GB1565153A

GB1565153A – Distortion corrector for wide-band transistorized amplification stages
– Google Patents

GB1565153A – Distortion corrector for wide-band transistorized amplification stages
– Google Patents
Distortion corrector for wide-band transistorized amplification stages

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Publication number
GB1565153A

GB1565153A
GB47764/77A
GB4776477A
GB1565153A
GB 1565153 A
GB1565153 A
GB 1565153A
GB 47764/77 A
GB47764/77 A
GB 47764/77A
GB 4776477 A
GB4776477 A
GB 4776477A
GB 1565153 A
GB1565153 A
GB 1565153A
Authority
GB
United Kingdom
Prior art keywords
circuit
transistor
emitter
varactor
corrector
Prior art date
1976-11-19
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Expired

Application number
GB47764/77A
Inventor
Philippe Legendre
Jean Marie Nef
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Thales SA

Original Assignee
Thomson CSF SA
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1976-11-19
Filing date
1977-11-16
Publication date
1980-04-16

1977-11-16
Application filed by Thomson CSF SA
filed
Critical
Thomson CSF SA

1980-04-16
Publication of GB1565153A
publication
Critical
patent/GB1565153A/en

Status
Expired
legal-status
Critical
Current

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230000003321
amplification
Effects

0.000
title
claims
description
3

238000003199
nucleic acid amplification method
Methods

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title
claims
description
3

239000003990
capacitor
Substances

0.000
claims
description
8

238000012937
correction
Methods

0.000
description
12

239000013256
coordination polymer
Substances

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description
5

230000000694
effects
Effects

0.000
description
4

238000010586
diagram
Methods

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description
2

230000003071
parasitic effect
Effects

0.000
description
2

230000010349
pulsation
Effects

0.000
description
2

230000005540
biological transmission
Effects

0.000
description
1

230000003247
decreasing effect
Effects

0.000
description
1

238000000034
method
Methods

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description
1

Classifications

H—ELECTRICITY

H03—ELECTRONIC CIRCUITRY

H03F—AMPLIFIERS

H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements

H03F1/32—Modifications of amplifiers to reduce non-linear distortion

H03F1/3217—Modifications of amplifiers to reduce non-linear distortion in single ended push-pull amplifiers

Description

PATENT SPECIFICATION ( 11) 1 565 153
M ( 21) Application No 47764/77 ( 22) Filed 16 Nov 1977 ( 19) ( 31) Convention Application No 7634913 ( 32) Filed 19 Nov 1976 in /» ( 33) France (FR) % ( 44) Complete Specification Published 16 Apr 1980 m ( 51) INT CL 3 H 03 F 1/08 l ( 52) Index at Acceptance H 3 T 2 Q 3 B 3 N 4 A 1 4 E 2 N 5 E AL ( 54) A DISTORTION CORRECTOR FOR WIDE-BAND TRANSISTORIZED AMPLIFICATION STAGES ( 71) We, THOMSON-CSF, a French Body Corporate of 173, Boulevard Haussmann, 75008 Paris France, do hereby declare the invention, for which we pray that a patent may be granted to us, and the method by which it is to be performed to be particularly described in and by the following statement:
This invention relates to distortion correctors for wide-band amplifiers and particularly 5 for coaxial cable repeaters.
The transmission of information by carrier currents over large distances necessitates the cascading of a large number of line amplifiers (up to several hundred) which are intended to compensate the attenuation of coaxial cables.
These amplifiers have to satisfy very stringent requirements in order to reach the quality 10 objectives recommended by the CCITT, particularly in regard to the intermodulation distortion including that of order 3 which is particularly troublesome particularly because it increases with the square of the number of repeaters.
One of the major causes of intermodulation distortion in transistorized amplifiers is the varactor effect of the transistors, which is reflected in a variation in the base-collector 15 capacitance of the transistors according to the amplitude of the amplified signal, and creates an intermodulation distortion which increases in dependence upon the frequency and power level; this latter is important in the case of the transistors of the output stages of high-capacity line repeaters.
It is known that these deficiences can be overcome by using transistors specially designed 20 for that They operate with high currents and biassing voltages and by simultaneously effecting a global correction of the amplifier either by negative feedback or by a so-called «feed-forward» circuit which corrects the amplified signal by reinjecting the sole products of distortion into the output signal in phase opposition.
These arrangements are attended by the drawback of involving the use of special, and 25 therefore expensive, transistors which increase the consumption of the repeater whilst at the same time reducing its reliability correlatively, and the use of a correction circuit which is made difficult by the phasing necessities which it involves quite apart from the problems of stability which arise if the correction circuit is of the negative feedback type.
The object of the present invention is considerably to reduce these requirements both in 30 regard to the special performances of the transistors and their consumption and in regard to the number of corrections which may remain necessary and which therefore become easier to effect this reduction being made possible by carrying out a simple correction at the actual level of at least one of the transistorized stages responsible for all the distortions.
According to the invention there is provided a distortion corrector for a wide-band 35 transistorized amplifier having at least a transistor the base collector junction capacitance C of which is variable in dependence upon the amplitude of the current passing through it, comprising at least one circuit having a capacitive impedance in parallel with a resistance, said circuit being inserted into said amplifier in such a way that it is traversed by the current amplified by said amplifier from a source impedance which is low by comparison with the 40 impedance of said circuit, and said capacitive impedance being formed by first and second varactors connected head-to-tail and having a capacitance which is variable in dependence upon the voltage established at its terminals according to a law determined to obtain compensation for the distortion introduced by said capacitance C.
The invention will be better understood from the following description in conjunction 45
1 565 153 with the accompanying drawing, wherein:
Figure 1 is a circuit diagram of one example of application of the corrector, according to the invention, to an amplifier stage equipped with a transistor having a common emitter circuit.
Figure 2 shows a variant of Figure 1 applied to a stage having a common collector circuit 5 followed by a stage having a common base circuit.
In Figure 1, an NPN transistor 1 receives at its base 2 an a c voltage delivered by a generator 3 of internal resistance R, Its collector 4 is connected to an output terminal 5 and to a positive biassing voltage B, through a resistor R 2 Its emitter 6 is connectd to earth through a resistor R 5 and to one of the plates of capacitors Cl and C, of which the others are 10 connected to earth respectively through the anode-cathode junction of a varactor 10 and the cathode-anode junction of a varactor 11 A negative biassing source B, supplies the anode of the varactor 10 through a resistor R 3 whilst a positive biassing source B 3 supplies the cathode of the varactor 11 through a resistor R 4.
This amplifier stage, having a common emitter circuit, delivers the signals applied to its 15 base 2 in amplified form at its output 5.
Its base-collector junction is the seat of a parasitic varactor effect which may be represented by an equivalent circuit diagram formed by a variable parasitic capacitor CP varying in the opposite direction to the voltage of the signal which is applied to it through a resistance RP 20 With respect to a transmitted signal of pulsation A this network has a transfer function TP such that 1 ( 1) T = P 1 +j RPCP C 25 where CP has a law of variation in dependence upon the voltage V which is at its terminals and which is a characteristic peculiar to the transistor used It has the following form:
CP = Q, ( 1 +a V+b V 2 +) 30 where C, is the value of the capacitance CP at rest in the absence of an a c signal a and b parameters representative of the non-linearity of the system, which are respectively responsible for the intermodulation distortion of order 2 by linear variation of the capacitance in dependence upon the amplitude of the signal and for the intermodulation 35 distortion of order 3 by variation, at the second degree of this same capacitance.
These distortions are compensated by a correction circuit according to the invention inserted into the emitter circuit of the transistor 1 In this circuit, the capacitors Cl and C, have an insulating function with respect to the biassing by d c voltages B, and B 3, they show a negligible impedance to the amplified alternating currents The resistors RR and R 4 40 are selected with very high values by comparison with the impedances of the varactors 10 and 11 to these same currents which therefore see an impedance ZE of the emitter circuit formed by the resistor R in parallel with a variable capacitance Cv formed by the varactors and 11 connected head-to-tail thus giving the following relation:
z 1 ZE = 1 +j RC, O where c) is the pulsation of the alternating current transmitted.
If the current gain P 3 of the transistor is very much greater than one and if the internal 50 resistance R, of the generator 3 is negligible by comparison with the product 3 ZE the gain of the stage i e the ratio of the voltage collected at the terminals of the load resistor R 2 to that supplied by the generator 3 is given by R, R, b = __ = ( 1 +j R 5 C, Cl)) 55 ZE RThere is thus obtained a transfer function ( 2) T, =-( 1 +j R,C, i) R 560 of the current flowing through this correction network which is the opposite of the transfer function Tp of the distorting network expressed by relation ( 1) above.
The transfer functions T, and T are in series in the circuit and the resulting transfer function TR is expressed by the product T x T 1, i e.
1 565 153 TR = Kl+j R 5 Cv, 1 +j R 1 CP X The distortion will be eliminated if TR is independent of C, and Cp which will be the case 5 if R 5 = R and if C = C this latter equality determining the choice of the varactors 10 and 11 and their operating Ppoints ensured by the voltages B, and B 3.
The following Figure shows a different circuit in which the correction network according to the invention acts as a connection between an input transistor having a common collector circuit and an output transistor having a common base circuit 10 In Figure 2, an NPN transistor 11 receives at its base 12 an a c voltage supplied by a generator 13 of internal resistance R,1 Its collector 14 is connected to a positive voltage source B 4 and its emitter 16 is connected, through a resistor R 15, to the emitter 26 of a PNP transistor 21 of which the base is connected to earth and of which the collector 24 is connected to an output terminal 25 and to a positive voltage source B, through a load 15 resistor R 12 A correction circuit, similar to that shown in the preceding figure, comprises in parallel, between the emitters 16 and 26, the cathode-anode space of a varactor 30 in series with a capacitor C,,, and a capacitor C 12 in series with the anodecathode space of a varactor 31 in addition to the already mentioned resistor R 15 Finally, the anodes of the varactors 30 and 31 are respectively connected to negative voltage sources B,, and B 12 20 through corresponding resistors R 13 and R 14.
If the current gains of each transistor are significantly greater than one, if the source resistance RI, is negligible, and taking into account the fact that the input impedance of the transistor 21, having a common base circuit is low by comparison with that of the correction circuit, the voltage gain may be expressed as follows: 25 G = R 12 ZF where ZF is the impedance of the emitter circuit of the transistor 11 which, under the 30 assumptions made, is limited to that of the correction circuit, namely:
F 1 +j R,5 C’, w 35 where C’, is the capacitance formed by the varactors 30 and 31 connected head-to-tail.
Accordingly, the conditions here are the same as in the circuit shown in Figure 1, C’, having, in this case, to be selected to compensate the varactor effect resulting from the two transistors 11 and 21.
The circuits described have been tested with type 2 N 5109 and 2 N 5583 transistors and 40 with type MV 1404 hyperabrupt varactors MOTOROLA (registered Trade Mark) These types of transistors have resulted in two varactors connected head-totail being included in the correction circuit.
Other types of varactors might be necessary with different transistors.
Similarly, it is pointed out that if the feed of the corrector by an emitter circuit readily 45 enables the need for a low internal source resistance to be satisfied, the corrector may also be differently connected, in particular between the collector of a first transistor and the base of a second transistor, provided that the first transistor has a sufficiently low load resistance and that the second transistor is a transistor operating with high currents so that it has a low input impedance 50 Experience has shown that the circuits described above enable the intermodulation power to be decreased by 10 d B for all the frequencies of the range of applications of the wide-band amplifiers thus equipped.

Claims (4)

WHAT WE CLAIM IS:

1 A distortion corrector for a wide-band transistorized amplifier having at least a 55 transistor the base collector junction capacitance C of which is variable in dependence upon the amplitude of the current passing through it comprising at least one circuit having a capacitive impedance in parallel with a resistance said circuit being inserted into said amplifier in such a way that it is traversed by the current amplified by said amplifier from a source impedance which is low by comparison with the impedance of said circuit, and said 60 capacitive impedance being formed bv first and second varactors connected head-to-tail and having a capacitance which is variable in dependence upon the voltage established at its terminals according to a law determined to obtain compensation for the distortion introduced by said capacitance C.

2 A corrector as claimed in claim l applied to a transistor having a common emitter 65 A 1 565 153 4 circuit, wherein the anode of said first varactor and the cathode of said second varactor are grounded, the cathode of said first varactor being connected to the emitter of said transistor through an insulating capacitor and coupled to a first adjustable biassing source, and the anode of said second varactor being connected to the emitter of said transistor through an insulating capacitor and coupled to a second adjustable biassing source, said first and 5 second biassing sources being opposite in sign.

3 A corrector as claimed in claim 1 applied to two cascaded amplification stages comprising a first transistor which has a common collector circuit and of which the emitter circuit is coupled with that of a second transistor having a common base circuit wherein the cathodes of said first and second varactors are respectively connected to the emitters of said 10 first and second transistors, each anode of said first and second varactors being respectively connected on the one hand to the emitter of said second and first transistors through an insulating capacitor and on the other hand to two adjustable biassing sources.

4 A distortion corrector substantially as described herein with reference to Figure 1 or to Figure 2 of the accompanying drawing 15 A wide band transistorized amplifier including distortion corrector as claimed in any preceding claim.
HASELTINE, LAKE & CO, Chartered Patent Agents, 20 Hazlitt House, 28, Southampton Buildings.
Chancery Lane.
London WC 2 A IAT.
-also 25 Temple Gate House, Temple Gate.
Bristol B 51 6 PT.
Agents for the Applicants.
Printed for Her Majesty’, Stationery Office, by Croydon Printing Company Limited Croydon Surrey 1980.
Published by The Patent Office, 25 Southampton Buildings, London WC 2 A IAY from which copies may be obtained.
A

GB47764/77A
1976-11-19
1977-11-16
Distortion corrector for wide-band transistorized amplification stages

Expired

GB1565153A
(en)

Applications Claiming Priority (1)

Application Number
Priority Date
Filing Date
Title

FR7634913A

FR2371817B1
(en)

1976-11-19
1976-11-19

CORRECTION DEVICE FOR DISTORTION OF BROADBAND TRANSISTORIZED AMPLIFICATION STAGES AND AMPLIFIER COMPRISING SUCH DEVICES

Publications (1)

Publication Number
Publication Date

GB1565153A
true

GB1565153A
(en)

1980-04-16

Family
ID=9180105
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

GB47764/77A
Expired

GB1565153A
(en)

1976-11-19
1977-11-16
Distortion corrector for wide-band transistorized amplification stages

Country Status (6)

Country
Link

US
(1)

US4119923A
(en)

CA
(1)

CA1118505A
(en)

DE
(1)

DE2751566C2
(en)

FR
(1)

FR2371817B1
(en)

GB
(1)

GB1565153A
(en)

NL
(1)

NL181540C
(en)

Cited By (2)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

GB2204202A
(en)

*

1987-04-28
1988-11-02
Racal Communications Equip
Radio transmitters

US5262734A
(en)

*

1991-07-06
1993-11-16
Racal Communications Systems Limited
Amplification systems

Families Citing this family (7)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

DE2819087C2
(en)

*

1978-04-29
1985-10-31
Philips Patentverwaltung Gmbh, 2000 Hamburg

Amplifier circuit with two transistors

JPS60113513A
(en)

*

1983-11-24
1985-06-20
Pioneer Electronic Corp
Signal waveform equalizing circuit

US4999585A
(en)

*

1989-11-06
1991-03-12
Burr-Brown Corporation
Circuit technique for cancelling non-linear capacitor-induced harmonic distortion

US5194827A
(en)

*

1991-04-10
1993-03-16
Ampex Systems Corporation
Voltage controlled high frequency equalization

JP3164151B2
(en)

*

1998-07-06
2001-05-08
日本電気株式会社

Power amplifier

CN1233090C
(en)

*

2000-08-11
2005-12-21
新加坡国立大学
Programmable radio frequency predistortion linearizer and method thereof

KR100965700B1
(en)

*

2005-03-04
2010-06-24
삼성전자주식회사
Pre-distorter

Family Cites Families (4)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3509480A
(en)

*

1968-10-03
1970-04-28
Gen Electric
Reduction of differential phase distortion in a system for correction of a video signal

US3533020A
(en)

*

1969-01-13
1970-10-06
Us Air Force
Reduction of intermodulation in varactor-tuned filters

US3614644A
(en)

*

1969-12-15
1971-10-19
Sylvania Electric Prod
Amplifier apparatus with distortion compensation

US3952260A
(en)

*

1974-12-16
1976-04-20
Delta-Benco-Cascade Limited
Distortion correction circuit

1976

1976-11-19
FR
FR7634913A
patent/FR2371817B1/en
not_active
Expired

1977

1977-11-15
US
US05/851,804
patent/US4119923A/en
not_active
Expired – Lifetime

1977-11-16
NL
NLAANVRAGE7712609,A
patent/NL181540C/en
not_active
IP Right Cessation

1977-11-16
GB
GB47764/77A
patent/GB1565153A/en
not_active
Expired

1977-11-17
CA
CA000291136A
patent/CA1118505A/en
not_active
Expired

1977-11-18
DE
DE2751566A
patent/DE2751566C2/en
not_active
Expired

Cited By (4)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

GB2204202A
(en)

*

1987-04-28
1988-11-02
Racal Communications Equip
Radio transmitters

US4890300A
(en)

*

1987-04-28
1989-12-26
Racal Communications Equipment Limited
Radio transmitters

GB2204202B
(en)

*

1987-04-28
1991-11-27
Racal Communications Equip
Radio transmitters

US5262734A
(en)

*

1991-07-06
1993-11-16
Racal Communications Systems Limited
Amplification systems

Also Published As

Publication number
Publication date

DE2751566C2
(en)

1986-02-27

NL181540C
(en)

1987-09-01

CA1118505A
(en)

1982-02-16

DE2751566A1
(en)

1978-05-24

US4119923A
(en)

1978-10-10

FR2371817B1
(en)

1980-09-05

NL7712609A
(en)

1978-05-23

FR2371817A1
(en)

1978-06-16

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Legal Events

Date
Code
Title
Description

1980-07-02
PS
Patent sealed [section 19, patents act 1949]

1990-07-11
PCNP
Patent ceased through non-payment of renewal fee

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