KR100456118B1 - Device for controlling an output of a high-power amplifier in a mobile communication terminal, specifically concerned with compensating for a transmission output by detecting an output level of the high-power amplifier - Google Patents

Abstract

PURPOSE: A device for controlling an output of a high-power amplifier in a mobile communication terminal is provided to compensate for a transmission output by detecting an output level of a high-power amplifier, thereby preventing a call disconnection caused by the deterioration of a transmission output level while suppressing power consumption caused by an excessive output. CONSTITUTION: An output level detector(270) detects an output level of a high-power amplifier(232). A logic unit(260) consists of a memory(261) for storing preset fixed data to compare with the detected output level and a register(262) for storing a control command for output gain controlling. A gain controller(280) comprises as follows. FETs for a switch use receive control signals of the logic unit(260) as each input to control an output gain of the high-power amplifier(232), and wherein a reference voltage is applied to commonly connected sources. A plurality of power dividing resistances supply driving voltages to the FETs by dividing the reference voltage, and control an output level of the control signal.

Description

Output control device of high power amplifier of mobile communication terminal

The present invention relates to a mobile communication terminal. In particular, the present invention provides a high output amplifier that detects an output level of a high output amplifier and compensates the transmission output constantly, thereby preventing power loss due to a drop in transmission output level or an excessive output. The present invention relates to a mobile communication terminal.

Conventionally, as one of the code division multiple access (CDMA) mobile wireless communication systems, there is a cellular mobile wireless telephone system, which has a control station connected to a wired telephone network and a control line connected to the control station via a wired line, respectively. It consists of a plurality of connected base stations and mobile communication terminals which are a plurality of mobile stations. Each base station forms a radio zone of a different area. The mobile communication terminal is connected to a device station in a wireless zone where its own station is located via a wireless line, and is connected to a wireline telephone network from the base station via a control station.

In addition, the system allows each base station and a mobile communication terminal to share a plurality of radio frequencies, to select their radio frequencies at the time of call or call so that they can be wirelessly connected to the base station. For example, if a hook switch is turned on to make a call in a mobile communication terminal, the mobile communication terminal first selects a control radio frequency, and also includes an origination call containing its own identification code. Generate a signal. The transmission signal is then sent to the radio base station via the control channel established by the control radio frequency. At this time, the radio base station monitors the occurrence of a call through the control channel when waiting for reception, and generates a call signal including an identification code of the mobile station and its own station when an outgoing signal arrives from the mobile communication terminal in this state. It is sent to the control station.

The control station determines whether the call is from its own system using an identification code included in the call signal, and if the call is from the own system, selects an empty radio frequency from among a plurality of radio frequencies for communication owned by the system, A call response signal containing information for specifying this radio frequency (call channel designation information) is returned to the base station. When the call response signal is returned from the control station, the base station generates an outgoing response signal including call channel designation information and an identification code of the caller's mobile communication terminal, and sends the signal to the mobile communication terminal using the control channel. Send. At this time, when the mobile communication terminal receives the outgoing response signal, training is performed for establishing a communication channel by the radio frequency with the base station according to the communication channel designation information included in the signal. When a call channel is established by training, a call signal is sent from the control station to the wired telephone network.

When the call signal of the wired telephone network is sent as described above, the wired telephone network transmits a signal requiring the transmission of the dial signal to the caller's mobile communication terminal via the control station and the base station. The mobile communication terminal indicates that the dial operation is enabled when the call request for the dial signal arrives. If the caller who confirms this indication enters the dialing number of the call counterpart by the dial key, the mobile communication terminal displays the dial number. The corresponding dial signal is transmitted to the base station through the wireless call channel. When the radio base station receives the dial signal, the dial signal is transmitted to the wired telephone network through the control station. Therefore, the exchange operation is performed in the wired telephone network, whereby the counterpart telephone which desires a call is called. When the other party's call is answered off-hook to the call, a call path is formed between the other party's phone and the caller's mobile communication terminal. You can make calls between them.

In this type of conventional wireless communication system, a mobile communication terminal of a mobile station is configured as shown in the block circuit diagram of FIG. 1, and a schematic circuit configuration will now be described with reference to this drawing. First, a dual structure antenna 110, a dual band filter 120 for preventing mutual interference of the transmission and reception signals, a reception signal low noise amplifier 121 for amplifying the reception signal, and a low noise amplified reception signal A reception signal high frequency mixer 123 for mixing the received signal high frequency band filter 122 for filtering, and a local frequency output from the local frequency oscillator 140 to the low noise signal filtered by the high frequency band filter 122; The received signal intermediate frequency band filter 124 for filtering the intermediate frequency from the mixed high frequency signal, the received signal automatic gain controller 125 for automatically adjusting the gain of the received signal, A transmission signal automatic gain controller 136 for automatically adjusting the gain, a transmission signal high frequency mixer 135 for mixing the transmission signal with the local frequency output from the local frequency oscillator 140, and transmission A transmission signal high frequency band filter 134 for filtering the interfrequency, an ultra short amplifier 133 for amplifying the gain of the high frequency signal, a power amplifier 132 for amplifying the high frequency signal to the maximum output level, and a reverse signal. An isolator 131 for separating, and a local band frequency oscillator 140, local band buffers 141 and 142, a baseband converter 150 for converting intermediate transmission and reception frequencies into analog and digital signals, and And a logic unit 160 which modulates and demodulates the signal converted by the baseband converter 150 to perform a desired control process.

The conventional mobile communication terminal as described above has a received signal low noise amplifier for amplifying a received signal through a dual band filter 120 for preventing mutual interference between transmitted and received signals by a signal received through the antenna 110 at the time of reception. (121), after passing through the received signal high frequency band filter 122 for filtering the low noise amplified received signal, the local frequency oscillator (12) to the low noise signal filtered by the high frequency band filter 122 in the received signal high frequency mixer 123 ( Local frequency output from 140 is mixed to generate an intermediate frequency, and the received signal intermediate frequency band filter 124 for filtering the intermediate frequency from the mixed high frequency signal of the local frequency and the gain of the received signal automatically. Control the desired signal by modulating and demodulating the signal converted by the baseband converter 150 through the baseband converter 150 through the automatic gain controller 125 for adjusting the received signal. It is recovered from the logic unit 160 to perform a re-received data.

On the other hand, during transmission, the transmission signal modulated by the logic unit 160 performing modulation and demodulation and control processing is passed through the baseband converter 150, and the transmission signal automatic gain controller 136 for automatically adjusting the gain of the transmission signal, After generating the high frequency signal through the transmission signal high frequency mixer 135 for mixing the local frequency output from the local frequency oscillator 140 with the transmission signal, and removes the unwanted wave in the transmission signal high frequency band filter 134, After amplifying the amplifier 133 and the high power amplifier 132 to an output suitable for transmission to the mobile communication terminal, the separator 131 for separating the reverse signal, the dual band filter 120 and the antenna 110 through It is transmitted to the mobile communication terminal. In this case, the high output amplifier 132 transmits a constant output signal in proportion to the input signal, and generally has a high gain of about 24 dB to 28 dB.

However, the gain of the conventional high power amplifier 132 is about 30% of the input signal, and the gain decreases over time due to high heat generation, and thus, the same output cannot be maintained continuously. Not only there is a problem, but even in a situation where a relatively low output level is required, since the high output level is constantly output, there is a problem that battery power consumption of the mobile communication terminal increases.

The present invention has been made in view of the above-described problems of the prior art, and detects the output level of a high output amplifier and compensates the transmission output uniformly, thereby preventing power loss due to a disconnection of the transmission output level or overpowering. The purpose is to provide a mobile communication terminal that can be.

The mobile communication terminal of the present invention for achieving the above object, in the mobile communication terminal of the code division multiple access method comprising a high output amplifier having a constant output gain in proportion to the input signal, detecting the output level of the high output amplifier A logic unit including an output level detector for adjusting the gain of the high output amplifier, a memory for storing predetermined fixed data, and a register for storing a control command for controlling output gain. It is characterized in that the transmission output of the mobile communication terminal is constantly compensated.

1 is a block circuit diagram showing the configuration of a conventional mobile communication terminal;

2 is a block circuit diagram of a mobile communication terminal of the present invention;

3 is a block circuit diagram of a high output amplifier output level detection unit of a mobile communication terminal according to the present invention;

4 is a circuit diagram of a mobile communication terminal control unit according to the present invention.

*** Explanation of symbols for main parts of drawing ***

110,210: Antenna 120,220: Dual Band Filter

121,221: Low noise amplifier 122,222,134,234: High frequency band filter

123,223: High frequency mixer 124,224: Intermediate frequency band filter

125,225,136,236: Automatic gain controller 150,250: Baseband converter

160,260: logic section 131,231: separator

140,240: Local frequency oscillator 135,235: High frequency mixer

132,232: High Power Amplifier 133,233: Ultra Short Amplifier

270: output level detector 280: gain control unit

261 memory 262 registers

Hereinafter, an embodiment of a mobile communication terminal according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block circuit diagram of a mobile communication terminal of the present invention, FIG. 3 is a block circuit diagram of a high output amplifier output level detector of a mobile communication terminal according to the present invention, and FIG. 4 is a circuit diagram of a mobile communication terminal control unit according to the present invention.

First, referring to FIG. 2, the components of the mobile communication terminal according to the present invention will be described. The antenna 210 of the dual structure, the dual band filter 220 for preventing mutual interference of the transmission and reception signals, and the low noise of the received signal. A local frequency oscillator 240 to the received signal low noise amplifier 221 for amplifying, the received signal high frequency band filter 222 for filtering out the low noise amplified received signal, and the low noise signal filtered by the high frequency band filter 222. The received signal high frequency mixer 223 for mixing the local frequencies output from the signal, the received signal intermediate frequency band filter 224 for filtering the intermediate frequency from the high frequency signal mixed with the local frequency, and the gain of the received signal. Receiving signal automatic gain controller 225 for automatically adjusting, the transmission signal automatic gain controller 236 for automatically adjusting the gain of the transmission signal, and the local frequency oscillator 240 to the transmission signal A transmission signal high frequency mixer 235 for mixing local frequencies outputted from the transmitter, a transmission signal high frequency band filter 234 for filtering the intermediate frequency of transmission, an ultra short amplifier 233 for amplifying the gain of the high frequency signal, and a high frequency Gain of the power amplifier 232 for amplifying the signal to the maximum output level, the separator 231 for separating the reverse signal, the output level detector 270 for detecting the output level of the high output amplifier 232, and the high output amplifier. A gain control unit 280 for adjusting, a local band frequency oscillator 240, local band buffers 241 and 242, a baseband converter 250 for converting intermediate transmission and reception frequencies into analog and digital signals, and the base And a logic unit 260 which modulates and demodulates the signal converted by the band converter 250 to perform a desired control process.

The logic unit 260 includes an E ² PROM (Electrical Erasable Programmable Read Only Memory) 261 for storing predetermined and fixed data, and a register 262 for storing control commands for controlling hardware.

The output level detector 270 for detecting the output level of the high output amplifier will be described with reference to the block circuit diagram shown in FIG. 3. The reference power supply 271, the input DC current blocking capacitor 272, and the detection diode unit ( 272, an RC filter 274 for noise reduction, and an amplifier 275.

Looking at the gain control unit 280 in more detail with reference to Figure 4, it is composed of a power split resistor (281, 282, 283) and a switch FET transistor (283, 284).

Looking at the operation of the mobile communication terminal of the present invention having the above-described configuration, the receiver is a received signal low noise amplifier for amplifying the received signal through the dual-band filter 220, the signal received by the transmission and reception antenna 210 as in the prior art ( 221, the received signal high frequency bandpass filter 222 for filtering the low noise amplified received signal, and then a local frequency oscillator 240 to the low noise signal filtered by the high frequency band filter 222 in the received signal high-frequency mixer 223 Local frequency outputted from) is mixed to generate an intermediate frequency, and the received signal intermediate frequency band filter 224 and the gain of the received signal are automatically adjusted to filter the intermediate frequency from the mixed high frequency signal. The received signal automatic gain controller 225 through the baseband converter 250 through the baseband converter 250 modulates and demodulates the desired signal It is restored to the received data from the logic unit 260 to perform processing.

On the other hand, during transmission, the transmission signal modulated by the logic unit 260 performing modulation and demodulation and control processing passes through the baseband converter 250, and the transmission signal automatic gain controller 236 automatically adjusts the gain of the transmission signal. After generating a high frequency signal through the transmission signal high frequency mixer 235 for mixing the local frequency output from the local frequency oscillator 240 with the transmission signal, and removes the unwanted wave in the transmission signal high frequency band filter 234, After passing through the amplifier 233, it is transferred to the high power amplifier 232. At this time, the high output amplifier 232 is controlled and compensated for the output by the gain control unit 280 and the output level detector 270, the signal is a separator 231 for separating the reverse signal and the dual band filter 220 And through the antenna 210 to the mobile communication terminal.

At this time, the operation of the gain control unit 280 is as follows. Since the gain of the high output amplifier 232 is determined by the control voltage, the power split resistors 281, 282, and 283 are all turned on in the case of the low output, and controlled by R1 // R2 // R3. In this case, only R2 and R3 of the power split resistor are turned on to control R2 // R3, and in the case of high output, gain is controlled by adjusting the voltage drop from the reference voltage using only R2.

When outputting a high output using only R2 among the power split resistors, the output of the high output amplifier 232 is deteriorated due to heat generation and efficiency deterioration. At this time, the output is detected by the output level detector 270 to maintain the same output.

The output level detection unit 270 receives only the AC signal through the unnecessary DC blocking capacitor 272 at the output terminal of the high output amplifier 232 and merges the DC current of the reference power supply unit 271 with the output level detection diode unit 273. ) Detects an AC signal carried on the DC signal, converts it into a DC signal in the RC filter unit 274, and amplifies the DC variable displacement in the amplifier 275. At this time, the level of the transmission output level corresponding to the DC value is stored in the E ² PROM 261 included in the logic unit 260. The DC level is read from the input / output register 262 to read the E ² PROM ( Comparing the data stored in 261 with the transmission signal automatic gain regulator 236 to increase the output when the output drops. In the same way, when the output is higher than the required level, the output can be reduced by using the output level detector 270.

According to the mobile communication terminal provided with the output level compensation circuit of the high output amplifier according to the present invention described above, the high power amplifier output level of the mobile communication terminal is detected by compensating the transmission output uniformly, so that the call according to the decrease in the transmission output level Disconnection can be prevented, and the power consumption due to the overpower of the high power amplifier can be prevented, thereby greatly reducing the battery consumption of the mobile communication terminal.

Claims (3)

A code division multiple access mobile communication terminal comprising a high output amplifier having a constant output gain in proportion to an input signal and a transmission signal automatic gain controller for automatically adjusting the gain of the transmission signal, wherein the output level of the high output amplifier is detected. A logic unit including an output level detection unit, a memory for storing preset fixed data for comparison with the output level detected by the output level detection unit, and a register for storing a control command for output gain control; In order to adjust the output gain of the high output amplifier, the control signal of the logic unit is input to each of the plurality of switch FET transistors, the source of which is commonly connected and the reference voltage is applied to the common connected source, and the reference voltage is divided into the FET transistors. Supply the driving power to each and adjust the output level of the control signal. A plurality of high-power amplifier output control apparatus of a mobile communication terminal, characterized in that having been made in the gain control unit comprising a power split resistors to. The apparatus of claim 1, wherein the automatic gain control of the transmission signal adjusts a transmission gain by a control command stored in a register of the logic unit. 2. The apparatus of claim 1, wherein the output level detector comprises a reference power supply for supplying a reference power, a capacitor for blocking direct current at the output of the high output amplifier, a diode for detecting the output level, and an RC signal for converting an AC signal into a DC signal. A high power amplifier output control device for a mobile communication terminal, comprising a filter and an amplifier for amplifying a variable displacement of direct current.

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