WO2000072440A1 - Amplifier circuit - Google Patents

Amplifier circuit Download PDF

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Publication number
WO2000072440A1
WO2000072440A1 PCT/GB2000/001895 GB0001895W WO0072440A1 WO 2000072440 A1 WO2000072440 A1 WO 2000072440A1 GB 0001895 W GB0001895 W GB 0001895W WO 0072440 A1 WO0072440 A1 WO 0072440A1
Authority
WO
WIPO (PCT)
Prior art keywords
signal
path
filters
sideband
along
Prior art date
Application number
PCT/GB2000/001895
Other languages
French (fr)
Inventor
Ian James Forster
Original Assignee
Marconi Data Systems Ltd.
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.)
Filing date
Publication date
Application filed by Marconi Data Systems Ltd. filed Critical Marconi Data Systems Ltd.
Priority to US09/926,572 priority Critical patent/US6799027B1/en
Priority to DE60003925T priority patent/DE60003925T2/en
Priority to AU49347/00A priority patent/AU4934700A/en
Priority to AT00931390T priority patent/ATE245317T1/en
Priority to US11/541,516 priority patent/USRE40900E1/en
Priority to JP2000620731A priority patent/JP4498620B2/en
Priority to EP00931390A priority patent/EP1188231B1/en
Priority to CA002371595A priority patent/CA2371595A1/en
Publication of WO2000072440A1 publication Critical patent/WO2000072440A1/en

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Classifications

    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03FAMPLIFIERS
    • H03F3/00Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
    • H03F3/60Amplifiers in which coupling networks have distributed constants, e.g. with waveguide resonators
    • H03F3/608Reflection amplifiers, i.e. amplifiers using a one-port amplifying element and a multiport coupler
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03FAMPLIFIERS
    • H03F2201/00Indexing scheme relating to details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements covered by H03F1/00
    • H03F2201/32Indexing scheme relating to modifications of amplifiers to reduce non-linear distortion
    • H03F2201/3215To increase the output power or efficiency

Definitions

  • AMPLIFIER CIRCUIT This invention relates to an amplifier circuit, in particular but not exclusively to an amplifier
  • circuit for providing bandpass amplification at intermediate frequencies in radio receivers.
  • the radio receivers employ amplifiers therein to amplify
  • Such received signals to an amplitude in the order of millivolts to volts, for example to drive
  • a radio for example, a radio
  • the receiver heterodynes the received signal to generate an
  • amplifier circuits incorporated therein. These circuits comprise transmission amplifiers and associated surface acoustic wave (SAW) or ceramic filters to provide a narrow bandpass signal
  • SAW surface acoustic wave
  • the inventor has appreciated, rather than concentrating on improving battery technology, that reduction in current consumption of intermediate frequency amplifier circuits in radio
  • the invention has
  • the filters are not operable to inhibit signal propagation in a reverse direction along the cascaded series of amplifiers to prevent the occurrence of spontaneous oscillation.
  • an amplifier circuit for receiving an input signal and providing a corresponding amplified output signal, the circuit characterised in that
  • the filters and the modulating means operative to promote
  • the circuit provides the benefit that is capable of providing signal amplification
  • Spontaneous oscillation is defined as self induced oscillation arising along a signal path providing amplification as a consequence of feedback occurring around or within the signal
  • the filters are arranged in series along the signal path, the filters alternating between sideband transmissive filters and sideband rejective filters along the path, and the
  • modulating means is arranged to convert the input signal as it propagates along the signal path
  • the invention provides a method of amplifying an input signal and providing
  • connecting means for connecting the reflection amplifiers to the signal path
  • the connecting means operative to promote signal propagation in a forward direction along the path and counteract signal propagation in a reverse direction therealong, the connecting means
  • the filters and the modulating means operative to promote
  • step (e) repeating step (d) until the amplified signal reaches an output of the signal path;
  • FIG. 1 is a schematic of an amplifier circuit in accordance with an embodiment of
  • Figure 2 is an illustration of signal transmission characteristics of filters for incorporating into the circuit in Figure 1 ;
  • Figure 3 is a schematic of a circuit of a reflection amplifier for incorporating into the
  • the circuit is indicated by 600. It comprises three bandpass filters 610, 620,
  • Each of the amplifiers 700, 710 incorporates a reflection amplifier circuit indicated by 1400 in Figure 3.
  • the filters 610, 630 are identical and employ surface acoustic wave (SAW), bulk acoustic wave (BAW) or ceramic filter components. Each of filters 610, 630 provides a bandpass
  • the filter 620 also employs SAW, BAW or ceramic filter components. It provides a double
  • double peak characteristic comprises two transmission peaks, a first peak centred at a
  • the first peak has - 3dB
  • the second peak has - 3dB upper and lower cut off frequencies of f 0 - f 2 + f ⁇ and fo - f 2 -
  • Figure 2 provides a graph indicated by 800 illustrating signal transmission
  • the graph 800 comprises a first axis 810
  • the first and second transmission peaks of the filter 620 are indicated by 860, 870
  • the filters 610, 630 also strongly absorb radiation at frequencies
  • the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also serves as a filter for signals applied to their terminals H2. Furthermore, the filter 620 also
  • the switching oscillator 670 is operative to generate a
  • the output from the oscillator 670 is
  • the biphase switches 650, 660 are identical and each incorporates three terminals, namely
  • control signals applied to the terminal K of the switch 650 are operative to control a potential
  • the control signal from the switching oscillator 670 is in the logic state 0, the switches 650,
  • switching oscillator 670 oscillates at the frequency f 2 and generates the control signal at this
  • the frequency f is selected to be equal to or greater than twice fi.
  • the control signal switches the biphase switches 650, 660 so that they phase modulate signals passing therethrough at the frequency f 2 .
  • the filter 610 receives an input signal S ln at its terminal HI input.
  • the signal Sj n is, for example, generated in a preceding stage (not shown) which heterodynes a received signal
  • the signal S m is transmitted through the filter 610
  • the terminal H2 it is unable to pass through the filter 620 because it is not transmissive at frequencies of the signal components; the signal S m thus propagates from the terminal H2
  • the modulated signal S m ⁇ propagates to a port
  • the signal S m3 is phase modulated and comprises two sidebands including signal components in the frequency range of peaks 860, 870.
  • the sidebands in the signal S ⁇ ⁇ are
  • the signal S ⁇ thus propagates from the terminal H3 of the
  • the signal S m3 propagates from the terminal H4 of the filter 620 to the terminal Jl of the
  • the filter 630 is unable to transmit the signal S safelye because it is not transmissive
  • the signal S m3 thus propagates through the switch 660 from its terminal Jl to its terminal J2 to emerge therefrom as a fourth signal S m4 . Because the switch 660 provides phase modulation at the frequency f 2 ,
  • the sidebands in the signal S m3 are heterodyned to generate a signal component in the signal
  • the signal S m4 in a frequency range of the peak 850.
  • the signal S m4 propagates from the terminal J2
  • the signal S ⁇ propagates from the port T3 of the
  • the signal S m6 includes, from the signal S m5 , signal components in the frequency range of the peak 850 after amplification
  • the filter 620 is untransmissive to signals including signal components within the
  • the signal S m6 is prevented
  • the signal S m6 thus propagates through
  • the filter 630 from its terminal HI to its terminal H2 to propagate therefrom as the signal
  • the signal S ou t incorporates signal components present in the signal Si n which have been amplified by the circuit 600.
  • the circuit 600 alternately converts from stage to stage the signal S m to
  • the circuit 600 can be modified to include more amplification stages, each stage
  • the filters 610, 620, 630 can be one or more of SAW filters, ceramic filters or tuned
  • inductance/capacitance filters For high frequency operation, bulk acoustic wave filters can be used.
  • the amplifiers 700, 710 can be connected to a bias controller arranged to control transistor currents within the amplifiers 700, 710 thereby enabling dynamic control of their gain, for
  • AGC automatic gain control
  • the amplifier circuit 600 incorporates a cascaded series of reflection amplifiers connected to form a signal path along which input signal amplification occurs.
  • the reflection amplifiers are connected by switched devices, for example the switches 650, 660 and the
  • filters 610, 620, 630 to facilitate signal propagation in a forward direction along the path for amplification and counteract signal propagation in a reverse direction along the path
  • the reflection amplifier circuit 1400 will now be further described with reference to Figure
  • the circuit 1400 is included within a dotted line 1410 and comprises a silicon or gallium arsenide (GaAs) transistor indicated by 1420, a capacitor 1430 and a resistor 1440 forming
  • a termination network for the transistor 1420 a feedback capacitor 1450, an inductor 1460
  • the circuit 1400 includes a resistor 1470 forming a bias network, and a current source 1480.
  • the circuit 1400
  • an input/output port T3 which is connected to a gate electrode 1420g of the transistor 1420 and to a first terminal of the capacitor 1450.
  • the circuit 1400 is connected to a power supply 1500 for supplying the circuit 1400 with
  • the supply 1500 is connected to a drain electrode 1420d of the transistor 1420 and also to a first terminal of the capacitor 1430; a second terminal of the capacitor 1430 is
  • the capacitor 1450 provides a second terminal which is
  • the gate electrode 1420g receives an incoming signal
  • the incoming signal causes a signal current corresponding to the incoming signal to flow between the source electrode 1420g and the drain electrode
  • the signal current is coupled through gate-drain and gate-source capacitances of
  • the incoming signal is reflected at the gate electrode 1420g where it is combined with the
  • circuit 1400 and its associated components shown within the dotted line 1410 are
  • amplifier circuit 600 incorporating a plurality of the circuits 1400 is capable of providing
  • reflection amplifiers can be used with reflection amplifiers provided they exhibit similar characteristics to the switches and filters in the circuit 600, namely for counteracting
  • the circuit 600 can be incorporated into radio receivers, for example mobile telephones,
  • the circuit is capable of operating as an IF receiver.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Amplifiers (AREA)
  • Compounds Of Unknown Constitution (AREA)
  • Pharmaceuticals Containing Other Organic And Inorganic Compounds (AREA)
  • Steroid Compounds (AREA)

Abstract

The invention provides an amplifier circuit (600) for amplifying an input signal to generate an amplifier output signal. The circuit incorporates a cascaded series of reflection amplifiers (1400) arranged along a signal path and operative to amplify signals propagating in a forward direction along the signal path. The circuit is operative to counteract signal propagation in a reverse direction along the signal path, thereby hindering spontaneous oscillation from arising within the circuit (600). Incorporation of reflection amplifiers into the circuit enables it to provide high gain, for example 50 dB, whilst consuming low currents, for example tens of microamperes. The circuit (600) is especially suitable for use at intermediate frequencies in radio receivers such as mobile telephones.

Description

AMPLIFIER CIRCUIT This invention relates to an amplifier circuit, in particular but not exclusively to an amplifier
circuit for providing bandpass amplification at intermediate frequencies in radio receivers.
Amplifiers are widely used in the prior art for amplifying input signals applied thereto to
provide amplified output signals. This is particularly important in radio receivers in which
radiation received thereat generates corresponding antenna received signals which typically
have an amplitude of microvolts. The radio receivers employ amplifiers therein to amplify
such received signals to an amplitude in the order of millivolts to volts, for example to drive
a loudspeaker. Since it is difficult to prevent amplifiers designed to amplify at radio
frequencies from spontaneously oscillating, especially if they comprise cascaded gain providing stages, it is customary to heterodyne the received signals to lower intermediate
frequencies whereat it is easier to provide a high degree of amplification and also provide
more selective bandpass signal filtration.
In prior art radio receivers, it is therefore customary to provide a majority of signal
amplification required at intermediate frequencies, namely frequencies lying intermediate
between that of the radiation received and audio or video frequencies. For example, a radio
receiver receives radiation at a frequency of 500 MHz and generates a corresponding antenna
received signal also at 500 MHz. The receiver heterodynes the received signal to generate an
intermediate frequency signal in a frequency range around 10.7 MHz which is then amplified
and filtered, and finally demodulates the amplified intermediate frequency signal to generate
a corresponding audio output signal having signal components in a frequency range of 100 Hz to 5 kHz. Recently, because the radio frequency spectrum is becoming increasingly congested, there is
a trend to use an ultra high frequency (UHF) range in contemporary communications systems,
namely around 500 MHz; transmission at microwave frequencies, for example 1 GHz to 30
GHz is now also employed. Associated with this is a trend in modern radio receiver design
to employ intermediate frequency amplification at several tens of MHz or greater; this is done
in order to obtain adequate ghost image rejection associated with using heterodyne processes.
In modern mobile telephones, most signal amplification is provided in intermediate frequency
amplifier circuits incorporated therein. These circuits comprise transmission amplifiers and associated surface acoustic wave (SAW) or ceramic filters to provide a narrow bandpass signal
amplification characteristic; the circuits and their associated filters are conventionally referred
to collectively as an "intermediate frequency strip". Such transmission amplifiers consume
significant power in operation, for example intermediate frequency amplifier circuits employed
in mobile telephones typically consume between several hundred microamperes and several mA of current when operational.
In order to provide modern mobile telephones with extended operating time from their
associated batteries, new types of battery have been researched and developed which provide enhanced charge storage to weight performance, for example rechargeable metal hydride and
lithium batteries.
The inventor has appreciated, rather than concentrating on improving battery technology, that reduction in current consumption of intermediate frequency amplifier circuits in radio
receivers is desirable to provide extended operating time from batteries. The invention has
therefore been made in a endeavour to provide an alternative type of amplifier circuit, for example a circuit especially suitable for use at intermediate frequencies in radio receivers
which is capable of requiring less power to operate.
It is known in the art, as described in a Japanese patent application no. JP 55137707, to
cascade reflection amplifiers in series and interpose filters therebetween to prevent higher
harmonic components generated in preceding stages from propagating to successive stages.
The filters are not operable to inhibit signal propagation in a reverse direction along the cascaded series of amplifiers to prevent the occurrence of spontaneous oscillation.
According to the present invention, there is provided an amplifier circuit for receiving an input signal and providing a corresponding amplified output signal, the circuit characterised in that
it comprises:
(a) a plurality of reflection amplifiers cascaded in series along a signal path and operative
to amplify the input signal propagating in a forward direction therealong to provide the output signal; and
(b) connecting means for connecting the reflection amplifiers to form the signal path and
for hindering signal propagation in a reverse direction therealong, thereby
counteracting spontaneous oscillation from arising within the circuit, the connecting
means incorporating filters which are interposed between neighbouring reflection
amplifiers along the signal path, and modulating means for modulating the input signal to associated sideband signal components and converting to and from the sideband
components along the path, the filters and the modulating means operative to promote
signal propagation in the forward direction along the path and hinder signal propagation in the reverse direction therealong. ~ ~
This provides the advantage that interposition of the filters between the amplifiers is capable
of isolating each amplifier from its neighbouring amplifiers, thereby hindering signal propagation in the reverse direction along the path; incorporation of the modulating means
enables the input signal propagating through each amplifier to be converted between a carrier
and a sideband signal, thereby enabling it to propagate through the filters in the forward
direction along the path.
The circuit provides the benefit that is capable of providing signal amplification and
consuming less current during operation compared to prior art amplifier circuits.
One skilled in the art would not expect it to be practicable to connect a plurality of reflection
amplifiers together and obtain stable amplification therefrom because of spontaneous interfering oscillations which would arise during operation. The circuit addresses this problem
by incorporating the connecting means which promotes intended signal amplification in the
circuit and counteracts signal amplification giving rise to spontaneous oscillation therein.
Spontaneous oscillation is defined as self induced oscillation arising along a signal path providing amplification as a consequence of feedback occurring around or within the signal
path.
Conveniently, the filters are arranged in series along the signal path, the filters alternating between sideband transmissive filters and sideband rejective filters along the path, and the
modulating means is arranged to convert the input signal as it propagates along the signal path
alternately between a corresponding carrier signal transmissible substantially through the sideband rejective filters only and a corresponding sideband signal transmissible substantially
through the sideband transmissive filters only, thereby promoting input signal propagation in the forward direction along the path and hindering signal propagation in the reverse direction
therealong.
In another aspect, the invention provides a method of amplifying an input signal and providing
a corresponding amplified output signal, the method characterised in that it includes the steps
of:
(a) providing a plurality of reflection amplifiers cascaded in series along a signal path, and
connecting means for connecting the reflection amplifiers to the signal path and
operative to promote signal propagation in a forward direction along the path and counteract signal propagation in a reverse direction therealong, the connecting means
incorporating filters which are interposed between neighbouring reflection amplifiers
along the signal path, and modulating means for modulating the input signal to
associated sideband signal components and converting to and from the sideband
components along the path, the filters and the modulating means operative to promote
signal propagation in the forward direction along the path and hinder signal
propagation in the reverse direction therealong;
(b) receiving the input signal at the signal path;
(c) directing the input signal through the connecting means to one of the reflection amplifiers for amplification therein to provide an amplified signal;
(d) directing the amplified signal to another of the reflection amplifiers for further amplification therein;
(e) repeating step (d) until the amplified signal reaches an output of the signal path; and
(f) outputting the amplified signal as the output signal from the signal path. The method provides the advantage that, during amplification, the signal is selectively directed
from amplifier to amplifier in a forward direction along the signal path, thereby counteracting
any of the amplifiers reamplifying the input signal and hence preventing any feedback loops
being established in which spontaneous oscillation can arise.
An embodiment of the invention will now be described, by way of example only, with
reference to the following diagrams in which:-
Figure 1 is a schematic of an amplifier circuit in accordance with an embodiment of
the invention;
Figure 2 is an illustration of signal transmission characteristics of filters for incorporating into the circuit in Figure 1 ; and
Figure 3 is a schematic of a circuit of a reflection amplifier for incorporating into the
circuit in Figure 1.
Referring to Figure 1, there is shown an amplifier circuit according to an embodiment of
the invention; the circuit is indicated by 600. It comprises three bandpass filters 610, 620,
630, two biphase switches 650, 660, a switching oscillator 670 and two reflection
amplifiers 700, 710. Each of the amplifiers 700, 710 incorporates a reflection amplifier circuit indicated by 1400 in Figure 3.
The filters 610, 630 are identical and employ surface acoustic wave (SAW), bulk acoustic wave (BAW) or ceramic filter components. Each of filters 610, 630 provides a bandpass
transmission characteristic for signals propagating between its terminals HI, H2. The
characteristic comprises a single transmission peak centred at a frequency fo having upper
and lower - 3 dB cut off frequencies of fo + f ι and fo - f \ respectively. In the circuit 600, fo
is 100 MHz and fi is 50 kHz.
The filter 620 also employs SAW, BAW or ceramic filter components. It provides a double
peak transmission characteristic for signals propagating between its terminals H3, H4. The
double peak characteristic comprises two transmission peaks, a first peak centred at a
frequency fo + f2 and a second peak centred at a frequency fo - f2. The first peak has - 3dB
upper and lower cut off frequencies of fo + f + f ι and f o + f - f ι respectively. Likewise, the second peak has - 3dB upper and lower cut off frequencies of f0 - f2 + f \ and fo - f2 -
respectively. Figure 2 provides a graph indicated by 800 illustrating signal transmission
characteristics of the filters 610, 620, 630. The graph 800 comprises a first axis 810
representing frequency and a second axis 820 representing relative signal transmission through the filters 610, 620, 630.
In Figure 2, the single transmission peak of the filters 610, 630 is indicated by 850.
Likewise, the first and second transmission peaks of the filter 620 are indicated by 860, 870
respectively. Moreover, the filters 610, 630 also strongly absorb radiation at frequencies
around fo - f2 and fo +f2, , namely around a frequency range of the peaks 860, 870,
especially for signals applied to their terminals H2. Furthermore, the filter 620 also
strongly absorbs radiation around a frequency range of the peak 850, especially for signals
applied to its terminal H4. ~ 6 ~
Referring now to Figure 1 again, the switching oscillator 670 is operative to generate a
binary logic square wave control signal at its output which switches periodically between
a logic state 0 and a logic state 1 at the frequency f2. The output from the oscillator 670 is
connected to input control terminals K of the biphase switches 650, 660.
The biphase switches 650, 660 are identical and each incorporates three terminals, namely
signal terminals Jl, J2 and an input terminal K as described above. The switch 650
incorporates an inductor and a varactor, also known in the art as a varicap diode; control signals applied to the terminal K of the switch 650 are operative to control a potential
applied to the varactor therein, thereby changing its tuning and affecting a phase shift
imparted to signals propagating through the switch 650 between its terminals Jl, J2. When
the control signal from the switching oscillator 670 is in the logic state 0, the switches 650,
660 are operative to provide 0° phase shift; conversely, when the control signal is in the
logic state 1, the switches 650, 660 are operative to provide 90° phase shift. Thus, in
operation, signals propagating through and subsequently returning from switches 650, 660
via their terminals Jl, J2 and amplified by associated reflection amplifiers 700, 710 are
periodically switched in phase between 0° and 180°.
Operation of the circuit 600 will now be described with reference to Figures 1 and 2. The
switching oscillator 670 oscillates at the frequency f2 and generates the control signal at this
frequency at its output. The frequency f is selected to be equal to or greater than twice fi.
The control signal switches the biphase switches 650, 660 so that they phase modulate signals passing therethrough at the frequency f2 .
The filter 610 receives an input signal Sln at its terminal HI input. The signal Sjn is, for example, generated in a preceding stage (not shown) which heterodynes a received signal
to generate the signal Sm as an intermediate frequency signal including signal components
in a frequency range of fo - fi to f o + f i . The signal Sm is transmitted through the filter 610
from the terminal HI to the terminal H2 thereof because its signal components are within
the frequency range of the peak 850 of the filter 610. When the signal Sm propagates from
the terminal H2, it is unable to pass through the filter 620 because it is not transmissive at frequencies of the signal components; the signal Sm thus propagates from the terminal H2
to the terminal Jl of the switch 650 and becomes phase modulated therein to emerge at the
terminal J2 as a first modulated signal Smι. The modulated signal Smι propagates to a port
T3 of the amplifier 700 which reflectively amplifiers the signal Smι to provide a second amplified modulated signal S^. The signal S^z propagates from the port T3 of the
amplifier 700 back through the switch 650 whereat it is further phase modulated to provide
a third modulated signal Sm3 which is output at the terminal Jl.
The signal Sm3 is phase modulated and comprises two sidebands including signal components in the frequency range of peaks 860, 870. The sidebands in the signal Sπβ are
prevented from propagating back through the filter 610 because it is non-transmissive at the
frequencies of these sidebands. The signal S^ thus propagates from the terminal H3 of the
filter 620 to the terminal H4 thereof because the sidebands are within the frequency range
of the peaks 860, 870 of the filter 620.
The signal Sm3 propagates from the terminal H4 of the filter 620 to the terminal Jl of the
switch 660. The filter 630 is unable to transmit the signal S„e because it is not transmissive
at the frequency ranges of the sidebands of the signal. The signal Sm3 thus propagates through the switch 660 from its terminal Jl to its terminal J2 to emerge therefrom as a fourth signal Sm4. Because the switch 660 provides phase modulation at the frequency f2,
the sidebands in the signal Sm3 are heterodyned to generate a signal component in the signal
Sm4 in a frequency range of the peak 850. The signal Sm4 propagates from the terminal J2
of the switch 660 to a port T3 of the amplifier 710 wherein it is reflectively amplified to
provide an amplified signal Sms. The signal S^ propagates from the port T3 of the
amplifier 710 back through the switch 660 whereat it is further phase modulated to emerge
as a sixth signal Sm6 at the terminal Jl of the switch 660. The signal Sm6 includes, from the signal Sm5, signal components in the frequency range of the peak 850 after amplification
thereof.
Because the filter 620 is untransmissive to signals including signal components within the
frequency range of the peak 850, especially at its H4 terminal, the signal Sm6 is prevented
from being transmitted back through the filter 620. The signal Sm6 thus propagates through
the filter 630 from its terminal HI to its terminal H2 to propagate therefrom as the signal
Sout- The signal Sout incorporates signal components present in the signal Sin which have been amplified by the circuit 600.
In broad overview, the circuit 600 alternately converts from stage to stage the signal Sm to
be amplified from carrier frequency, namely within the frequency range of the peak 850,
to sidebands, namely within the frequency range of the peaks 860, 870. Thus, the switches
650, 660 in combination with the filters 610, 620, 630 are effective at counteracting signal
propagation back in a reverse direction along a path from the output Sout to the input Sin; this isolates the amplifiers 700, 710 thereby enabling greater signal amplification to be
achieved in the circuit 600 without spontaneous oscillations arising. Hence, the circuit 600
is capable of providing high signal amplification approaching 50 dB for low current consumption in the order of a few tens of microamperes on account of employing reflection amplifiers.
If the reflection amplifiers 700, 710 were merely cascaded together without the switches
650, 660 and the filters 610, 620, 630, severe spontaneous oscillation problems would be encountered which would hinder intended input signal amplification from being achieved.
The circuit 600 can be modified to include more amplification stages, each stage
incorporating a reflection amplifier and being isolated from its neighbouring stages by a
filter like the filter 610 in a first direction along the signal path, and by a filter like the filter 620 in a second direction along the signal path, said directions being mutually opposite.
This enables higher gain to be achieved on account of incorporating more amplifier stages
than illustrated in Figure 1.
The filters 610, 620, 630 can be one or more of SAW filters, ceramic filters or tuned
inductance/capacitance filters. For high frequency operation, bulk acoustic wave filters can
also be employed.
The amplifiers 700, 710 can be connected to a bias controller arranged to control transistor currents within the amplifiers 700, 710 thereby enabling dynamic control of their gain, for
example where automatic gain control (AGC) is required to cater for a relatively large dynamic range of signals applied at Sm.
The amplifier circuit 600 incorporates a cascaded series of reflection amplifiers connected to form a signal path along which input signal amplification occurs. The reflection amplifiers are connected by switched devices, for example the switches 650, 660 and the
filters 610, 620, 630, to facilitate signal propagation in a forward direction along the path for amplification and counteract signal propagation in a reverse direction along the path
which can give rise to spontaneous oscillation. This enables higher amplification gains to
be achieved for a lower current consumption which is less than required for prior art
transmission amplifiers providing comparable gain.
The reflection amplifier circuit 1400 will now be further described with reference to Figure
3. The circuit 1400 is included within a dotted line 1410 and comprises a silicon or gallium arsenide (GaAs) transistor indicated by 1420, a capacitor 1430 and a resistor 1440 forming
a termination network for the transistor 1420, a feedback capacitor 1450, an inductor 1460
and a resistor 1470 forming a bias network, and a current source 1480. The circuit 1400
includes an input/output port T3 which is connected to a gate electrode 1420g of the transistor 1420 and to a first terminal of the capacitor 1450.
The circuit 1400 is connected to a power supply 1500 for supplying the circuit 1400 with
power. The supply 1500 is connected to a drain electrode 1420d of the transistor 1420 and also to a first terminal of the capacitor 1430; a second terminal of the capacitor 1430 is
connected to a signal ground. The capacitor 1450 provides a second terminal which is
connected to a source electrode 1420s of the transistor 1420, to the resistor 1440 which is
grounded, and through the inductor 1460 and the resistor 1470 in series to the source 1480, which is connected to the signal ground.
In operation of the circuit 1400, the gate electrode 1420g receives an incoming signal
applied through the port T3. The incoming signal causes a signal current corresponding to the incoming signal to flow between the source electrode 1420g and the drain electrode
1420d. The signal current is coupled through gate-drain and gate-source capacitances of
the transistor 1420 and also through the capacitor 1450, thereby generating an outgoing
signal at the gate electrode 1420g which is an amplified version of the incoming signal.
The incoming signal is reflected at the gate electrode 1420g where it is combined with the
outgoing signal which propagates out through the port T3.
On account of the circuit 1400 receiving the incoming signal and returning the combined
signal via one terminal, namely the port T3, it behaves as a reflecting negative resistance.
The circuit 1400 and its associated components shown within the dotted line 1410 are
capable of providing a high power gain approaching +30 dB for a drain/source current
through the transistor 1420 in the order of a few tens of microamperes. Such a high power
gain is not achievable from a transmission amplifier operating on such a low supply current.
When incorporated into a mobile telephone as part of its intermediate frequency strip, the
amplifier circuit 600 incorporating a plurality of the circuits 1400 is capable of providing
an order of magnitude reduction in telephone current consumption associated with
amplifying signals therein at intermediate frequencies compared to prior art. This is of considerable benefit which provides extended duration of telephone operation from power
supplied from rechargeable batteries for example.
It will be appreciated by those skilled in the art that variations can be made to the circuit
600 without departing from the scope of the invention. Thus, alternative switching devices,
or equivalent devices, can be used with reflection amplifiers provided they exhibit similar characteristics to the switches and filters in the circuit 600, namely for counteracting
spurious oscillation from arising.
The circuit 600 can be incorporated into radio receivers, for example mobile telephones,
to function as intermediate frequency strips therein. Moreover, when provided with a
demodulator to convert signals output from the circuit 600, the circuit is capable of operating as an IF receiver.

Claims

1. An amplifier circuit (600) for receiving an input signal (Sm) and providing a
corresponding amplified output signal (Sout), the circuit characterised in that it comprises:
(a) a plurality of reflection amplifiers (710, 710) cascaded in series along a signal path and
operative to amplify the input signal (Sm) propagating in a forward direction therealong
to provide the output signal (Sout); and
(b) connecting means (610, 620, 630, 650, 660) for connecting the reflection amplifiers
(700, 710) to form the signal path and for hindering signal propagation in a reverse
direction therealong, thereby counteracting spontaneous oscillation from arising within
the circuit (600), the connecting means incorporating filters (610, 620, 630) which are
interposed between neighbouring reflection amplifiers (700, 710) along the signal path,
and modulating means (650, 660) for modulating the input signal to associated sideband
signal components (860, 870) and converting to and from the associated sideband signal
components (860, 870) along the path, the filters (610, 620, 630) and the modulating
means (650, 660) being operative to promote signal propagation in the forward
direction along the path and hinder signal propagation in the reverse direction
therealong.
2. A circuit according to Claim 1 wherein the filters (610, 620, 630) are arranged in series
along the signal path, the filters alternating between sideband transmissive filters (620) and
sideband rejective filters (610, 630) along the path, and the modulating means (650, 660)
is arranged to convert the input signal (Sm) as it propagates along the signal path alternately
between a corresponding carrier signal (850) transmissible substantially through the
sideband rejective filters (610, 630) only and a corresponding sideband signal transmissible substantially through the sideband transmissive filters (620) only, thereby promoting input
signal propagation in the forward direction along the path and hindering signal propagation in the reverse direction therealong.
3. A circuit according to Claim 1 or 2 wherein the modulating means comprises a plurality
of phase switches (650, 660), each phase switch having a respective reflection amplifier (700, 710) associated therewith.
4. A circuit according to Claim 3 wherein the phase switches (650, 660) are interposed
between the filters and their associated amplifiers (700, 710).
5. A circuit according to Claim 1, 2, 3 or 4 wherein the modulating means (650, 660) is
operable at a rate having an associated frequency which is half a frequency separation of
transmission peaks of the sideband transmission characteristics of the sideband transmissive
filters.
6. A circuit according to Claim 4 or 5 wherein the phase switches (650, 660) each
incorporate a tuned circuit comprising an inductor and a modulated varactor.
7. An intermediate frequency strip incorporating an amplifier circuit according to any
preceding claim.
8. An intermediate frequency receiver incorporating an amplifier circuit according to any
one of Claims 1 to 6.
9. A mobile telephone incorporating an amplifier circuit according to any one of Claims
l to 6.
10. A method of amplifying an input signal and providing a corresponding amplified
output signal, the method characterised in that it includes the steps of:
(a) providing a plurality of reflection amplifiers (700, 710) cascaded in series along a
signal path, and connecting means (610, 620, 630, 650, 660) for connecting the
reflection amplifiers (700, 710) to the signal path and operative to promote signal
propagation in a forward direction along the path and counteract signal propagation
in a reverse direction therealong, the connecting means incorporating filters (610,
620, 630) which are interposed between neighbouring reflection amplifiers (700,
710) along the signal path, and modulating means (650, 660)for modulating the
input signal (Sm) to associated sideband signal components and converting to and
from associated sideband signal components along the path, the filters (610, 620,
630) and the modulating means (650, 660) being operative to promote signal
propagation in the forward direction along the path and hinder signal propagation
in the reverse direction therealong;
(b) receiving the input signal (Sm) at the signal path;
(c) directing the input signal through the connecting means (610) to one of the
reflection amplifiers (700) for amplification therein to provide an amplified signal;
(d) directing the amplified signal in the forward direction to another of the reflection
amplifiers (710) for further amplification therein;
(e) repeating step (d) until the amplified signal reaches an output of the signal path; and
(f) outputting the amplified signal as the output signal (Sout) from the signal path.
PCT/GB2000/001895 1999-05-22 2000-05-17 Amplifier circuit WO2000072440A1 (en)

Priority Applications (8)

Application Number Priority Date Filing Date Title
US09/926,572 US6799027B1 (en) 1999-05-22 2000-05-17 Amplifier circuit
DE60003925T DE60003925T2 (en) 1999-05-22 2000-05-17 AMPLIFIER CIRCUIT
AU49347/00A AU4934700A (en) 1999-05-22 2000-05-17 Amplifier circuit
AT00931390T ATE245317T1 (en) 1999-05-22 2000-05-17 AMPLIFIER CIRCUIT
US11/541,516 USRE40900E1 (en) 1999-05-22 2000-05-17 Amplifier circuit
JP2000620731A JP4498620B2 (en) 1999-05-22 2000-05-17 Amplifier circuit
EP00931390A EP1188231B1 (en) 1999-05-22 2000-05-17 Amplifier circuit
CA002371595A CA2371595A1 (en) 1999-05-22 2000-05-17 Amplifier circuit

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
GBGB9911880.4A GB9911880D0 (en) 1999-05-22 1999-05-22 Amplifier circuit
GB9911880.4 1999-05-22

Publications (1)

Publication Number Publication Date
WO2000072440A1 true WO2000072440A1 (en) 2000-11-30

Family

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PCT/GB2000/001895 WO2000072440A1 (en) 1999-05-22 2000-05-17 Amplifier circuit
PCT/GB2000/001893 WO2000072439A1 (en) 1999-05-22 2000-05-17 Amplifier circuit

Family Applications After (1)

Application Number Title Priority Date Filing Date
PCT/GB2000/001893 WO2000072439A1 (en) 1999-05-22 2000-05-17 Amplifier circuit

Country Status (11)

Country Link
US (3) USRE40900E1 (en)
EP (2) EP1186097B1 (en)
JP (2) JP4498620B2 (en)
KR (1) KR100849001B1 (en)
CN (2) CN1364336A (en)
AT (2) ATE245317T1 (en)
AU (2) AU4934700A (en)
CA (2) CA2371595A1 (en)
DE (2) DE60003925T2 (en)
GB (3) GB9911880D0 (en)
WO (2) WO2000072440A1 (en)

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Also Published As

Publication number Publication date
GB2350957B (en) 2001-08-01
EP1188231A1 (en) 2002-03-20
GB2350957A (en) 2000-12-13
KR20020053033A (en) 2002-07-04
CN1365537A (en) 2002-08-21
ATE245317T1 (en) 2003-08-15
JP2003500967A (en) 2003-01-07
DE60001940T2 (en) 2004-01-08
EP1186097B1 (en) 2003-04-02
EP1188231B1 (en) 2003-07-16
DE60003925T2 (en) 2004-02-05
GB2350958A (en) 2000-12-13
CA2371595A1 (en) 2000-11-30
JP4498619B2 (en) 2010-07-07
ATE236473T1 (en) 2003-04-15
KR100849001B1 (en) 2008-07-30
USRE40900E1 (en) 2009-09-01
GB0011666D0 (en) 2000-07-05
EP1186097A1 (en) 2002-03-13
CA2371593A1 (en) 2000-11-30
GB0011665D0 (en) 2000-07-05
DE60003925D1 (en) 2003-08-21
CN1364336A (en) 2002-08-14
US6480062B1 (en) 2002-11-12
JP2003500968A (en) 2003-01-07
JP4498620B2 (en) 2010-07-07
WO2000072439A1 (en) 2000-11-30
GB2350958B (en) 2001-08-01
AU4934700A (en) 2000-12-12
GB9911880D0 (en) 1999-07-21
DE60001940D1 (en) 2003-05-08
AU4934600A (en) 2000-12-12
US6799027B1 (en) 2004-09-28

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