KR100301020B1 - Transmission apparatus of dual mode communication device - Google Patents

Abstract

The present invention relates to a transmission device of a dual mode communication device that minimizes current consumption in data transmission by adaptively operating a supply current of a drive amplifier for each mode and output power.

The transmission device according to the present invention comprises a drive amplifier for amplifying the output of the upconverter; And a drive amplifier current controller configured to vary a supply current of the drive amplifier in response to a transmission power control signal generated by the baseband processor.

The transmitting device according to the present invention controls the current consumption according to the output, and this control is different in the case of CDMA and AMPS, so that the drive amplifier and power in the AMPS mode more effectively in the structure of sharing the drive amplifier in CDMA and AMPS It has the effect of reducing the current consumption of the amplifier.

Description

Transmission apparatus of dual mode communication device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission apparatus of a dual mode communication device. In particular, the CDMA / AMPS dual mode communication device adaptively operates a supply current of a drive amplifier for each mode and output power, thereby minimizing current consumption during data transmission. Relates to a device.

In the United States, the digital cellular radio access standard is based on the Time Division Multiple Access (TDMA) technology and the Code Division Multiple Access (CDMA) method, respectively, according to the Telecommunications Industry Association (TIA). Provisionally standardized to -54 (interim standard 54) and IS-95. In both specifications, the existing analog cellular system is designed to be compatible with the AMPS (Advanced Mobile Phone Service) system in the same frequency band, and thus the terminal or the base station can operate in dual mode.

The structure of a transmission device in a dual band (CDMA & AMPS) mobile communication terminal that is currently commercialized is shown in FIG. In the apparatus shown in FIG. 1, data output from the baseband processor 101 is input to a modulator 103, and a signal modulated through the modulator 103 is an auto gain controller (hereinafter referred to as AGC). Is amplified to have a predetermined level.

This amplified signal is input to the mixer 107 for up-converter to raise to the transmission frequency band. This signal is frequency converted by the carrier generated in the local oscillator 109 to the transmission frequency band. The signal frequency-converted by the up-converter 107 is filtered by the band pass filter 111 and then amplified by the drive amplifier 113 and again by the power amplifier 115 and then the band pass filter to control unnecessary noise. It propagates through the antenna 119 via 117.

The CDMA scheme controls the transmit power of each terminal so that the power of the signals received at the base station is about the minimum received power necessary for the base station to correctly demodulate the received signals to make the maximum possible call state. This transmission power control is performed by the terminal itself or by a command from the base station. In the apparatus shown in FIG. 1, control of the transmit power is performed by the AGC 108. In the case of commercial CDMA, the output power control range is about 80 dB, so the AGC 108 generally has a gain characteristic of +45 dB / -45 dB.

In CDMA, drive amplifiers and power amplifiers are required to have sufficient linearity at high outputs. Because CDMA is a PSK method, if sufficient linearity cannot be guaranteed, the transmission phase is changed, which can change the content of the data, making it impossible to reproduce.

In contrast, AMPS does not need to maintain linearity at high power. Because the AMPS method is an FM transmission method, even if distortion occurs in the transmission data, it becomes a distortion of the received voice and is not lost.

In the apparatus shown in Fig. 1, the drive amplifier and the power amplifier are set to have sufficient linearity in the CDMA mode.

In the case of CDMA, since the output power control range is 80 dB, the transmission power control is performed by the IF AGC amplifier 105, and the drive amplifier 113 and the power amplifier 115 operate with a fixed gain and a fixed current consumption. In this case, high output power is not a problem, but when transmitting low power, the drive amplifier operates with a fixed current consumption, thereby consuming unnecessary current.

The present invention has been made to solve the above problems, and an object thereof is to provide an apparatus which prevents unnecessary consumption of power by operating adaptively according to a use mode and an output power.

1 is a block diagram showing the configuration of a conventional dual mode communication device.

2 is a block diagram showing a configuration of a dual mode communication device according to the present invention.

FIG. 3 is a block diagram illustrating a detailed configuration of the drive amplifier and the drive amplifier current controller shown in FIG. 2.

FIG. 4 is a graph showing current characteristics of the drive amplifier shown in FIG. 3 and illustrates a relationship between a transmission power control signal and a bias current.

FIG. 5 is a graph showing the current characteristics of the drive amplifier shown in FIG. 3 and shows a relationship between a transmission power control signal and saturation power.

A transmission apparatus according to the present invention which achieves the above object is a dual mode transmission apparatus corresponding to the CDMA method and the AMPS method, and includes a transmission power for adjusting a transmission output level of the transmission device in response to a transmission power control command from a base station or the like. A baseband processor generating a mode signal according to a control signal and a transmission mode and generating a baseband digital signal; A modulator for modulating the digital signal generated by the baseband processor; An automatic gain controller controlling a gain of a signal generated by the modulator in response to a transmit power control signal generated by the baseband processor; An up-converter for converting a frequency band of the signal generated by the automatic gain controller into a frequency of a transmission band; A drive amplifier for amplifying the output of the upconverter; A drive amplifier current controller configured to vary a supply current of the drive amplifier in response to a transmission power control signal generated by the baseband processor; And an antenna for transmitting the output of the drive amplifier. Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing the configuration of a transmission apparatus according to the present invention. In the apparatus illustrated in FIG. 2, apparatuses that perform the same operations as those illustrated in FIG. 1 are denoted by the same reference numerals, and detailed operation description thereof will be omitted. The apparatus shown in FIG. 2 further includes a drive amplifier current controller 203 and a power amplifier current controller 205 as compared to the apparatus shown in FIG.

The drive amplifier current controller 203 varies the current of the drive amplifier 201 according to the RF_AGC signal and the mode signal generated by the baseband processor 101. In addition, the power amplifier current controller 205 varies the current of the power amplifier 207 according to the RF_AGC signal and the mode signal generated by the baseband processor 101.

The apparatus shown in FIG. 2 can be roughly divided into an IF portion and an RF portion. The IF portion has a so-called intermediate frequency amplification frequency band as a portion up to the AGC 105, while the RF portion is a portion having a transmission frequency band as a portion after the up converter 107.

The transmission power is controlled by dividing the power control signal of the IF part and the power control signal of the RF part according to the transmission power control signal. That is, the IF_AGC signal is modified in accordance with the control characteristics of the AGC 105, and the RF_AGC signal is modified in accordance with the control characteristics of the drive amplifier 201 and the power amplifier 115.

The operation of the apparatus shown in FIG. 2 is as follows. The baseband processor 101 generates an IF_AGC signal and an RF_AGC signal in response to the transmission power control signal transmitted from the base station in case of CDMA. These AGC signals are signals for controlling the transmission power in response to the transmission power control commanded by the base station.

The drive amplifier current controller 203 controls the drive current of the drive amplifier 201 in response to the RF_AGC signal generated by the baseband processor 101. The power amplifier current controller 205 controls the driving current of the power amplifier 115 in response to the rf_AGC signal generated by the baseband processor 101.

As described above, the apparatus illustrated in FIG. 3 operates adaptively by controlling the driving current according to the mode signal and the output power in the AGC 108 as well as the drive amplifier and the power amplifier.

3 is a circuit diagram showing a detailed configuration of the drive amplifier and drive amplifier current control unit 203 shown in FIG.

In FIG. 3, the drive amplifier 201 is composed of a self-biased class A amplifier. The drive amplifier current controller 203 includes a first transistor 309 connected in parallel to the base side of the drive amplifier 201 and a second transistor 307 connected in parallel to the base side of the first transistor 309. .

The input signal provided from the band pass filter 111 of FIG. 2 is connected to the amplifying transistor 319 through an input matching unit 307, and resistors 313 and 315 are provided at the base of the amplifying transistor 319. The input matching unit 321 is connected to the connection point of the resistors 313 and 315. An emitter terminal of the bias control transistor 309 is connected to the other side of the resistor 313, and a resistor 311 is connected between the emitter of the transistor 309 and the collector. A resistor 301 is connected between the terminal that receives the RF_AGC and the base of the bias control transistor 309. Again, resistor 303 is connected to the emitter of PNP transistor 307, the MODE terminal is connected to the base of transistor 307 through resistor 305, and the collector terminal of transistor 307 is grounded. The output matching unit 303 is connected to the collector of the transistor 319 to output a signal.

The operation of the apparatus shown in FIG. 3 will be described in detail. In FIG. 3, RF_AGC and MODE signals, which are control signals output by the baseband processor 101, are input to the drive amplifier current controller 203, and the drive amplifier current controller 203 controls the current of the drive amplifier 201. .

Such current control is controlled by mode (CDMA / AMPS) and by output power. For CDMA the mode signal goes high and for AMPS the mode signal goes low. When the mode signal goes high, the transistor 307 turns off and operates as if there is no transistor 307. The RF_AGC signal is then input directly to the base of the transistor 309 via a resistor 301. For example, if the transistor 309 is not operating, and it is assumed that a voltage of 1V is applied to the emitter of the transistor 309, the voltage of RF_AGC applied to the base of the transistor 309 becomes 1.7V or more. The transistor 309 does not operate until it is.

Therefore, the voltage applied to the base of the amplifying transistor 319 is divided by the resistors 311, 313, and 315, so that the current consumption of the transistor 319 is reduced.

However, when the RF_AGC voltage exceeds 1.7V, the emitter voltage of the transistor 309 increases. When the voltage increases in this way, the current flowing into the base of the transistor 319 increases, and eventually, the collector current of the transistor 319 increases. As described above, the current consumption of the drive amplifier 105 increases in the CDMA mode when the TX_AGC voltage (power control signal at the transmitter level) exceeds V1. As the current increases, the saturation power of the transistor 319 also increases. Therefore, if the output of the drive amplifier 201 is used lower than the saturation power, the case where the drive amplifier 201 is saturated does not occur.

Since the CDMA mode requires linearity, in the case of the drive amplifier 201, it is preferable to use saturation power 6 dB or more than the output power.

In the AMPS mode, since the transistor 307 is turned on, the voltage applied to the base of the transistor 309 is divided by the RF_AGC voltage by the resistors 301 and 303. Therefore, as shown in FIG. 4, when the TX_AGC voltage is greater than V2, the transistor 309 is turned on so that the current consumption of the drive amplifier 201 increases when the TX_AGC voltage is greater than V2.

Therefore, as shown in FIG. 5, the saturation power increases only when the output of the drive amplifier 201 becomes P2 or more in the AMPS mode. Therefore, the saturation power increases when the output of the drive amplifier 201 becomes more than P2 in the AMPS mode. Therefore, when the output of the drive amplifier 201 is p3, the saturated power becomes Psat1 in the AMPS mode and Psat2 in the CDMA mode.

In this manner, the saturation power of the drive amplifier 201 is slightly larger than the output in the AMPS mode and is considerably larger in the CDMA mode.

This is because AMPS has a modulation scheme of FM, so there is no problem in performance even if the output is close to saturation power, but CDMA requires some linearity because the modulation scheme is PSK.

Likewise, controlling the current consumption of the drive amplifier by mode and output may be applied to the power amplifier as well.

As described above, the transmitting device according to the present invention controls the current consumption in accordance with the output, and this control is more effective in the AMPS mode in a structure in which the drive amplifier is shared between the CDMA and the AMPS by controlling the difference between the CDMA and AMPS cases. The current consumption of the drive amplifier and power amplifier can be reduced.

Claims (2)

A baseband processor for generating a transmission power control signal for adjusting a transmission power level of a transmission device and a mode signal according to a transmission mode in response to a transmission power control command from a base station, and for generating a baseband digital signal; A modulator that modulates a digital signal generated by a signal, an automatic gain controller that controls a gain of a signal generated by the modulator in response to a transmit power control signal generated by the baseband processor, and a frequency band of the signal generated by the automatic gain controller An up-converter for converting a frequency into a frequency of a transmission band, a drive amplifier for amplifying an output of the up-converter, a drive amplifier current controller in which a supply current of the drive amplifier varies in response to a transmission power control signal generated by the baseband processor, The dry In the dual mode transmission apparatus corresponding to the CDMA method and the AMPS method including an antenna for transmitting the output of the amplifier, The drive amplifier includes an amplifying transistor and a bias resistor for providing a bias current to the amplifying transistor, The drive amplifier current control unit includes a bias control transistor connected in parallel to the bias resistor and a blocking transistor connected in parallel between a control signal input terminal of the bias control transistor and a ground potential, And the transmission power control signal is applied to a control signal input terminal of the bias control transistor and the mode signal is applied to a control signal input terminal of the blocking transistor. The transmission device according to claim 1, wherein the blocking transistor reduces the size of the transmission power control signal according to the mode signal.