JP2006295522A - Portable telephone terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the number of components in a portable telephone terminal with multi bands which detects a part of transmission power, and controls transmission power based on the detection signal. <P>SOLUTION: The terminal includes a single detection circuit 225 which is used for a 1st and a 2nd transmission circuits, and detects transmission power of the transmission signal, a switch 228 which selectively supplies a part of the transmission power of the 1st and the 2nd transmission circuits to the detection circuit 225, and a control part 230 which switches the switch 228. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a multiband mobile phone terminal corresponding to a plurality of frequency bands.

  Conventionally, in mobile phone terminals, the transmission power of the terminal fluctuates depending on conditions such as temperature characteristics, frequency characteristics, aging, etc., but in order to compensate for these transmission power fluctuations and maintain the desired transmission power, A technique is generally used in which a part of the signal is detected by a detection circuit, and the detection power is fed back to control transmission power (see Patent Document 1).

  In recent years, in order to cope with the effective use of frequencies and the increasing number of subscribers, multiband terminals corresponding to a plurality of frequency bands have attracted attention.

  FIG. 1 shows a configuration of a conventional multiband terminal corresponding to a plurality of frequency bands (band 1 and band 2). This terminal includes a band 1 transmission / reception circuit 110, a band 2 transmission / reception circuit 120, a diplexer 102 and an antenna 101 shared by both transmission / reception circuits, and a control unit 130.

  The transmission / reception circuit 110 includes a variable gain amplifier (AGCAmp) 117, a power amplifier (PA) 116, a directional coupler 114, a detection circuit 115, an isolator 113, a reception circuit 112, and a duplexer 111. Similarly, the transmission / reception circuit 120 includes a variable gain amplifier (AGCAmp) 127, a power amplifier (PA) 126, a directional coupler 124, a detection circuit 125, an isolator 123, a reception circuit 122, and a duplexer 121.

When this terminal performs transmission at a frequency included in band 1, the transmission signal is amplified by variable gain amplifier (AGCAmp) 117 and power amplifier (PA) 116 and transmitted from antenna 101. At this time, a part of the output is taken out by the directional coupler 114 from the rear stage of the PA and detected by the detection circuit 1. The control unit 130 controls the AGC control voltage 1 of the variable gain amplifier 117 based on the detection output 1 output from the detection circuit 115, and is controlled so as to obtain a desired transmission output. On the other hand, when transmitting in the frequency band of band 2, the transmission / reception circuit 120 of band 2 is used, but the operation is the same.
JP-A-10-22841

  In the multiband terminal described above, it is necessary to have a transmission system circuit (including the above-described detection circuit) and a reception system circuit corresponding to each frequency band. Has the disadvantage of being inferior.

  The present invention has been made in such a background, and an object thereof is to reduce the number of components in a multiband mobile phone terminal that detects a part of transmission power and controls the transmission power based on the detection signal. There is to do.

  In order to solve the above problems, the present invention detects a part of its own transmission power by a detection circuit for control of transmission power in a multiband mobile phone terminal corresponding to a plurality of frequency bands, and outputs the detected signal. A mobile phone terminal having a function of controlling transmission power by a plurality of transmission circuits for a plurality of frequency bands so as to share a single detection circuit.

  More specifically, the mobile phone terminal of the present invention is a mobile phone that detects a part of transmission power in a multiband mobile phone terminal corresponding to a plurality of frequency bands and controls the transmission power based on the detection signal. A telephone terminal, which is shared by a first frequency band transmission circuit, a second frequency band transmission circuit, and the first and second transmission circuits, and detects a transmission output of a transmission signal A single detection means, a switch for selectively supplying a part of transmission power of the first and second transmission circuits to the single detection means, and a control means for switching the switch. .

  The single detection means is used for the transmission circuit for the first frequency band during the operation of the transmission circuit for the first frequency band, and the second detection means is used for the transmission circuit for the second frequency band. The switch is switched so as to be used for the transmission circuit for the frequency band.

  The positions of the switches include (1) the front stage of the detection means (detection circuit), (2) the front stage of one of the power amplifiers of the first and second transmission circuits, or (3) the first and second transmission circuits. One stage of the variable gain amplifier is considered. In the latter two cases, an amplifier for a frequency band that is not used is utilized for amplification of the detection signal.

According to the present invention, the following effects can be expected by sharing a detection circuit for transmission power control in mobile phone terminals corresponding to a plurality of frequency bands.
1. Since the necessary number of detection circuits is reduced, the number of parts can be reduced, and the cost and mounting area can be reduced.
2. Detection sensitivity can be improved by using an amplifier for a frequency band that is not used for amplification of a detection signal.
3. Since the detection circuits can be integrated into one, the adjustment process in manufacturing can be simplified.

  Hereinafter, preferred embodiments of the present invention will be described in detail.

  In the present invention, in a mobile phone terminal that supports a plurality of frequency bands (for example, 2 GHz and 800 MHz), the transmission circuit for a plurality of frequency bands shares one detection circuit, so that the number of components used as the detection circuit and the mounting area are increased. This is to realize a reduction in energy consumption.

  FIG. 2 shows a configuration example of the mobile phone terminal according to the first embodiment of the present invention.

  The transmission / reception circuit 210 includes a variable gain amplifier (AGCAmp) 217, a power amplifier (PA) 216, a directional coupler 214, an isolator 213, a reception circuit 212, and a duplexer 211. The transmission / reception circuit 220 includes a variable gain amplifier (AGCAmp) 227, a two-input one-output switch 228, a power amplifier (PA) 226, a directional coupler 224, a detection circuit 225, an isolator 223, a reception circuit 222, and a duplexer 221. The detection circuit 225 is included only on the transmission / reception circuit 220 side and is shared with the transmission / reception circuit 210. Therefore, the output branched from the directional coupler 214 in the transmission / reception circuit 210 is input to one input terminal of the switch 228. The output of the variable gain amplifier 227 is input to the other input terminal of the switch 228. The output of the switch 228 is input to the power amplifier 226. Switching of the switch 228 is performed according to a control signal from the control unit 230.

  When this terminal transmits at a frequency included in band 1, the transmission signal is amplified by a variable gain amplifier (AGCAmp) 217 and a power amplifier (PA) 216, and passes through a directional coupler 214, an isolator 213, and a duplexer 211. It is transmitted from the antenna 201. The directional coupler 214 is used to extract a part of the output signal of the power amplifier 216 at a ratio such as 1/10 or 1/20.

  Although not directly related to the present invention, the isolator 213 is for making it difficult to see the change in impedance on the antenna side from the power amplifier 216 in order to stabilize the operation of the power amplifier 216. The duplexer 211 is a circuit for sharing the antenna 201 for transmission / reception operations of the transmission circuit and the reception circuit 212. The diplexer 202 is a circuit for separating the signals of the two bands and sharing the antenna 201. In FIG. 2, the switch 228 is used to switch the input to the power amplifier 226, but other means such as a diplexer or a coupling by a capacitor may be used. The same applies to configuration examples of other embodiments described later.

  The signal extracted by the directional coupler 214 at the rear stage of the band 1 power amplifier 216 is input to the switch 228 as described above, and further extracted by the directional coupler 224 via the band 2 power amplifier 226 for detection. Input to the circuit 225. Based on this detection output, control unit 230 generates AGC control voltage 1 to variable gain amplifier 217, and controls the gain of variable gain amplifier 217 so as to obtain a desired transmission output. When the band 1 transmission / reception circuit 210 operates, the switch 228, the power amplifier 226, the directional coupler 224, and the detection circuit 225 of the band 2 transmission / reception circuit 220 also need to be in operation, but the variable gain amplifier 227 May be in a non-operating state.

  The operation of the band 2 transceiver circuit 220 is the same, but the feedback control of the variable gain amplifier 227 during the band 2 operation is completed by the band 2 transceiver circuit 220 alone, and the band 1 transceiver circuit 210 is in an inoperative state. And

  2 eliminates the need for a circuit corresponding to the detection circuit 115 in FIG. Further, since the signal used for detection of band 1 is amplified by the power amplifier 226, the detection output output from the detection circuit 225 is increased, and there is an advantage that the detection sensitivity can be increased. This configuration is suitable when the power amplifier 216 on the band 1 side has a smaller gain than the power amplifier 226 on the band 2 side.

  FIG. 3 shows a configuration example of the second embodiment of the mobile phone terminal according to the present invention. The difference of the second embodiment from the first embodiment is the position of the switch.

  The transmission / reception circuit 310 in the present embodiment includes a variable gain amplifier (AGCAmp) 317, a power amplifier (PA) 316, a directional coupler 314, an isolator 313, a reception circuit 312, and a duplexer 311. This configuration is the same as that of the transmission / reception circuit 210 of the first embodiment.

  On the other hand, the transmission / reception circuit 320 includes a two-input one-output switch 328, a variable gain amplifier (AGCAmp) 327, a power amplifier (PA) 326, a directional coupler 324, a detection circuit 325, an isolator 323, a reception circuit 322, and a duplexer 321. Including. As in the first embodiment, the detection circuit 325 is included only on the transmission / reception circuit 320 side, and is shared with the transmission / reception circuit 310. However, unlike the first embodiment, the switch 328 is provided before the variable gain amplifier 327. That is, the output branched from the directional coupler 314 in the band 1 transmission / reception circuit 310 is input to one input terminal of the switch 328 provided in front of the variable gain amplifier 327. A transmission signal of band 2 is input to the other input terminal of the switch 328. The output of the switch 328 is input to the variable gain amplifier 327. Switching of the switch 328 is performed according to a control signal from the control unit 330.

  According to the configuration example of FIG. 3, since the transmission output of both bands is controlled using a single detection circuit as in the configuration example of FIG. 2, one detection circuit can be omitted. Further, in this configuration, the detection signal branched from the power amplifier 316 is amplified by both the variable gain amplifier 327 and the power amplifier 326, so that a greater detection sensitivity can be obtained compared to the configuration example of FIG. it can.

  FIG. 4 shows a configuration example of the third embodiment of the cellular phone terminal according to the present invention. In the third embodiment, the switch is installed in another position. In other words, in this configuration example, a switch is arranged in front of the detection circuit.

  Specifically, the transmission / reception circuit 410 in the present embodiment includes a variable gain amplifier (AGCAmp) 417, a power amplifier (PA) 416, a directional coupler 414, an isolator 413, a reception circuit 412 and a duplexer 411. This configuration is the same as the transmission / reception circuits 210 and 310 of the first and second embodiments.

  On the other hand, the transmission / reception circuit 420 includes a two-input one-output switch 428, a variable gain amplifier (AGCAmp) 427, a power amplifier (PA) 426, a directional coupler 424, a detection circuit 425, an isolator 423, a reception circuit 422, and a duplexer 421. Including. As in the first and second embodiments, the detection circuit 425 is included only on the transmission / reception circuit 420 side and is shared with the transmission / reception circuit 410. However, unlike the first and second embodiments, the switch 428 is provided in front of the detection circuit 425. That is, the output branched from the directional coupler 414 in the transmission / reception circuit 410 in the band 1 is input to one input terminal of the switch 428 provided in the preceding stage of the detection circuit 425. The branch output of the band 2 directional coupler 424 is input to the other input terminal of the switch 428. The output of the switch 428 is input to the detection circuit 425. Switching of the switch 428 is performed according to a control signal from the control unit 430.

  In the configuration example of FIG. 4, since the branch output of the directional coupler 414 in band 1 is directly input to the detection circuit, the detection sensitivities in band 1 and band 2 are equivalent. This configuration is particularly suitable when it is not necessary to increase the detection sensitivity of one band.

  The preferred embodiments of the present invention have been described above, but various modifications and changes other than those mentioned above can be made. For example, in the above description, a terminal corresponding to two frequency bands is taken as an example, but a single detection circuit can be shared in the same manner even when corresponding to three or more frequency bands.

It is a circuit block diagram which shows the structure of the conventional multiband terminal corresponding to several frequency bands (band 1 and band 2). 1 is a circuit block diagram showing a configuration example of a mobile phone terminal according to a first exemplary embodiment of the present invention. It is the circuit block diagram which showed the structural example of the mobile telephone terminal which concerns on 2nd Embodiment by this invention. It is the circuit block diagram which showed the structural example of the mobile telephone terminal which concerns on 3rd Embodiment by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 201 ... Antenna, 202 ... Diplexer, 210 ... Transmission / reception circuit, 211 ... Duplexer, 212 ... Reception circuit, 213 ... Isolator, 214 ... Directional coupler, 216 ... Power amplifier, 216 ... Power amplifier, 217 ... Variable gain amplifier, 220 Transmission / reception circuit, 221 Duplexer, 222 Reception circuit, 223 Isolator, 224 Directional coupler, 225 Detection circuit, 226 Power amplifier, 227 Variable gain amplifier, 228 Switch, 230, Control unit, 310 Transmission / reception circuit, 311 ... Duplexer, 312 ... Reception circuit, 313 ... Isolator, 314 ... Directional coupler, 316 ... Power amplifier, 320 ... Transmission / reception circuit, 321 ... Duplexer, 322 ... Reception circuit, 323 ... Isolator, 324 ... Direction Sex coupler, 325 ... detection circuit, 326 ... electric power Width device, 327... Variable gain amplifier, 328... Switch, 330. Duplexer, 422 ... receiving circuit, 423 ... isolator, 424 ... directional coupler, 425 ... detector circuit, 428 ... switch, 430 ... control unit

Claims (5)

In a multiband mobile phone terminal corresponding to a plurality of frequency bands, a mobile phone terminal that detects a part of transmission power and controls transmission power based on the detection signal,
A transmission circuit for a first frequency band;
A transmission circuit for the second frequency band;
A single detection means shared by the first and second transmission circuits for detecting the transmission output of the transmission signal;
A switch for selectively supplying a part of transmission power of the first and second transmission circuits to the single detection means;
And a control means for switching the switch.   2. The mobile phone terminal according to claim 1, wherein the switch is arranged in front of the detection means.   2. The first and second transmission circuits each include a power amplifier, and the switch is disposed in front of one of the power amplifiers of the first and second transmission circuits. Mobile phone terminals.   The first and second transmission circuits each include a variable gain amplifier, and the switch is arranged in front of one of the variable gain amplifiers of the first and second transmission circuits. 1. The mobile phone terminal according to 1.   In a multi-band mobile phone terminal supporting multiple frequency bands, a mobile phone having a function of detecting a part of its own transmission power by a detection circuit for controlling transmission power and controlling the transmission power by the detection output A mobile phone terminal, characterized in that a single detection circuit is shared by a plurality of transmission circuits for a plurality of frequency bands.

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