JP2007143035A - Transmission apparatus and transmission power detection device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission apparatus and transmission power detection device thereof in which powers of two transmission signals can be detected and controlled while suppressing increase in the number of circuit elements or expansion in the area. <P>SOLUTION: A signal flowing backward from a first output terminal T1 to a first power amplifier circuit A1 is suppressed by an isolator 10 provided in a signal path for supplying a transmission signal from the first power amplifier circuit A1 to the first output terminal T1. Furthermore, a part of an output signal from a second power amplifier circuit A2 is inputted to an input terminal T3 of a rectifier circuit 13 by a directional coupler circuit 11 provided in a signal path for supplying a transmission signal from the second power amplifier circuit A2 to a second output terminal T2. Moreover, a part of an output signal from the first power amplifier circuit A1 is inputted to the rectifier circuit 13 by capacitors C1, C2 for electrically coarsely coupling an input terminal of the isolator 10 and the input terminal T3 of the rectifier circuit 13. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a transmission device that selectively transmits a plurality of signals and a transmission power detection device that is used to control the transmission power of each signal. For example, transmission of a mobile phone or the like that performs wireless communication by switching a plurality of signals It relates to the device.

  A dual-band communication terminal that performs wireless communication by switching between two frequency bands is known. By adopting a dual-band communication terminal, for example, it is possible to cover a plurality of different communication methods with a single unit, and a limited frequency band can be used effectively by switching the use band according to the degree of congestion of the line. The benefits of

  2 to 4 are diagrams illustrating examples of a general configuration of a transmission apparatus in such a dual-band communication terminal.

The transmitter shown in FIG. 2 employs the method disclosed in Patent Document 1, for example, and includes power amplifiers 101 and 102, an isolator 103, a dual directional coupler 105, a rectifier circuit 110, and a resistor 113. And have. The rectifier circuit 110 includes an inductance element 116, a diode 117, a capacitor 118, and a resistor 119.
Transmission signals S1 and S2 having different frequency bands are amplified by power amplifiers 101 and 102, respectively, and supplied to an antenna (not shown) via a dual directional coupler 105. The isolator 103 is inserted between the dual directional coupler 105 and the antenna in order to prevent a signal reflected from the antenna from flowing backward to the power amplifier 101 due to impedance mismatch. The dual directional coupler 105 takes out the output signal of the power amplifier 101 or a part of the output signal of the power amplifier 101 and outputs it to a common output line. One end of the common output line is connected to the ground G via the resistor 113, and the other end is connected to the anode of the diode 117.
The rectifier circuit 110 rectifies the transmission signal extracted by the dual directional coupler 105. In the rectifier circuit 110, the inductance element 116 is connected between the anode of the diode 117 and the ground G, and the capacitor 118 and the resistor 119 are connected in parallel between the cathode of the diode 117 and the ground G. The rectification result of the rectifier circuit 110 is output from the cathode of the diode 117 as a signal S3.

The transmitter shown in FIG. 3 replaces the dual directional coupler 105 of the transmitter shown in FIG. 2 with two single directional couplers 106 and 107, and includes a rectifier circuit 110 that performs rectification with one diode. The rectifier circuit 111 is configured to rectify with two diodes 122 and 123.
The output signal of the power amplifier 101 is supplied to the antenna via the single directional coupler 106 and the isolator 103. The output signal of the power amplifier 102 is supplied to the antenna via the single directional coupler 107. One end of the output line of the unidirectional coupler 106 is connected to the ground G via the resistor 114, and the other end is connected to the anode of the diode 122. One end of the output line of the unidirectional coupler 107 is connected to the ground G via the resistor 115, and the other end is connected to the anode of the diode 123.
The rectifier circuit 111 rectifies the transmission signal extracted by the unidirectional coupler 106 or the transmission signal extracted by the unidirectional coupler 107. In the rectifier circuit 111, the inductance element 120 is connected between the anode of the diode 122 and the ground G, and the inductance element 121 is connected between the anode of the diode 123 and the ground G. The cathodes of the diodes 122 and 123 are connected in common, and a capacitor 124 and a resistor 125 are connected in parallel between the connection point and the ground G.

The transmission apparatus shown in FIG. 4 is obtained by replacing the dual directional coupler 105 in the transmission apparatus shown in FIG. 2 with capacitors 108 and 109 and providing an isolator 104 in the signal path between the power amplifier 102 and the antenna. is there.
The capacitor 108 is connected between the input of the isolator 103 and the anode of the diode 117. The capacitor 109 is connected between the input of the isolator 104 and the anode of the diode 117.

2 to 4, two transmission signals (S1, S2) in different bands are respectively amplified by two power amplifiers (101, 102), and a part of the output signal is directionally coupled. Are taken out by the capacitors (105 to 107) and the capacitors (108 and 109) and rectified in the rectifier circuits (110 and 111). This rectified signal is used for gain control of the power amplifiers (101, 102) as a result of detecting the power of the two transmission signals.
JP 11-355155 A

  2 to 4 have the following disadvantages.

  The dual directional coupler (105) used in the transmission apparatus shown in FIG. 2 has a disadvantage that the signal passing loss is generally larger and the cost is higher than that of the single directional coupler. Further, when a dual directional coupler is formed on the substrate by a strip line or the like to reduce the cost, there is a disadvantage that the substrate becomes thick.

  The transmitter shown in FIG. 3 requires two rectifying diodes (122, 123) and two unidirectional couplers (106, 107), which increases the number of circuit elements. There is a profit. In addition, when a single directional coupler is formed on a substrate by a strip line or the like, there is a disadvantage that a very large area is required.

In the transmission device shown in FIG. 4, since the output of the power amplifier 102 and the input of the rectifier circuit 110 are connected via the capacitor 109, it is necessary to provide an isolator 104 at the output of the power amplifier 102. If the isolator 104 is not provided, when the transmission signal S1 is amplified and output, a signal that flows backward from the antenna to the power amplifier 102 is input to the rectifier circuit 110 via the capacitor 109, reducing the power detection accuracy. Because it ends up.
The isolator 104 also serves to prevent the operation of the power amplifier 102 from becoming unstable due to the reflected wave from the antenna when the transmission signal S2 is amplified and output. However, the power amplifier 102 requires the isolator 104 in order to suppress the above-described reverse flow signal from being input to the rectifier circuit 110 even when it has a characteristic that the influence of the reflected wave is small.
Therefore, in the transmitting apparatus shown in FIG. 4, an extra isolator that is not necessary for the original role must be added, which disadvantageously increases the number of circuit elements and increases the cost.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a transmission apparatus capable of detecting and controlling the power of two transmission signals while suppressing an increase in the number of circuit elements and area, and so on. Another object of the present invention is to provide a transmission power detection device used for a simple transmission device.

  A transmission apparatus according to a first aspect of the present invention includes a first power amplification circuit that amplifies the power of an input first transmission signal and outputs the amplified first transmission signal to a first output terminal, and the input power of the second transmission signal. A second power amplifying circuit for amplifying and outputting to the second output terminal; and a signal path between the first power amplifying circuit and the first output terminal. A suppression circuit that suppresses a signal propagating to the power amplifier circuit; and a signal path between the second power amplifier circuit and the second output terminal, and the second output terminal from the second current amplifier circuit. A directional coupling circuit that extracts a part of a transmission signal that propagates to the first terminal and inputs the extracted signal to the first terminal; a loosely coupled circuit connected between the input terminal of the suppression circuit and the first terminal; and the first terminal The rectifier circuit that rectifies and outputs the signal input to the rectifier, and the rectifier circuit In response to a signal al outputted and a control circuit for controlling the power of the signal output from the first power amplifier circuit or the second power amplifier circuit.

  The loosely coupled circuit is provided at a junction between a conductor line, a first loosely coupled element provided at a junction between the input terminal of the suppression circuit and the conductor line, and a junction between the first terminal and the conductor line. The second loosely coupled element may be included.

  The directional coupling circuit may be electromagnetically coupled to a first strip line provided in a signal path between the second power amplifier circuit and the second output terminal, and to the first strip line. And a second strip line to which a part of a transmission signal propagating from the second power amplifier circuit to the second output terminal is distributed in the first strip line.

  A transmission power detection apparatus according to a second aspect of the present invention is a transmission power detection apparatus that detects the power of a first transmission signal output from a first output terminal or a second transmission signal output from a second output terminal. A suppression circuit that is provided in a signal path for supplying the first transmission signal to the first output terminal, and that suppresses a signal propagating from the first output terminal to the signal path; A directional coupling circuit that is provided in a signal path for supplying the second transmission signal to the output terminal, extracts a part of the signal propagating from the signal path to the second output terminal, and inputs the signal to the first terminal. And a loosely coupled circuit connected between the input terminal of the suppression circuit and the first terminal, and a rectifier circuit that rectifies and outputs a signal input to the first terminal.

  According to the present invention, it is possible to detect the power of two transmission signals while suppressing an increase in the number of circuit elements and the area.

FIG. 1 is a diagram illustrating an example of a configuration of a transmission apparatus according to an embodiment of the present invention.
1 includes a power amplifier circuit A1, A2, an isolator 10, a directional coupling circuit 11, a transmission circuit 12, a rectifier circuit 13, a gain control circuit 14, capacitors C1, C2, and a resistor. And R2.
The power amplifier circuit A1 is an embodiment of the first power amplifier circuit of the present invention.
The power amplifier circuit A2 is an embodiment of the second power amplifier circuit of the present invention.
The isolator 10 is an embodiment of the suppression circuit of the present invention.
The directional coupling circuit 11 is an embodiment of the directional coupling circuit of the present invention.
The circuit including the capacitors C1 and C2 is an embodiment of the loosely coupled circuit of the present invention.
The rectifier circuit 13 is an embodiment of the rectifier circuit of the present invention.

  The transmission circuit 12 selectively generates two transmission signals (S1, S2) having different frequency bands. For example, two systems of transmission data that have been subjected to encoding processing and modulation processing in a digital signal processing circuit (not shown) are converted from analog signals to digital signals, and analog signal processing such as frequency conversion processing and quadrature modulation processing is performed on this. To generate transmission signals S1 and S2. The transmission circuit 12 stops the output of the other when one of the two transmission signals (S1, S2) is output.

  The power amplifier circuit A1 (hereinafter referred to as the first power amplifier circuit A1) amplifies the power of the first transmission signal S1 generated by the transmission circuit 12, and outputs the amplified power to the first output terminal T1 via the isolator 10 described later. Further, by changing the amplification gain of the first power amplifier circuit A1 according to the control signal S31 generated by the gain control circuit 14, the first power amplifier circuit A1 outputs the signal S1A output toward the first output terminal T1. It is possible to control power.

  The power amplifying circuit A2 (hereinafter referred to as the second power amplifying circuit A2) amplifies the power of the second transmission signal S2 generated by the transmission circuit 12, and supplies the power to the second output terminal T2 via the directional coupling circuit 11 described later. Output. Further, by changing the amplification gain of the second power amplifier circuit A2 according to the control signal S32 generated by the gain control circuit 14, the second power amplifier circuit A2 outputs the signal S2A output toward the second output terminal T2. It is possible to control power.

  The isolator 10 is provided in a signal path between the first power amplifier circuit A1 and the first output terminal T1, and transmits a signal that propagates (that is, flows backward) from the first output terminal T1 to the first power amplifier circuit A1. Suppress.

  When the electrical environment around the antenna changes, the impedance of the antenna changes, and transmission signals may be easily reflected. In such a case, the transmission signal output from the first output terminal T1 is reflected by the antenna and returns to the first output terminal T1. The isolator 10 has a function of stabilizing the operation of the first power amplifier circuit A1 by attenuating the signal flowing backward from the antenna to the first output terminal T1 in this way.

  The directional coupling circuit 11 is provided in a signal path between the second power amplifier circuit A2 and the second output terminal T2, and is one of the signals S2A propagating from the second power amplifier circuit A2 to the second output terminal T2. Are taken out and input to the input terminal (first terminal) T3 of the rectifier circuit 13.

The directional coupling circuit 11 can be configured by two strip lines SL1 and SL2, for example, as shown in FIG.
The strip line SL1 is provided in a signal path between the second power amplifier circuit A2 and the second output terminal T2, and propagates the signal S2A amplified in the second power amplifier circuit A2 to the second output terminal T2. To do.
The strip line SL2 is disposed so as to be electromagnetically coupled to the strip line SL1, and a part of the signal S2A propagating from the second power amplifier circuit A2 to the second output terminal T2 is distributed in the strip line SL1. One terminal of the strip line SL2 is connected to the ground G via the resistor R2, and the other terminal is connected to the input terminal T3 of the rectifier circuit 13.
However, the signal distributed to the strip line SL2 is a transmission signal (a signal supplied to the antenna) that propagates from the second power amplifier circuit A2 to the second output terminal T2 in the strip line SL1, and from the second output terminal T2. The signal propagating to the second power amplifier circuit A2 (the signal reflected by the antenna) is hardly distributed.

  The capacitors C1 and C2 and the conductor wiring (conductor line) W1 constitute a circuit (loosely coupled circuit) for electrically coupling the input terminal of the isolator 10 and the input terminal T3 of the rectifier circuit 13.

The wiring W1 can be configured by a strip line.
The capacitor C1 is provided at the junction between the input terminal of the isolator 10 and the wiring W1. The capacitance of the capacitor C1 is relatively small so that the impedance of the capacitor C1 in the frequency band of the transmission signal S1 is sufficiently larger than the characteristic impedance (for example, 50Ω) of the transmission line between the first power amplifier circuit A1 and the isolator 10. Is set to a value. Therefore, most of the signal S1A output from the first power amplifier circuit A1 is transmitted to the isolator 10.

  The capacitor C2 is provided at the junction between the input terminal of the rectifier circuit 13 and the wiring W1. The capacitance of the capacitor C2 is such that the impedance of the capacitor C2 in the frequency band of the transmission signal S2 is sufficiently larger than the characteristic impedance (for example, 50Ω) of the transmission line between the second power amplifier circuit A2 and the directional coupling circuit 11. It is set to a relatively small value. Therefore, most of the signal output from the directional coupling circuit 11 is transmitted to the rectifier circuit 13.

The rectifier circuit 13 is a circuit for rectifying a signal input to the input terminal T3, and includes, for example, an inductance element L1, a diode D1, a capacitor C3, and a resistor R1, as shown in FIG.
The input terminal T3 is connected to the anode of the diode D1. The inductor element L1 is connected between the anode of the diode D1 and the ground G. The capacitor C3 and the resistor R1 are connected in parallel between the cathode of the diode D1 and the ground G.

  According to the above configuration, the diode D1 becomes conductive near the positive peak of the input signal at the input terminal T3, and the capacitor C3 is charged. Therefore, a positive voltage corresponding to the amplitude of the input signal is generated in the capacitor C3. . This positive voltage is input to the gain control circuit 14 as a rectification result of the input signal at the input terminal T3.

The gain control circuit 14 controls the gain of the first power amplifier circuit A1 or the gain of the second power amplifier circuit A2 in accordance with the signal rectified and output by the rectifier circuit 14. That is, when the transmission signal S1 is generated in the transmission circuit 12, the control signal S31 of the first power amplification circuit A1 is generated, and when the transmission signal S2 is generated, the control signal S32 of the second power amplification circuit A2. Is generated.
For example, the gain control circuit 14 controls the control signal according to the output signal of the rectifier circuit 14 (the voltage of the capacitor C3 in the example of FIG. 1) so that a transmission gain according to a target value indicated by a control device (not shown) is obtained. Adjust S1 and S2.

Next, the operation of the transmission apparatus shown in FIG. 1 will be described.
Here, as an example, it is assumed that the transmission device illustrated in FIG. 1 is a dual-band communication terminal, and performs communication by switching between two frequency bands, a 2 GHz band and an 800 MHz band.
The transmission circuit 12 generates a transmission signal S1 in the 2 GHz band or a transmission signal S2 in the 800 MHz band in accordance with control of a control device (not shown).

When communication in the 2 GHz band is performed, the transmission circuit 12 generates a transmission signal S1. The transmission signal S1 is amplified by the first power amplifier circuit A1 and supplied to the antenna (not shown) from the first output terminal T1 via the isolator 10.
Part of the signal S1A amplified in the first power amplifier circuit A1 is input to the input terminal T3 via the capacitors C1 and C2, and is rectified in the rectifier circuit 13. The signal rectified in the rectifier circuit 13 is input to the gain control circuit 14 as the detection result of the power of the signal S1A. In the gain control circuit 14, the control signal S31 is adjusted so that the detection result approaches the target value, and the gain of the first power amplifier circuit A1 is controlled.

  At this time, part of the transmission signal supplied to the antenna is reflected by the antenna due to impedance mismatch and returns to the first output terminal T1. Since this reflected wave is attenuated by the isolator 10 and hardly propagates to the output of the first power amplifier circuit A1, the instability of the first power amplifier circuit A1 due to the reflected wave can be prevented.

On the other hand, when 800 MHz communication is performed, the transmission circuit 12 generates a transmission signal S2. The transmission signal S2 is amplified by the second power amplifier circuit A2 and supplied to the antenna (not shown) from the second output terminal T2 via the directional coupling circuit 11.
Part of the signal S2A amplified in the second power amplifier circuit A2 is taken out by the directional coupling circuit 11 and input to the input terminal T3, and is rectified in the rectifier circuit 13. The signal rectified in the rectifier circuit 13 is input to the gain control circuit 14 as the detection result of the power of the signal S2A. In the gain control circuit 14, the control signal S32 is adjusted so that the detection result approaches the target value, and the gain of the second power amplifier circuit A2 is controlled.

  At this time, part of the transmission signal supplied to the antenna is reflected by the antenna due to impedance mismatch and returns to the second power amplifier circuit A2. Since the second power amplifier circuit A2 has a configuration (characteristics) that is less susceptible to the influence of the reflected wave than the first power amplifier circuit A1, the attenuation of the reflected wave by an isolator such as the first power amplifier circuit A1. Even without processing, the amplification operation can be performed stably.

As described above, according to the present embodiment, the isolator 10 is provided in the signal path for supplying the transmission signal from the first power amplifier circuit A1 to the first output terminal T1, and the isolator 10 allows the first A signal flowing backward from the first output terminal T1 to the first power amplifier circuit A1 is suppressed. A directional coupling circuit 11 is provided in a signal path for supplying a transmission signal from the second power amplifier circuit A2 to the second output terminal T2, and propagates from the second power amplifier circuit A2 to the second output terminal T2. A part of the signal is extracted by the directional coupling circuit 11 and input to the input terminal T3 of the rectifier circuit 13. Furthermore, capacitors C1 and C2 are provided as circuits for electrically loosely coupling the input terminal of the isolator 10 and the input terminal T3 of the rectifier circuit 13, and the first output terminal T1 is provided from the first power amplifier circuit A1. A part of the signal propagating to is input to the input terminal T3 of the rectifier circuit 13 through the capacitors C1 and C2.
Therefore, since the power of two transmission signals can be detected without using a dual directional coupler as in the transmission apparatus shown in FIG. 2, it is possible to reduce costs and improve transmission power.
Further, since it is not necessary to use two single directional couplers and two diodes as in the transmission device shown in FIG. 3, the number of circuit elements can be reduced and an increase in circuit area can be suppressed.
Further, it is not necessary to provide an isolator in the two transmission paths as in the transmission apparatus shown in FIG. 4, and one of them can be omitted, so that the circuit configuration can be simplified.

  Furthermore, by configuring the directional coupling circuit 11 with a strip line on the circuit board, the cost can be reduced as compared with the case where a dedicated component is provided.

  Further, according to the present embodiment, the capacitor C1 is provided in the immediate vicinity of the input line of the isolator 10, and the capacitor C2 is provided in the immediate vicinity of the output line of the directional coupling circuit 11, and the capacitors C1 and C2 are connected by the wiring W1. Therefore, the power of the two transmission signals can be reduced without breaking the impedance matching between the first power amplifier circuit A1 and the isolator 10 and the impedance matching between the second power amplifier circuit A2 and the directional coupling circuit 11. Can be detected by the common rectifier circuit 13.

  In addition, embodiment mentioned above is an example and this invention is not limited only to said form.

  In the example of FIG. 1, the gain control circuit 14 generates the control signal S31 for gain control of the power amplifier circuit A1 and the control signal S32 for gain control of the power amplifier circuit A2, respectively. It is not limited to this. That is, the gain control circuit 14 may generate a control signal common to the power amplifier circuits A1 and A2 according to the rectified signal of the rectifier circuit 13.

  In the example of FIG. 1, capacitors C1 and C2 are used as loosely coupled elements, but these may be replaced with resistors having an appropriately high resistance value.

  In the above-described embodiment, the first power amplifier circuit A1 or the second power amplifier circuit A2 is controlled according to the control signals S31 and S32 output from the gain control circuit 14 according to the signal rectified by the rectifier circuit 14. Although the configuration is such that the power of the signals S1A and S2A output from the first power amplifier circuit A1 or the second power amplifier circuit A2 is controlled by controlling the gain, the present invention is not limited to this. For example, the transmission signals S1 and S2, the first power amplification circuit A1 or the second power amplification generated by the transmission circuit 12 in accordance with a control signal output from the gain control circuit 14 in accordance with a signal rectified in the rectification circuit 14 The level (gain) of the transmission signal S1 input to the circuit A2 may be controlled to control the power of the signals S1A and S2A output from the first power amplifier circuit A1 or A2.

It is a figure which shows an example of a structure of the transmitter which concerns on embodiment of this invention. It is a 1st figure which shows the example of the general structure of the transmitter in the communication terminal of a dual band system. It is a 2nd figure which shows the example of the general structure of the transmitter in the communication terminal of a dual band system. It is a 3rd figure which shows the example of the general structure of the transmitter in the communication terminal of a dual band system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Isolator, 11 ... Directional coupling circuit, 12 ... Transmission circuit, 13 ... Rectifier circuit, 14 ... Gain control circuit, A1 ... 1st power amplifier circuit, A2 ... 2nd power amplifier circuit, C1, C2, C3 ... Capacitor , Resistors R1, R2, inductance elements L1, D1, diodes, W1, wiring.

Claims (4)

A first power amplification circuit that amplifies the power of the input first transmission signal and outputs the amplified first transmission signal to the first output terminal;
A second power amplifier circuit that amplifies the power of the input second transmission signal and outputs the amplified power to the second output terminal;
A suppression circuit that is provided in a signal path between the first power amplifier circuit and the first output terminal, and that suppresses a signal propagating from the first output terminal to the first power amplifier circuit;
The first terminal is provided in a signal path between the second power amplifier circuit and the second output terminal, and extracts a part of the transmission signal propagating from the second current amplifier circuit to the second output terminal. A directional coupling circuit that inputs to
A loosely coupled circuit connected between an input terminal of the suppression circuit and the first terminal;
A rectifier circuit that rectifies and outputs a signal input to the first terminal;
And a control circuit that controls power of a signal output from the first power amplifier circuit or the second power amplifier circuit in accordance with a signal output from the rectifier circuit. The loosely coupled circuit is:
A conductor wire;
A first loosely coupled element provided at a joint between the input terminal of the suppression circuit and the conductor wire;
The transmission device according to claim 1, further comprising: a second loosely coupled element provided at a joint portion between the first terminal and the conductor wire. The directional coupling circuit is:
A first strip line provided in a signal path between the second power amplifier circuit and the second output terminal;
A second strip line disposed so as to be electromagnetically coupled to the first strip line, wherein a part of a transmission signal propagating from the second power amplifier circuit to the second output terminal is distributed in the first strip line; The transmission apparatus according to claim 1, further comprising: A transmission power detection device for detecting power of a first transmission signal output from a first output terminal or a second transmission signal output from a second output terminal,
A suppression circuit that is provided in a signal path for supplying the first transmission signal to the first output terminal, and suppresses a signal propagating from the first output terminal to the signal path;
A direction that is provided in a signal path for supplying the second transmission signal to the second output terminal, and that part of the signal that propagates from the signal path to the second output terminal is extracted and input to the first terminal. A sex coupling circuit;
A loosely coupled circuit connected between an input terminal of the suppression circuit and the first terminal;
And a rectifier circuit that rectifies and outputs a signal input to the first terminal.

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