth transistor


112


where it appears in the load


43


as follows:






β


p


*(δI


sig


).






For small signal currents, where α is close to half (0.5), the translinear loop is active, that is a quiescent current is flowing through both the tenth transistor


110


and the twelfth transistor


112


, the signal current splits with α and (1−α) multiplied by δI


sig


flowing into the base of the twelfth transistor


112


. Thus the current gain from input to output is as follows:






α*β


n


+(1−α)*β


p


,






for all cases of α such that α is equal to or greater than zero and equal to or less than 1.




As shown in the graph of

FIG. 16

, the gain will transition from β


p


to β


n


through the translinear region.





FIG. 17

is a circuit diagram of the final sub-stage of the second embodiment of an operational amplifier in a no load configuration.

FIG. 17

illustrates type II biasing of the output transistors as follows:










β
n

*

β
p

*

i
b
2




A
Q109

*

A
Q111



=



I
Q110C

*

I
Q112C




A
Q112

-

A
Q110




,
and







β
n

*

β
p

*

i
b
2




A
Q109

*

A
Q111



=




(



β
n

*
I

-


β
p

*

β
n

*

i
b



)



(


β





I

-


β
n

*

β
P

*

i
b



)




A
Q112

-

A
Q110



.











The current through branch


70


is: β


p


*i


b


.




The current through branch


75


is: I−β


p


*i


b


.




The current through branch


72


is: β


n


*i


b


.




The current through branch


74


is: I−β


n


*i


b


.




The current through branch


76


is: β


n


*I−β


p





n


*i


b


.




The current through branch


77


is: β


p


*I−β


n





p


*i


b


.




As can be seen, an offset current (β


n


−β


p


)*I will develop an offset voltage in a load, and would self correct in the localized feedback circuit.




Referring to

FIG. 18

, which illustrates type II biasing of the output transistors:




The current through branch


75


is: I+δI−β


p


i


b


.




The current through branch


74


is: I+δI−β


n


i


b


.




The current is through branch


76


is: (β


n


*I)+(β


n


*δI)−(β


n





p


*i


b


).




The current through branch


77


is: (β


p


*I)−(β


p


*δI)−(β


n





p


*δI).




Thus, the output current through branch


78


is: i


o


=I*(β


n


−β


p


)+(β


n





p


)*δI.




This result theoretically indicates no crossover distortion in the output, albeit with an offset.





FIGS. 19

,


20


and


21


illustrate the current drive relationships of the type I and type II biasing schemes.




Pre-Driver Biasing





FIG. 22

is a circuit diagram illustrating one technique of bias current generation for a rail to rail output stage in a conventional operational amplifier. The main disadvantage of this configuration is that current gain from the input to the output is only a single β. Also this type of stage will have a large output impedance making compensation more difficult given variation in a load's impedance. In the first and second embodiments of the present invention, translinear principles are used to establish the bias currents in the pre-driver stage.




Referring back to

FIGS. 7 and 8

, if there is a slight mismatch in the currents through the second transistor


102


and sixth transistor


106


due to an Early voltage mismatch between these two devices, a cascode on the second transistor


102


and the sixth transistor


106


will remedy this effect.




Also referring to

FIGS. 7 and 8

, assume that feedback introduces a correction term into the circuit to establish equality of collector currents in the first transistor


101


and the fifth transistor


105


, then:






I


Q101C


=I


Q105C


=I


Qpre








Thus, from translinear principles:








1.







I
132
2



A
Q107

*

A
Q108




=



I
Q106C


A
Q106


*


I
Qpre


A
Qpre




;






2.







I
132
2



A
Q103

*

A
Q104




=



I
Q102C


A
Q102


*


I
Qpre


A
Qpre




;







3.






I
Q106C


+

I
Q102C


=

I
131


;






4.







I
132
2



A
Q107

*

A
Q108




=




A
Q101


I
QpreC


*

A
Q106


=

I
Q106C



;





(

derived





from





equation











1

)

;






5.







I
132
2



A
Q103

*

A
Q104




=




I
Q105


A
QpreC


*

A
Q102


=

I
Q102C



;





(

derived





from





equation





2

)

;







6.







I
132
2



A
Q107

*

A
Q108



*


I
Q105


A
QpreC


*

A
Q106


+



I
132
2



A
Q103

*

A
Q104



*


A
Q101


I


Q
pre


C



*

A
Q102



=

I
131


;




(


derived





from





equaions





3

,

4





and





5


)




Thus
,






I


Q
pre


C


=



I
132
2


I
131





(




A
Q105

*

A
Q106




A
Q107

*

A
Q108



+



A
Q101

*

A
Q102




A
Q103

*

A
Q104




)

.













Referring to the operational amplifier output stage


100


shown in

FIG. 7

, the change in current in the first transistor


101


and the fifth transistor


105


in response to a change in input current is computed as follows: The input current change takes the form of an equal but opposite change in I


X


and I


Y


given that the difference current between I


X


and I


Y


(i.e. δI) has to be divided between the bases of the first transistor


101


and the fifth transistor


105


. Therefore,








I




o




=I




Y




−α*δI*β




p




−I




Y


−(1−α)δ


I−β




n








 δ


I




o




=−α*δI*β




p


−(1−α)*δ


I*β




n


;






δ


I




o




=−δI


(α*β


p


+(1−α)−β


n


).






Where α is greater than zero and less than one, the value of α indicates the proportion of δI delivered into the bases of each of the pre-driver transistors, first transistor


101


and fifth transistor


105


.




Where α is approximately zero, I


X


has significantly increased and I


Y


has significantly decreased by equal and opposite quantities. The base-emitter voltage is large in the second transistor


102


and small in the sixth transistor


106


. The second transistor


102


cuts off and all of the difference current between I


X


and I


Y


(i.e. δI) flows into the base of the fifth transistor


105


. This gives a current gain in the circuit of β


n


.




Where α is approximately equal to one, the opposite of where α is approximately equal to zero occurs. Where I


X


significantly decreases, I


Y


significantly increases causing all difference current, δI, to flow into base of the first transistor


101


, resulting in a current gain of β


p


.




Where α is greater than zero but less than one, the pre-driver sub-stage


122


is in translinear mode. The difference current is split in varying proportion into the first transistor


101


and the fifth transistor


105


. Thus, δI


o


/δI=α*β


p


+(1−α)*β


n


.




Referring to

FIG. 23

, the DC response of the pre-driver sub-stage


122


of the present invention is shown.




In connection with the coupling of the pre-driver sub-stage


122


to the final sub-stage


123


, the biasing scheme of the pre-drivers and the biasing scheme of the final drivers of the present invention have the advantageous property of not absorbing any signal current. All of the signal current is delivered directly into the bases of the transistors, and none is lost in translinear loops.




The current gain from the input to the output has approximately the form:






δ


I




o


≈β


n





p




*∂I




in


.






Feedback Analysis




When feedback is locally applied by means of some localized feedback circuit, the errors are corrected within a very tight loop which will respond much more quickly than relying on the amplifier overall feedback loop.




Four (4) possibilities are presented: (i) current feedback, transitional β output (ii) current feedback, constant β output (iii) voltage feedback, transitional β output, and (iv) voltage feedback, constant β output.





FIG. 24

is a circuit diagram of a first embodiment of the present invention with a current feedback circuitry.





FIG. 25

is a circuit diagram of the first embodiment of the present invention with a voltage feedback circuitry.




When the input g


m


cell


121


takes the form of a complementary differential pair, the inherent RHPZ appearing when the pre-driver sub-stage is Miller compensated vanishes as the feed forward term contributing to the RHPZ is pulled back out by the differential pair.





FIG. 28

illustrates the output in a closed loop configuration with [greater than unity gain] driving a heavy load over a wide voltage range. In all cases the worst ease non-linearity is approximately plus/minus 1 part in 1000. For the current feedback, constant β output, cross-over distortion is virtually eliminated.





FIG. 29

is a circuit diagram of the first embodiment of the present invention with a compound darlington output stage using type I biasing. A generalized evaluation of this circuit is as follows:




Referring to current through branches


150


,


152


,


154


,


156


,


158


,


160


,


172


and


174


in FIG.


29


:




Current through branch


150


is I


LTP


; where I


LTP


refers to the current through current source


131


.




Current through branch


152


is: −α·δI.




Current through branch


154


is:








I
LTP

2

+

δ







I


(


1
2

-
α

)


.












Current through branch


156


is:








I
LTP

2

-



δ





I

2

.











Current through branch


158


is:








I
LTP

2

+



δ





I

2

.











Current through branch


160


is: I


bias p


−β


Q101


·α·δI.




Current through branch


162


is approximately equal to:







I
biasp

-


I
LTP

2

-

δ






I
·

β
Q101

·

α
.













Current through


172


is: −λ·δI(β


Q101


·α+β


Q105


(1−α)).




Current through


174


is: −λ·δI·(β


Q101


·α+β


Q105


(1−α))+I


bais out


.




Referring to current through branches


151


,


153


,


155


,


157


,


159


,


161


,


163


,


173


and


175


:




Current through branch


151


is I


LTP


; where I


LTP


refers to the current through current source


134


which is the same as the current through current source


131


.




Current through branch


153


is: (1−α) δI.




Current through branch


155


is:








I
LTP

2

+

δ







I


(


1
2

-
α

)


.












Current through branch


157


is:








I
LTP

2

+



δ





I

2

.











Current through branch


159


is:








I
LTP

2

-



δ





I

2

.











Current through branch


161


is: I


bias p





Q105


·(1−α)δI.




Current through branch


163


is:







I
biasp

-


I
LTP

2

+



β
Q105

·

(

1
-
α

)



δ






I
.












Current through branch


173


is: (1−λ)·δI(β


Q101


·α+β


Q105


(1−α).




Current through


175


is: (1−λ)−δI(β


Q101


·α+β


Q105


(1−α)+I


bias out


.




Therefore:








I




out




=−λ·δI·β




Q110


·(β


Q101


·α+β


Q105


(1−α))−(1−λ)·


δI·β




Q112





Q101


·α+β


Q105


(1−α)).






In a first case where I


out


is large and positive, and load conduction is through transistor


110


and transistor


101


, where α=1, λ=1, then:








I




out




=−δI·β




Q110


·β


Q101








In a second case where I


out


is large and negative, and load conduction is through transistor


112


and transistor


105


, where α=0, λ=0, then:








I




out




=−δI·β




Q112


·β


Q105








In a third case where I


out


is very small through the cross-over point, and load conduction is through transistor


110


and transistor


112


, where α≈0.5, λ≈0.5, then:







I
out

=


-
δ







I


(



β
Q101

+

β
Q105


2

)




(



β
Q110

+

β
Q112


2

)












Thus, for β


Q112





Q101





p






and β


Q110





Q105





n










I
out

=


-
δ








I


(



β
p

+

β
n


2

)


2













FIG. 30

is a circuit diagram of the first embodiment of the present invention with a compound darlington output stage using type I biasing and a differential pair input g


m


cell. A specific evaluation of this circuit is as follows:




Referring to the current through branches


140


,


142


,


152


,


160


,


172


and


174


in FIG.


30


:




The current through branch


140


is:






I


131


+δI(½−α)






The current through branch


142


is:






-


δ





I

2











The current through branches


152


,


160


,


172


and


174


are the same as that in the equivalent numbered branches in FIG.


29


.




Referring to the current through branches


141


,


143


,


153


,


161


,


173


, and


175


in FIG.


30


:




The current through branch


141


is:






I


134


+δI(½−α)






The current through branch


143


is:







δ





I

2










The current through branches


153


,


161


,


173


and


175


are the same as that in the equivalent numbered branches in FIG.


29


.




Therefore:








I




out




=−λ·δI·β




Q110


·(β


Q101


·α+β


Q105


(1−α))−(1−λ)·δ


I·β




Q112





Q101


·α+β


Q105


(1−α))






Referring to

FIG. 30

, and as noted in

FIG. 29

, in a first case, where I


out


is large and positive, and load conduction is through transistor


110


and transistor


101


, where α=1, λ=1, then:








I




out




=−δI·β




Q110


·β


Q101








In a second case where I


out


is large and negative, and load conduction is through transistor


112


and transistor


105


, where α=0, λ=0, then:








I




out




=−δI·β




Q112


·β


Q105








In a third case, where case I


out


is very small through the cross-over point, and load conduction is through transistor


110


and transistor


112


, where α≈0.5, λ≈0.5, then:







I
out

=


-
δ







I


(



β
Q101

+

β
Q105


2

)




(



β
Q110

+

β
Q112


2

)












Thus, for β


Q112





Q101





p






and β


Q110





Q105





n










I
out

=


-
δ








I
(



β
p

+

β
n


2

)

2












where 0<α<1;




and 0<λ<1.




I


biasp


and I


biasout


are established using translinear principles.




Compensation





FIGS. 31

,


32


,


33


and


34


show the various types of compensation techniques that can be used with the present invention.

FIG. 31

is a half circuit showing the current feedback case with small signal AC. The circuit is a 2 voltage gain stage amplifier with voltage gain being developed at nodes


63


and


64


. The circuit lends itself to classic Miller compensation as shown in FIG.


31


.




Referring to

FIG. 32

, the resistor


81


eliminates the right half plane through the compensation capacitor


85


. At the quiescent condition, the value is the reciprocal of the transconductance of the first transistor


101


.





FIG. 33

illustrates the voltage feedback case. Referring to the circuit in

FIG. 33

, there are two (2) loops to be compensated, inner loop


2


and outer loop


1


. As can be seen in

FIG. 32

, similar to the current feedback implementation, the system is a 2 voltage gain stage amplifier with voltage gain at nodes


63


and


64


. This circuit can also be Miller compensated. There is no concern with RHPZ because the differential transistor


113


draws the feed forward signal out.




Implementation




It is noted that the voltage feedback implementation can only be used for gain greater than 1. Further, the current feedback implementation can be used for arbitrary gain. All four implementations can be used as a stand alone amplifier configuration.





FIG. 35

illustrates how gain from the present invention can be preserved where additional lower frequency precision is required.




The advantages of the present invention over conventional operational amplifier output stages is significantly higher linearity for the same supply current or linearity equal to the conventional operational amplifiers.




The current gain obtained in the error correction loop of each of the first and second conventional operational amplifiers is only a single current gain whereas the current gain of the present invention is up to β


2


. Further, the DC non-linearity of conventional amplifiers is approximately 2 parts per 1000, a factor of 25 worse than the present invention. Reduced current draw is one of the advantages afforded by the design of each of the present invention.




The numerous innovative teachings of the present application are described with particular reference to the disclosed embodiments. However, it should be understood that these embodiments provide only two examples of the many advantageous uses and innovative teachings herein. Various alterations, modifications and substitutions can be made to the disclosed invention without departing in any way from the spirit and scope of the invention, as defined in the claims that follow. For example, although the embodiments have been presented herein with reference to particular transistor types, voltage and current polarities and methods of coupling, the present inventive structures and characteristics are not necessarily limited to particular transistor types, polarities or methods of coupling, as used herein. It should be understood the embodiment used hereinabove can easily be implemented using many diverse transistor types, polarities and methods of coupling so long as the combinations achieve an ultra linear, high speed operational amplifier output stage with reduced current draw and extended bandwidth.



Claims
  • 1. An operational amplifier output stage, comprising:a pre-driver sub-stage and a final sub-stage, the pre-driver sub-stage having a plurality of transistors being biased by a plurality of current sources, the pre-driver sub-stage being adapted to accept a current signal (δIin) from an input transconductance gm cell; the pre-driver stage being further adapted to provide biasing to a plurality of transistors in the final sub-stage; and the pre-driver sub-stage being coupled to the final sub-stage so as to provide current gain from input to output of δIo≈βn*βp*βIin.
  • 2. The operational amplifier output stage recited in claim 1, wherein the plurality of transistors in the final sub-stage comprises 4 transistors arranged as a complementary pair of differential transistors.
  • 3. The operational amplifier output stage recited in claim 1, wherein the pre-driver sub-stage comprises two circuits, the first pre-driver sub-stage circuit being adapted to condition a positive portion of an inputted signal for transfer to a first final sub-stage circuit of the final sub-stage, and the second pre-driver sub-stage circuit being adapted to condition a negative portion of an inputted signal for transfer to a second final sub-stage circuit of the final sub-stage;the first pre-driver sub-stage circuit being coupled to the first final sub-stage circuit operable to amplify the positive portion of a signal in tandem; and the second pre-driver sub-stage circuit being coupled to the second final sub-stage circuit operable to amplify the negative portion of a signal in tandem.
  • 4. The operational amplifier output stage recited in claim 3, wherein the first final sub-stage circuit and the second final sub-stage circuit are interconnected at an output terminal node such that the conditioned and amplified positive portion of the signal and the conditioned and amplified negative portion of the signal are joined in phase with minimal crossover distortion the output signal (δIo) having the form δIo≈βn*βp*δIin.
  • 5. An operational amplifier output stage, comprising:a first voltage supply rail Vcc connected to a first node; two connection terminals to an input stage, a first terminal connected to a second node for receiving a positive portion of an input signal and a second terminal connected to a sixth node for receiving a negative portion of an input signal; a first pre-driver sub-stage circuit coupled at the second node, the first pre-driver sub-stage circuit further comprising: a first transistor having its emitter coupled to the first voltage supply rail Vcc at the first node, and its base coupled at the second node; a second transistor having its emitter coupled to the second node and its base coupled to a third node; a third transistor having its base and collector coupled to the third node; a fourth transistor having its collector and base being coupled to a fourth node, and its emitter coupled to the first voltage supply rail Vcc at the first node; a second voltage supply rail Vee coupled to a fifth node; a second pre-driver sub-stage circuit coupled to the sixth node, the second pre-driver sub-stage circuit further comprising: a fifth transistor having its emitter coupled to the second voltage supply rail Vee at the fifth node, and its base coupled to the sixth node; a sixth transistor having its emitter coupled to the sixth node, its base coupled to a seventh node, and its collector coupled to the second node; a seventh transistor having its base and collector coupled to a seventh node; and its emitter coupled to an eighth node; an eighth transistor having its collector and base being coupled to the eighth node, and its emitter coupled to the second voltage supply rail Vee at the fifth node; a cross connection between the second transistor's collector and the sixth transistor's emitter at the sixth node, and the second transistor's emitter and the sixth transistor's collector at the second node, the cross connection resulting in a proportion of any error current flowing into the second transistor's emitter and sixth transistors emitter to flow out through the second transistor's collector and the sixth transistor's collector into the base of the first transistor and the base of the fifth transistor; a first current source coupled between the first voltage supply rail Vcc at the first node and the second node; a second current source coupled between the first voltage supply rail Vcc at the first node and the seventh node; a third current source coupled between the second voltage supply rail Vee at the fifth node and at the third node; a fourth current source coupled between the second voltage supply rail Vee at the fifth node and the sixth node; a final sub-stage, comprising: a first final sub-stage circuit further conditioning the positive portion of the current signal provided by the first pre-driver sub-stage circuit, the first final sub-stage circuit comprising: a ninth transistor having its emitter coupled to the first transistor's collector at a ninth node, and its base and collector coupled to a tenth node; a tenth transistor having its base coupled to the ninth node, and its collector coupled to the first voltage supply Vcc rail at the first node; a second final sub-stage circuit further conditioning the negative portion of the current signal, provided by the second pre-driver sub-stage circuit, the second final sub-stage circuit comprising: an eleventh transistor having its emitter coupled to the fifth transistor's collector at an eleventh node, its base and collector coupled to the ninth transistor's base and collector at the tenth node; a twelfth transistor having its base coupled to the eleventh node, and its collector coupled to the second voltage supply rail Vee at the fifth node; a twelfth node interconnecting the tenth transistors emitter with the twelfth transistor's emitter; and an output terminal coupled to the twelfth node.
  • 6. The operational amplifier output stage recited in claim 5 wherein the first, second, third, fourth, ninth and twelfth transistors are pnp transistors and the fifth, sixth, seventh, eight, tenth and eleventh transistors are npn transistors.
  • 7. The operational amplifier output stage recited in claim 5, including a localized feedback circuitry enclosed within the operational amplifier output stage.
  • 8. The operational amplifier output stage recited in claim 7, wherein the localized feedback circuitry utilizes current feedback principles operable to substantially eliminate cross-over distortion.
  • 9. The operational output stage recited in claim 7, wherein the localized feedback system utilizes voltage feedback principles, operable to provide unity gain.
  • 10. An operational amplifier output stage, comprising:a first voltage supply rail Vcc connected to a first node; two connection terminals to an input stage, a first terminal connected to a second node for receiving a positive portion of a current signal and a second terminal connected to a sixth node for receiving a negative portion of a current input signal; a first pre-driver sub-stage circuit coupled at the second node, the first pre-driver sub-stage circuit further comprising: a first transistor having its emitter coupled to the first voltage supply rail Vcc at the first node, and its base coupled at the second node; a second transistor having its emitter coupled to the second node and its base coupled to a third node; a third transistor having its base and collector coupled to the third node; a fourth transistor having its collector and base being coupled to a fourth node, and its emitter coupled to the first voltage supply rail Vcc at the first node; a second voltage supply rail Vee coupled to a fifth node; a second pre-driver sub-stage circuit coupled to the sixth node, the second pre-driver sub-stage circuit further comprising: a fifth transistor having its emitter coupled to the second voltage supply rail Vee at the fifth node, and its base coupled to the sixth node; a sixth transistor having its emitter coupled to the sixth node, its base coupled to a seventh node, and its collector coupled to the second node; a seventh transistor having its base and collector coupled to a seventh node; and its emitter coupled to an eighth node; an eighth transistor having its collector and base being coupled to the eighth node, and its emitter coupled to the second voltage supply rail Vee at the fifth node; a cross connection between the second transistor's collector and the sixth transistor's emitter at the second node, and the second transistor's emitter and the sixth transistor's collector at the second node, the cross connection resulting in a proportion of any error current flowing into the second transistor's emitter and sixth transistor's emitter to flow out through the second transistor's collector and the sixth transistors collector into the base of the first transistor and the base of the fifth transistor; a first current source coupled between the first voltage supply rail Vcc at the first node and the second node; a second current source coupled between the first voltage supply rail Vcc at the first node and the seventh node; a third current source coupled between the second voltage supply rail Vee at the fifth node and at the third node; a fourth current source coupled between the second voltage supply rail Vee at the fifth node and the sixth node; a final sub-stage, comprising: a first final sub-stage circuit further conditioning the positive portion of the current signal provided by the first pre-driver sub-stage circuit, the first final sub-stage circuit comprising: a ninth transistor having its emitter coupled to the first transistor's collector at a ninth node, and its base coupled to a tenth node and its collector coupled to the second voltage supply rail Vee at the fifth node; a tenth transistor having its base coupled to the ninth node, and its collector coupled to the first voltage supply Vcc rail at the first node; a second final sub-stage circuit further conditioning the negative portion of the current signal, provided by the second pre-driver sub-stage circuit, the second final sub-stage circuit comprising: an eleventh transistor having its emitter coupled to the fifth transistor's collector at an eleventh node, its base coupled to the ninth transistor's base and collector at the tenth node and its collector coupled to the first voltage supply rail Vcc at the first node; a twelfth transistor having its base coupled to the eleventh node, and its collector coupled to the second voltage supply rail Vee at the fifth node; a twelfth node interconnecting the tenth transistor's emitter with the twelfth transistor's emitter; and an output terminal coupled to the twelfth node.
  • 11. The operational amplifier output stage recited in claim 10, including a localized feedback circuitry enclosed within the operational amplifier output stage.
  • 12. The operational amplifier output stage recited in claim 11, wherein the localized feedback circuitry utilizes current feedback principles.
  • 13. The operational amplifier output stage in claim 11, wherein the localized feedback circuitry utilizes voltage feedback principles.
  • 14. The operational amplifier output stage recited in claim 10, wherein the first, second, third, fourth, ninth and twelfth transistors are pnp transistors, and the fifth, sixth, seventh, eighth, tenth and eleventh transistors are npn transistors.
US Referenced Citations (5)
Number Name Date Kind
5789982 Uscategui et al. Aug 1998 A
5825228 Gross Oct 1998 A
5907262 Graeme et al. May 1999 A
6433637 Sauer Aug 2002 B1
6566949 Park May 2003 B1