KR19980013783U - Transmission device of CDM mobile communication terminal - Google Patents

Abstract

The present invention relates to an improved transmission apparatus capable of improving power efficiency and reducing design cost in a CDMA mobile communication terminal, comprising: a baseband signal processor; Orthogonal converter for converting the I, Q signal transmitted from the modem to the intermediate frequency; A voltage control amplifier for adjusting the gain of the transmission signal output from the quadrature converter; A frequency mixer for converting a signal output from the voltage control amplifier into a transmission frequency; A drive amplifier for amplifying the signal output from the frequency mixer to a predetermined level; A power amplifier for amplifying the signal output from the driving amplifier to another predetermined level; Set the transmission path so that the output of the drive amplifier is transmitted through the power amplifier when the level of the signal to be transmitted is high, and transmit the output of the drive amplifier without passing the power amplifier when the level of the signal to be transmitted is low First transmission means for setting a furnace; And a power detecting means for detecting power by dividing the dynamic range into a high state and a low state.

Description

Transmission device of CDM mobile communication terminal

1 is a main spectrum of a transmission waveform of a code division multiple access (CDMA) scheme.

2 is a block diagram of a conventional transmitter in a CDMA mobile communication terminal.

3 is an input / output characteristic and efficiency characteristic diagram of a power amplifier.

4 is a block diagram of a transmission apparatus according to the present invention in a CDMA mobile communication terminal.

5 is a conceptual diagram of an operating range when a transition state is placed between a high state and a low state.

Explanation of symbols on the main parts of the drawings

400: baseband signal processor 402: quadrature modulator

404: voltage controlled amplifier 407: frequency converter

SW1, SW2, SW3: switch 415: power detection means

The present invention relates to a transmission apparatus provided in a CDMA (Code Division Multiple Access, CDMA) type mobile communication terminal, and more particularly, to a transmission apparatus for improving power efficiency and reducing design cost.

Transmitters provided in CDMA mobile communication terminals require a wide dynamic range of 80 dB or more, unlike conventional analog transmitters using narrowband FM modulation, which have a dynamic range of about 30 dB. Since a vocoder having a variable data rate is used, frequent on / off functions should be performed. In addition, it uses a Quadrature Phase Shift Keying (QPSK) series Linear Modulation modem that modulates both amplitude and phase, so that even if the efficiency is somewhat low, use a power amplifier with excellent linear characteristics or attach a linearizer to the power amplifier. It must be used to satisfy the frequency spectrum of the CDMA transmission waveform as shown in FIG.

2 is a block diagram of a conventional transmission apparatus implemented to satisfy the frequency spectrum of the CDMA transmission waveform as described above, wherein the in-phase (Q) and quadrature-phase (Q) signals generated by the modem are orthogonal modulators. When applied to 301, the quadrature modulator 301 converts the frequency into an intermediate frequency and outputs the frequency. The output signal is attenuated to a level sufficient for power regulation by the attenuator 302.

The attenuated signal is applied to the voltage control amplifier 303, and the power is adjusted in the 80 dB range, and the frequency converter 306 and the frequency synthesizer 305 is frequency-converted to the transmission frequency. At this time, the spurious components are filtered out by appropriate bandpass filtering of the intermediate frequency band and the transmission frequency band using the bandpass filters 304 and 307, and only the desired signal is driven by the driving amplifier 308 and the power amplifier ( 309).

A portion of the power passed by the power amplifier 309 is detected by the directional coupler 310 and is converted into a DC value through the broadband power detector 311 using a diode. The DC voltage output from the power detector 311 is compared with the power control signal output from the baseband signal processor 300 in the comparator CP1, and the compared result adjusts the voltage control amplifier 303.

However, the transmission device configured as described above has some power efficiency when operating near the maximum output power, but when the output signal of the power amplifier 309 is weak by power control, the power efficiency of the transmission device is very low. For example, when a power amplifier having a maximum output of 30 dBm is provided, a signal of -50 dBm must be output by power control. In this case, the efficiency of the power amplifier 309 is characterized by the characteristics of the power amplifier shown in FIG. As shown in the figure, most of the power of the power amplifier 309, which accounts for more than 60% of the total power consumption of the mobile communication terminal within 1%, is wasted. In addition, since the power detector 311 and the voltage control amplifier 303 have to have a high operating range of 80 dB or more, the design cost is increased.

Accordingly, an object of the present invention is to provide an improved transmission apparatus that can improve power efficiency and reduce design cost in a CDMA mobile communication terminal.

A transmission apparatus according to the present invention includes: a baseband signal processor for processing a baseband signal and controlling a transmission gain; A modem for generating I and Q signals; An orthogonal converter for orthogonally modulating the I and Q signals transmitted from the modem to convert to an intermediate frequency; A voltage control amplifier for adjusting the gain of the transmission signal output from the quadrature converter; A frequency mixer for converting a transmission signal output from the voltage control amplifier into a transmission frequency; A drive amplifier for amplifying the signal output from the frequency mixer to a predetermined level; A power amplifier for amplifying the signal output from the driving amplifier to another predetermined level; Controlled by the baseband signal processor, the transmission path is set so that the output of the drive amplifier is transmitted through the power amplifier when the level of the signal to be transmitted is high, and the output of the drive amplifier when the level of the signal to be transmitted is low First transmission means for setting a transmission path to be transmitted without passing through the power amplifier; A directional detector for transmitting a signal output from the first transmission means; Power detection means for converting a signal output from the directional detector into a DC value by dividing the dynamic range into a high state and a low state; When the transmission signal is in the high state, transmits the value of detecting the power in the dynamic range for the high state as a signal for controlling the voltage control amplifier, and detects the power in the dynamic range for the low state when the transmission signal is in the low state. And second transmission means for transmitting one value as a signal for controlling the voltage control amplifier.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a block diagram of a transmission apparatus according to the present invention to be applied to a CDMA mobile communication terminal. When the maximum transmission power is 30 dBm and the dynamic range is 80 dB, the range from 30 dBm to -10 dBm is set to 'high'. Next, an example will be described in which the -50 dBm to -10 dBm is set to a 'low state'.

Referring to FIG. 4, the transmitter includes a baseband signal processor 400, an orthogonal modulator 402 for converting an in-phase signal and a quadrature-phase signal generated from a modem to an intermediate frequency, orthogonal. The attenuator 403 for attenuating the level of the signal output from the modulator 402 to a level sufficient to control the power, and the signal output from the attenuator 403 to the operating range by subtracting the gain of the power amplifier 410 to be described later. A band pass filter 405 and a band pass filter 405 for band filtering the signal output from the voltage control amplifier 404 and the voltage control amplifier 404 for regulating power using a predetermined cutoff frequency. The frequency converter 407 and the signal output from the frequency converter 407 for frequency conversion to the transmission frequency by the signal output from the frequency and the frequency synthesizer 406 by a predetermined cutoff frequency as in the prior artA band pass filter 408 for band filtering, a drive amplifier 409 for amplifying to a predetermined value output from the band pass filter 408, and a power amplifier for amplifying power for a signal output from the drive amplifier 409 410, which is controlled by the baseband signal processor 400 to pass the signal output from the driving amplifier 409 through the power amplifier 410 and bypasses the power amplifier 410 without passing through the power amplifier 410. Directional coupler 411, Directional coupler 411 for detecting some power of the signal output from the first transmission means (SW1, SW2), the first transmission means (SW1, SW2) for transmitting a signal by selecting one The power detected by the power detection means 415 and the baseband signal processor 400 for converting each of the power detected by the high state and low state into a DC value is output from the power detection means 415 signal The voltage control amplifier 403 compares a signal output from the baseband signal processor 400 with a DC voltage transmitted through the second transmission means SW3 and the second transmission means SW3 for selecting and transmitting one. Comparator (CP2) for controlling the.

In the transmission apparatus configured as described above, first, an in-phase (I) signal and a quadrature-phase (Q) signal generated by a modem are transitioned to an intermediate frequency via the quadrature modulator 402. In-phase (I) signals and quadrature-phase (Q) signals may be generated by the baseband signal processor 400. The signal shifted to the intermediate frequency is adjusted by the voltage control amplifier 404 having a dynamic range of about 80 dB according to the power control command of the base station, and converted into a transmission frequency via the frequency mixer 407. When the signal commanded to be transmitted by the base station requires a high output of about -10 dBm to about 30 dBm, the signal passing through the frequency mixer 407 has a high signal level, and thus, the baseband signal processor 400 uses the first transmission means SW1, SW2) is controlled to amplify the signal amplified by the driving amplifier 409 to an appropriate level through the power amplifier 410. Here, the first transmission means (SW1, SW2) is composed of switches provided at the input terminal and the output terminal of the power amplifier 410, respectively. Therefore, when the signal level is high, the signal output from the driving amplifier 409 through the switch SW1 is transmitted to the power amplifier 410, and the signal amplified by the power amplifier 410 is the directional coupler through the switch SW2. 411, and is transmitted to the base station through the antenna 412.

However, if the level of the transmitted signal is sufficiently low, the baseband signal processor 400 controls the switches SW1 and SW2 in the first transmission means because the drive amplifier 409 alone can transmit sufficient power. The output of is transmitted to the antenna 412 directly through the directional coupler 411 without passing through the power amplifier 410.

On the other hand, the power detecting means 415 is a conventional high-power power detector having a dynamic range of about 80dB, but the power detector 413 of the 'high state' having a dynamic range for the range of 30dBm to -10dBm as described above ) And a 'low state' power detector 414 with dynamic range from -50 dBm to -10 dBm to detect power for the signal transmitted from the directional coupler 411.

In the actual operation state of the terminal, fading occurs due to various factors such as reflection, refraction, and diffraction depending on the propagation environment from the base station to the terminal. Therefore, when power is transmitted from the middle point of the high state and the low state of the terminal, the transition between the two states may occur frequently. In this case, when there is no transition state in the section between the high state and the low state as shown in (a) of FIG. 5, the voltage may be caused by sudden on / off of the switches SW1 and SW2 corresponding to the first transmission means. The transmit power of the control amplifier 404 may occur incorrectly. In order to prevent this phenomenon, in the present invention, as shown in (b) of FIG. 5, the transition state is added to the section between the high state and the low state so that the switch does not suddenly switch during the transition state. You can do that. In terms of hardware, the baseband signal processor 400 may be prepared to be designed using the Schmitt trigger circuit and to prepare the terminal transmitter and the state when the Schmitt trigger state stays long. In addition, the baseband signal processor 400 may be programmed to detect a change in signal level and perform a state transition when a sufficient state transition is necessary. Using this concept, the high state and the low state are not exactly distinguished, and there is some overlapping interval.

As described above, the transmission apparatus of the CDA mobile communication terminal according to the present invention can reduce the power loss caused by the power amplifier because the power amplifier does not operate when the transmission signal level is small, and 80dB when the voltage control amplifier is selected. Instead of an amplifier with a high operating range, the operating range of the power amplifier is enough to save the design cost of the voltage-controlled amplifier, and the power amplifier can be distinguished according to the high and low states. This is an inexpensive power detector that can be implemented.

This invention is not limited to the embodiments described so far, it should be understood that various modifications and changes can be made without departing from the technical spirit of the invention. Therefore, the present invention should be determined only by the matters described in the following utility model registration claims.

Claims (3)

A baseband signal processor for processing the baseband signal and controlling transmission gain; A modem for generating I and Q signals; An orthogonal converter for orthogonally modulating the I and Q signals transmitted from the modem to change to an intermediate frequency; A voltage control amplifier for adjusting a gain of a transmission signal output from the quadrature converter; A frequency mixer for converting a transmission signal output from the voltage control amplifier into a transmission frequency; A driving amplifier for amplifying the signal output from the frequency mixer to a predetermined level; A power amplifier for amplifying the signal output from the driving amplifier to another predetermined level; Set a transmission path such that the output of the driving amplifier is transmitted through the power amplifier when the level of the signal to be transmitted controlled by the baseband signal processor is high; and when the level of the signal to be transmitted is low First transmission means for setting a transmission path such that an output of a driving amplifier is transmitted without passing through the power amplifier; A directional detector for transmitting a signal output from the first transmission means; Power detecting means for converting a signal output from the directional detector into a DC value by dividing a dynamic range into the high state and the low state; When the transmission signal is in a high state, transmits a value for detecting power in a dynamic range for a high state as a signal for controlling the voltage control amplifier, and when the transmission signal is in a low state, power in a dynamic range for a low state. And a second transmission means for transmitting the detected value as a signal for controlling the voltage control amplifier. The method of claim 1, The first transmission means is a transmission device of a CDM mobile communication terminal, characterized in that consisting of switches provided at each of the input terminal and the output terminal of the power amplifier. The method of claim 1, The power detecting means includes a first power detector for detecting power with a high dynamic range and a second power detector for detecting power with a low dynamic range. Transmission device of the terminal.