A detector circuit for detecting degradation in the distortion characteristics of a power amplifier based on signals from both ends of a coupled line of a directional coupler. The detector circuit includes a phase shifter/attenuator for phase shifting and attenuating a signal from a coupled terminal of the coupled line, a differential amplifier for outputting difference between an output signal from the phase shifter/attenuator and a signal from the isolated terminal of the coupled line, a wave detector circuit for converting the difference into a dc signal, and a comparing circuit for determining whether the voltage level of the dc signal exceeds a predetermined level. When degradation in the distortion characteristics of the power amplifier arises, the phase shifter/attenuator phase shifts the signal from the coupled terminal and outputs a signal 180° out of phase with the signal from the isolated terminal.
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1. A detector circuit for detecting degradation in distortion characteristics of a power amplifier based on signals derived from a coupled line of a directional coupler, wherein the directional coupler includes a main line connected to the power amplifier and to an antenna, and a coupled line having a coupled terminal at a first end of the coupled line and an isolated terminal at a second end of the coupled line, said detector circuit comprising:
a phase shifter/attenuators connected to said coupled terminal of said coupled line of the directional coupler and shifting phase of the signal from said coupled terminal of said coupled line, and attenuating the signal from said coupled terminal of said coupled line and outputting an output signal;
difference output means connected to and receiving the output signal from said phase shifter/attenuator and to said isolated terminal of said coupled line and outputting a difference signal representing difference between the output signal from said phase shifter/attenuator and the signal from said isolated terminal of said coupled line;
a wave detector circuit for converting the difference signal into a dc signal; and
a comparing circuit for determining whether voltage level of the dc signal exceeds a predetermined level, wherein, when load conditions at the antenna cause degradation in the distortion characteristics of the power amplifier, said phase shifter/attenuator phase shifts the signal from said coupled terminal of said coupled line so that the output signal of the said phase shifter/attenuator is 180° out of phase with the signal from said isolated terminal of said coupled line.
11. A semiconductor device comprising:
a detector circuit for detecting degradation in distortion characteristics of a power amplifier based on signals derived from a coupled line of a directional coupler, wherein the directional coupler includes a main line connected to the power amplifier and to an antenna, and a coupled line having a coupled terminal at a first end of the coupled line and an isolated terminal at a second end of the coupled line, said detector circuit comprising:
a phase shifter/attenuators connected to said coupled terminal of said coupled line of the directional coupler and shifting phase of the signal from said coupled terminal of said coupled line, and attenuating the signal from said coupled terminal of said coupled line and outputting an output signal;
difference output means connected to and receiving the output signal from said phase shifter/attenuator and to said isolated terminal of said coupled line and outputting a difference signal representing difference between the output signal from said phase shifter/attenuator and the signal from said isolated terminal of said coupled line;
a wave detector circuit for converting the difference signal into a dc signal; and
a comparing circuit for determining whether voltage level of the dc signal exceeds a predetermined level, wherein, when load conditions at the antenna cause degradation in the distortion characteristics of the power amplifier, said phase shifter/attenuator phase shifts the signal from said coupled terminal of said coupled line so that the output signal is 180° out of phase with the signal from said isolated terminal of said coupled line; and
means for varying the load impedance of the power amplifier in accordance with the output from said comparing circuit to prevent degradation of the distortion characteristics.
2. The detector circuit according to
3. The detector circuit according to
4. The detector circuit according to
said phase shifter/attenuator includes a first phase shifter/attenuator and a second phase shifter/attenuator;
said difference output means includes first difference output means and second difference output means;
an output signal from said first phase shifter/attenuator is input to said first difference output means;
an output signal from said second phase shifter/attenuator is input to said second difference output means;
said first phase shifter/attenuator phase shifts a first signal and outputs a signal 180° out of phase with the signal from said isolated terminal of said coupled line; and
said second phase shifter/attenuator phase shifts a second signal, different from the first signal, and outputs a signal 180° out of phase with the signal from said isolated terminal of said coupled line.
5. The detector circuit according to
6. The detector circuit according to
said coupled line includes a first coupled line and a second coupled line;
said first phase shifter/attenuator is connected to a coupled terminal of said first coupled line;
said second phase shifter/attenuator is connected to a coupled terminal of said second coupled line;
said first difference output means is connected to an isolated terminal of said first coupled line; and
said second difference output means is connected to an isolated terminal of said second coupled line.
7. The detector circuit according to
said isolated terminal of said coupled line includes a first isolated terminal connected to an intermediate point of said coupled line and further includes a second isolated terminal connected to the second end of said coupled line;
said first and second difference output means are connected to said first isolated terminal through a first switch; and
said first and second difference output means are connected to said second isolated terminal through a second switch.
9. The detector circuit according to
said balun has a side connected to said phase shifter/attenuator and a grounded center point; and
said wave detector circuit includes a variable capacitor connected in parallel with said side of said balun.
10. The detector circuit according to
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1. Field of the Invention
The present invention relates to a circuit for detecting variations in the load at the antenna terminal of the transmitter front end of a portable terminal, etc., and more particularly to a detector circuit for detecting the reflection amplitude and phase at the antenna end. The present invention also relates to a semiconductor device using such a circuit.
2. Background Art
The transmitter front end of a wireless terminal generally includes a directional coupler for monitoring the transmission power level, etc. This directional coupler is inserted, e.g., between the transmission power amplifier and the antenna. In such configurations, the directional coupler is used to monitor the output level (or output power) of the amplifier.
A well known transmitter front end will be described with reference to
As shown in
As in this example, the distortion characteristics of the power amplifier may be degraded due to variation in the load at the antenna end. Particularly it is important and necessary to prevent degradation of the distortion characteristics of CDMA power amplifiers. Conventional methods for preventing degradation of the distortion characteristics due to variation in the load include the use of an isolator (a device which allows power to pass from the input IN to the output OUT but prevents power from passing from the output OUT to the input IN) instead of a directional coupler, and the use of a power amplifier employing a balanced configuration. These methods, however, increases the manufacturing cost of the front end.
The present invention has been made to solve the above problems. It is, therefore, an object of the present invention to provide a detector circuit that allows for an easy and low cost way to prevent degradation of the distortion characteristics. Another object of the present invention is to provide a semiconductor device adapted to use such a detector circuit.
According to one aspect of the present invention, a detector circuit for detecting a degradation in the distortion characteristics of a power amplifier based on signals from both ends of a coupled line of a directional coupler disposed between the power amplifier and an antenna, the detector circuit includes, a phase shifter/attenuator for phase shifting and attenuating a signal from the coupled terminal of the coupled line, means for outputting the difference between an output signal from the phase shifter/attenuator and a signal from the isolated terminal of the coupled line, a wave detector circuit for converting the difference into a DC signal, and a comparing circuit for determining whether the voltage level of the DC signal exceeds a predetermined level. When the load conditions at the antenna end cause a degradation in the distortion characteristics of the power amplifier, the phase shifter/attenuator phase shifts the signal from the coupled terminal to output a signal 180° out of phase with the signal from the isolated terminal.
According to another aspect of the present invention, a semiconductor device includes a detector circuit for detecting a degradation in the distortion characteristics of a power amplifier based on signals from both ends of a coupled line of a directional coupler disposed between the power amplifier and an antenna, wherein the detector circuit includes a phase shifter/attenuator for phase shifting and attenuating a signal from the coupled terminal of the coupled line, means for outputting the difference between an output signal from the phase shifter/attenuator and a signal from the isolated terminal of the coupled line, a wave detector circuit for converting the difference into a DC signal, and a comparing circuit for producing an output if the voltage level of the DC signal exceeds a predetermined level, and wherein when the load conditions at the antenna end cause a degradation in the distortion characteristics of the power amplifier, the phase shifter/attenuator phase shifts the signal from the coupled terminal to output a signal 180° out of phase with the signal from the isolated terminal, and means for varying the load impedance of the power amplifier in accordance with the output from the comparing circuit to prevent degradation of the distortion characteristics.
Other and further objects, features and advantages of the invention will appear more fully from the following description.
A first embodiment of the present invention will be described with reference to
The configuration of the detector circuit 10 will be described. A resistance 16 is connected at one end to one end of the coupled line 14 and at the other end to ground, and a resistance 18 is connected at one end to the other end of the coupled line 14 and at the other end to ground. A phase shifter/attenuator 20 is connected to the coupled terminal 15. The phase shifter/attenuator 20 phase shifts and attenuates the power from the coupled terminal 15. The output of the phase shifter/attenuator 20 and the isolated terminal 17 are connected to a differential amplifier 22. The differential amplifier 22 converts a differential signal into a single phase signal. The output of the differential amplifier 22 is connected to a wave detector circuit 24 through a coupling capacitor Cc1. The wave detector circuit 24 is of the current mirror type and converts the RF signal into a DC signal.
The phase shifter/attenuator 20 phase shifts the power from the coupled terminal 15 to output a signal 180° out of phase with the signal from the isolated terminal 17 when the load conditions (or impedance) at the antenna end cause a degradation in the distortion characteristics of the power amplifier. In addition, the phase shifter/attenuator 20 attenuates the power from the coupled terminal 15 so that the output signal from the phase shifter/attenuator 20 is equal in amplitude to the signal from the isolated terminal 17 when they are 180° out of phase. The phase shifter in the phase shifter/attenuator 20 may be implemented with lumped-parameter elements or a delay line (which is merely a long transmission line), etc. Further, the attenuator in the phase shifter/attenuator 20 may be only a series resistance or a resistance attenuator having a π or T configuration. It should be noted that typical load conditions at the antenna end which cause a degradation in the distortion characteristics of the amplifier include, e.g., those indicated by points A and B in
The operation of the detector circuit 10 will now be described. When reflection occurs at the antenna end (28), the reflected power Pr is coupled out to the isolated terminal 17 (#C2). The signal (or power) transmitted from the input to the output, on the other hand, is coupled out to the coupled terminal 15 (#C1). In this example, the directional coupler is assumed to have a directivity of approximately 10-2 dB (as defined as the ratio of the output power from the coupled terminal 15 to the output power from the isolated terminal 17). The power output from the isolated terminal 17 is input to the differential amplifier 22. The signal (or power) output from the coupled terminal 15, on the other hand, is phase shifted and attenuated by the phase shifter/attenuator 20 and then input to the differential amplifier 22.
Upon receiving the signals from the terminals 15 and 17, the differential amplifier 22 outputs a signal corresponding to the difference between the received signals; that is, the voltage amplitude of the signal output from the differential amplifier 22 is maximized when the received signals are equal in amplitude to each other and are 180° out of phase with each other. The output of the differential amplifier 22 is input to the wave detector circuit 24 through the coupling capacitor Cc1. The wave detector circuit 24 converts the RF signal (i.e., the input to the wave detector circuit 24) into a DC signal. The comparing circuit 26 compares the output from the wave detector circuit 24 with a reference voltage level Vref and, if it exceeds the reference voltage level Vref, the comparing circuit 26 outputs a noninverted signal Vo1 and an inverted signal Vo2.
Thus by using the detector circuit 10 of the present embodiment it is possible to detect the reflection amplitude and phase when the distortion in the output of the power amplifier is greatest. The output of the comparing circuit 26 may be used to vary the load impedance of the power amplifier so as to prevent degradation of the distortion characteristics of the amplifier. That is, this makes it possible to prevent degradation of the distortion characteristics of even common power amplifiers due to load variations, thus providing a low cost way to reduce degradation of the distortion characteristics of power amplifiers. Although the present invention is not primarily intended for balanced power amplifiers (which have relatively good distortion characteristics), the detector circuit of the present embodiment may be used with a balanced power amplifier to further reduce degradation of the distortion characteristics of the amplifier due to load variations.
The construction and operating principle of the detector circuit 10 of the present embodiment are very simple. Therefore, the detector circuit 10 can be manufactured by a GaAs-HBT process or a GaAs-BiFET process (including only n-channel FETs or npn transistors), which are often used to manufacture power amplifiers. This means that the detector circuit 10 can be easily incorporated in power amplifiers.
Although in the present embodiment the phase shifter/attenuator 20 is constructed to produce only a fixed amount of phase shift and a fixed amount of attenuation, it is to be understood that the present invention is not limited to this particular construction. For example, the phase shifter in the phase shifter/attenuator 20 may have the construction shown in
When the detector circuit 10 of the present embodiment is implemented with a GaAs-based device, the wave detector circuit 24 preferably has “steep” DC inversion characteristics. The use of a wave detector circuit with relatively “steep and linear” wave detection characteristics (i.e., a wave detector circuit with a detected voltage (V) vs. input (dB) curve which is relatively steep and linear, as shown in
A detector circuit of a second embodiment of the present invention allows for detection of reflection amplitudes and phases under two different load conditions which cause a degradation in the distortion characteristics of the power amplifier. The present embodiment will be described with reference to
The output of the first phase shifter/attenuator 50 is input to a first differential amplifier 54, and the output of the second phase shifter/attenuator 52 is input to a second differential amplifier 56. The signal from the isolated terminal 17 is input to both the first and second differential amplifiers 54 and 56. The outputs of the first and second differential amplifiers 54 and 56 are input to a wave detector circuit 24 through capacitances Cc1 and Cc2, respectively. The configurations and operations of the wave detector circuit 24 and the comparing circuit 26 connected to the output of the wave detector circuit 24 are the same as those described in connection with the first embodiment.
Thus, the detector circuit of the present embodiment includes two phase shifters/attenuators each connected to a respective differential amplifier. When the load conditions are those indicated by point A in
Further, the outputs of the differential amplifiers 54 and 56 are connected together and to the wave detector circuit 24 in a wired OR manner through the capacitances Cc1 and Cc2. Thus the detector circuit of the present embodiment is small and simple in construction, as compared to detector circuits provided with two separate wave detector circuits. Further, this wired OR configuration allows the power outputs from the differential amplifiers 54 and 56 to cancel out each other before they are input to the wave detector circuit 24, except under the load conditions indicated by points A and B in
Although in the present embodiment the detector circuit includes only one wave detector circuit 24 and only one comparing circuit 26, it is to be understood that the invention is not limited to this particular construction. In other embodiments, the detector circuit may include two wave circuits 180 and 182 and two comparing circuit 184 and 186, as shown in
A third embodiment of the present invention provides a detector circuit capable of handling a larger dynamic range of input signals than the detector circuits of the first and second embodiments. The present embodiment will be described with reference to
Referring to
The wave detector circuit 24 is connected to the dual balun 90 through a single phase amplifier 92. This construction eliminates the need for having two wave detector circuits, so that the detector circuit is small and simple in construction. Further, this construction allows the power outputs from the phase shifters/attenuators 94 and 96 to cancel out each other before they are input to the wave detector circuit 24, except under the load conditions indicated by points A and B in
A fourth embodiment of the present invention relates to a detector circuit which receives signals from a plurality of coupled lines. The present embodiment will be described with reference to
This construction allows one to design the first phase shifter/attenuator 104 and the second phase shifter/attenuator 106 separately, thereby facilitating the design of the detector circuit. That is, the connection of two phase shifters/attenuators to a single coupled line, as in the second embodiment, complicates the design of the detector circuit. The construction of the detector circuit of the present embodiment avoids this by including two coupled lines. The present embodiment also has all the advantages of the second embodiment.
A fifth embodiment of the present invention relates to a detector circuit having a function to switch between a coupled line and a series connection of coupled lines. The present embodiment will be described with reference to
The first coupled line 120 has a coupled terminal 121 (#C1) at one end and a first isolated terminal 123 (#C2′) at the other end. The first isolated terminal 123 is connected to a first differential amplifier 54 and to a second differential amplifier 56 through a first switch 128 (Fa). When the first coupled line 120 and the second coupled line 122 together function as a single coupled line, the second isolated terminal 125 (#C2) of the second coupled line 122 serves as the isolated terminal of that coupled line (the series connection of coupled lines). The second isolated terminal 125 is connected to the first differential amplifier 54 and to the second differential amplifier 56 through a second switch 130 (Fb). Thus, the detector circuit of the present embodiment is characterized in that it can be switched between a coupled line and a series connection of coupled lines and thereby switched between different electrical lengths by turning on and off the first switch 128 and the second switch 130.
Specifically, when the first switch 128 is turned on and the second switch 130 is turned off, the first coupled line 120 alone functions as a coupled line. When the first switch 128 is turned off and the second switch 130 is turned on, on the other hand, the first coupled line 120 and the second coupled line 122 together function as a single coupled line. The phase shifters/attenuators may be constructed such that the amount of phase shift and the amount of attenuation produced by each phase shifter/attenuator can be varied to operate the detector circuit at two different frequencies while maintaining the coupling of the directional coupler substantially constant. Further, if the coupling is substantially equalized between two frequency bands, the detector circuit can be operated in these two frequency bands by varying only the amounts of phase shift produced by the phase shifters while maintaining the characteristics of the attenuators substantially constant. This eliminates the need for adjustment of the attenuators, allowing the detector circuit to be made small and simple in construction. The present embodiment also has all the advantages of the second embodiment.
It follows also from this construction that if the coupling is substantially equalized between two frequency bands, the detector circuit can be operated in these two frequency bands by varying only the amounts of phase shift produced by the phase shifters while maintaining the characteristics of the attenuators substantially constant. This eliminates the need for adjustment of the attenuators, allowing the detector circuit to be made small and simple in construction.
A sixth embodiment of the present invention provides a semiconductor device (e.g., portable terminal) in which the detector circuit shown in
Further, a detector circuit 10 (shown enclosed by the dashed line in
The load lines of the power amplifier will now be described with reference to
Thus, in the semiconductor device of the present embodiment, the output of the comparing circuit in the detector circuit is used to vary the load impedance of the power amplifier so as to prevent degradation of the distortion characteristics of the amplifier. Although the semiconductor device of the present embodiment employs the detector circuit 10 of the first embodiment, it is to be understood that the detector circuit of any one of the embodiments described above may be used to implement the concept of the present embodiment while retaining the advantages noted above.
Such a variation of the semiconductor device of the present embodiment will be described with reference to
The semiconductor device shown in
Further, a detector circuit (shown enclosed by the dashed line in
The Load lines of the power amplifiers will now be described with reference to
The features of the present invention will be described primarily with reference to the first embodiment discussed above. As described above, the detector circuit of the first embodiment of the invention is adapted to detect the reflection amplitude and phase at an antenna end under load variations, and includes a phase shifter/attenuator for adjusting the phase and amplitude of the signal from the coupled line of the directional coupler. The detector circuit also includes a wave detector circuit for detecting the power level of the RF signal and a comparing circuit for determining the power level. Further, the semiconductor device of the sixth embodiment of the present invention is adapted to use the signal from the detector circuit of the first embodiment and includes means for varying the load impedance of the power amplifier so as to prevent degradation of the distortion characteristics of the amplifier due to load variations.
With this circuit configuration, the above detector circuit of the present invention can detect the reflection amplitude and phase at the antenna end when the distortion in the output of the power amplifier is greatest under load variations. Further, the detection signal from the detector circuit may be used to vary the load impedance of the power amplifier. This makes it possible to prevent degradation of the distortion characteristics of even common power amplifiers due to load variations. That is, it is possible to efficiently prevent degradation of the distortion characteristics of a power amplifier by detecting specific load conditions which cause a degradation in the distortion characteristics of the amplifier. Further, the detector circuits of the present invention may be used with balanced power amplifiers to further reduce degradation of the distortion characteristics of the amplifiers due to load variations. Since the construction and operating principle of the detector circuits of the present invention are simple, they can be manufactured by a GaAs-HBT process or a GaAs-BiFET process (including only n-channel FETs or npn transistors), which are often used to manufacture power amplifiers. This means that the detector circuits can be easily incorporated in power amplifiers.
Thus, the present invention allows for an easy and low coat way to prevent degradation of the distortion characteristics.
Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.
The entire disclosure of a Japanese Patent Application No. 2010-023029, filed on Feb. 4, 2010 including specification, claims, drawings and summary, on which the Convention priority of the present application is based, are incorporated herein by reference in its entirety.
Yamamoto, Kazuya, Asada, Tomoyuki, Miyashita, Miyo
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