KR100623353B1 - Transmitter with predistorter and handset for transmitting with function of predistortion - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a precompensation transmitting device and a portable terminal having a precompensation transmitting function.

2. The technical problem to be solved by the invention

According to the present invention, a predistorter is mounted in a transmitter to prevent saturation of an amplitude modulation (AM) component of a power amplifier in a polar loop transmission device. At the same time, the object of the present invention is to provide a precompensation transmitting device capable of reducing the mounting area and a portable terminal having a precompensation transmitting function.

3. Summary of Solution to Invention

The present invention receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, generates a power detection signal according to the envelope component, and precompensates the phase oscillation signal. A signal transmission unit for amplifying the signal and transmitting the amplified signal; And receiving the power detection signal from the signal transmission unit, and transferring the power detection signal as the precompensation signal to the signal transmission unit as the voltage level of the power detection signal is equal to or less than a saturation reference voltage, and transmitting the power detection signal. And a precompensator for increasing the voltage level of the power detection signal as the voltage level exceeds the saturation reference voltage and outputting the precompensation signal to the signal transmitter.

4. Important uses of the invention

The present invention is used in a portable terminal.

Precompensation, PAM, Spurious, Terminal

Description

TRANSMITTER WITH PREDISTORTER AND HANDSET FOR TRANSMITTING WITH FUNCTION OF PREDISTORTION}             

1 is a block diagram showing a conventional transmission device;

2 is a block diagram showing another conventional transmission apparatus;

3 is a block diagram showing a precompensation transmitting apparatus according to an embodiment of the present invention;

4 is a circuit diagram illustrating a predistorter of FIG. 3;

5A is a graph illustrating input and output characteristics of a predistorter;

5B is a graph illustrating an output power value according to an input of a gain control signal of a power amplifier;

5C is a graph illustrating an output power value according to an input of a precompensation signal, which is a gain control signal of a power amplifier.

* Explanation of symbols for the main parts of the drawings

300: signal transmission unit 360: precompensation unit

The present invention relates to a precompensation transmitting apparatus and a portable terminal having a precompensating transmitting function. More particularly, the present invention relates to an amplitude modulation (AM) component of a power amplifier in a polar loop transmitting apparatus. A precompensation transmitting apparatus for preventing saturation and a portable terminal having a precompensation transmitting function.

A general polar loop transmission device transmits a signal modulated using an I signal and a Q signal. At this time, the modulated signal has a change in phase and envelope. When a signal with a change in phase and envelope is amplified directly by a power amplifier, spurious occurs in an adjacent channel of a transmission channel due to the frequency component of the envelope signal. In order to solve this problem, a general polar loop type transmission device is configured as follows.

1 is a block diagram showing a conventional transmission apparatus, which will be described below.

The RF oscillation signal generator 110 generates an oscillation signal of an RF band and outputs the generated signal to the mixing unit 120. In addition, the mixing unit 120 receives an I signal for transmission and a Q signal for transmission, receives an oscillation signal of an RF band from the RF oscillation signal generator 110, an oscillation signal of the RF band, an I signal for transmission, and By mixing the transmission Q signal, respectively, the transmission I signal and the transmission Q signal are upconverted to the RF band, and serve to output the upconverted signal to the limiter 130 and the power detector 140. The limiter 130 receives a signal from the mixing unit 120, generates a limited transmission signal having a limited amplitude and a phase identical to the input signal, and outputs the limited transmission signal to the transmission oscillator 150. do. In addition, the power detector 140 receives a signal from the mixing unit 120, detects an envelope component of the input signal, and uses the detected envelope signal as a control signal for adjusting the gain of the power amplifier 160. It plays a role of outputting. Meanwhile, the transmission oscillator 150 receives the limited transmission signal from the limiter 130, generates an RF oscillation signal having a phase of the limited transmission signal, and outputs the RF oscillation signal to the power amplifier 160. . In addition, the power amplifier (PAM) 160 receives an RF oscillation signal from the transmission oscillator 150, receives an envelope signal from the power detector 140, and amplifies the RF oscillation signal with a gain according to the envelope signal. It plays a role.

That is, only the phase information is detected as a path by the limiter 130 and the transmission oscillator 150 and applied to the power amplifier 160, and only the envelope information is detected as a path (AM path) by the power detector 140. To apply to the power amplifier 160. As a result, the output signal of the power amplifier 160 maintains the phase of the original transmission signal as it is and does not generate spurious.

However, according to the conventional transmission apparatus described above, since the power amplifier 160 is saturated near the maximum output, the distorted signal is transmitted. In order to solve this problem, an improved polar loop transmission device is constructed as follows.

2 is a block diagram showing another conventional transmission apparatus, which will be described below.

The IF oscillation signal generator 205 generates an oscillation signal of the IF band and outputs the generated signal to the mixing unit 210. In addition, the mixing unit 210 receives the I signal for transmission and the Q signal for transmission, receives the oscillation signal of the IF band from the IF oscillation signal generator 205, and the oscillation signal and the I signal for transmission of the IF band and By mixing the transmission Q signals, respectively, the transmission I signal and the transmission Q signal are up-converted to the IF band, and serve to output the upconverted signals to the limiter 215 and the power detector 220. On the other hand, the limiter 215 receives a signal from the mixing unit 210 generates a limited transmission signal having a limited amplitude and the same phase as the input signal, and outputs the limited transmission signal to the phase detector 230. do. In addition, the power detector 220 receives a signal from the mixing unit 210, detects an envelope component of the input signal, and outputs the detected envelope signal to the comparator 235. On the other hand, the phase detector 230 receives a down-converted signal from the mixer 255, receives a limited transmission signal from the limiter 215, and reflects the down-converted signal based on the limited transmission signal. It generates and outputs the phase synchronization signal to the transmission oscillator (240). In addition, the comparator 235 receives an envelope signal from the plurality of power detectors 220 and 260, respectively, and controls the gain of the power amplifier 245 in a direction in which the envelope components of the two signals coincide. Meanwhile, the transmission oscillator 240 receives a phase synchronization signal from the phase detector 230, generates an RF oscillation signal having a phase of the phase synchronization signal, and outputs an RF oscillation signal to the power amplifier 245. do. The power amplifier (PAM) 245 receives an RF oscillation signal from the transmission oscillator 240, receives a signal controlling a gain from the comparator 235, and outputs an RF oscillation signal from the comparator 235. It amplifies the gain according to the signal. In addition, the RF oscillation signal generator 250 generates an oscillation signal in the RF band and outputs the generated signal to the mixer 255. The mixer 255 receives the amplified signal from the power amplifier 245, receives the oscillation signal of the RF band from the RF oscillation signal generator 250, and mixes the oscillation signal and the amplified signal of the RF band. The down-converted amplified signal to the IF band, and outputs the down-converted signal to the phase detector 230. In addition, the power detector 260 receives a signal from the power amplifier 245, detects an envelope component of the input signal, and outputs the detected envelope signal to the comparator 235.

That is, by compensating the output signal of the power amplifier 245 by the comparator 235, the envelope component output from the comparator 235 is prevented from being distorted by the saturation region of the power amplifier 245.

However, according to the conventional technology described above, since hardware such as the power detector 260 and the comparator 235 must be added, not only the mounting area is increased, but also the speed of compensating the output signal to the response speed of the feedback loop having a limit point There is a problem that depends.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problem, and by installing a predistorter in a transmitter, an amplitude modulation (AM) component of a power amplifier in a polar loop type transmission device can be obtained. It is an object of the present invention to provide a precompensation transmitting apparatus capable of preventing saturation and reducing the mounting area and a portable terminal having a precompensation transmitting function.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. In addition, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

An apparatus of the present invention for achieving the above object, receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, and generates a power detection signal according to the envelope component A signal transmission unit for amplifying the phase oscillation signal by a precompensation signal and transmitting the amplified signal; And receiving the power detection signal from the signal transmission unit, and transferring the power detection signal as the precompensation signal to the signal transmission unit as the voltage level of the power detection signal is equal to or less than a saturation reference voltage, and transmitting the power detection signal. And a precompensator for increasing the voltage level of the power detection signal as the voltage level exceeds the saturation reference voltage and outputting the precompensation signal to the signal transmitter.

In addition, the apparatus of the present invention for achieving the above object, in a portable terminal having a pre-compensation transmission function, receives a transmission signal having a phase component and an envelope component, and generates a phase oscillation signal according to the phase component A signal transmission unit generating a power detection signal according to the envelope component, amplifying the phase oscillation signal by a precompensation signal, and transmitting the amplified signal; And receiving the power detection signal from the signal transmission unit, and transferring the power detection signal as the precompensation signal to the signal transmission unit as the voltage level of the power detection signal is equal to or less than a saturation reference voltage, and transmitting the power detection signal. And a precompensator for increasing the voltage level of the power detection signal as the voltage level exceeds the saturation reference voltage and outputting the precompensation signal to the signal transmitter.

On the other hand, the apparatus of the present invention for achieving the above object, in a portable terminal having a pre-compensation transmission function, receives a transmission signal having a phase component and an envelope component, and generates a phase oscillation signal according to the phase component A signal transmission unit generating a power detection signal according to the envelope component, amplifying the phase oscillation signal by a precompensation signal, and transmitting the amplified signal; And a mapped lookup table that receives the power detection signal from the signal transmission unit and maps the voltage level of the precompensation signal for each voltage level of the power detection signal, wherein the voltage level reflects the amplification saturation characteristic of the signal transmission unit. And a predistorter for outputting the predistortion signal generated by referring to the lookup table to the signal transmitter.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing a precompensation transmitting apparatus according to an exemplary embodiment of the present invention. The precompensation transmitting apparatus of the present invention includes a signal transmitter 300 and a precompensator 360.

The signal transmission unit 300 receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, generates a power detection signal according to the envelope component, and generates the phase oscillation. The signal is amplified by the precompensation signal input from the precompensator 360 and transmits the amplified signal. Here, the signal transmission unit 300 will be described in detail as follows.

The IF oscillation signal generator 305 mounted in the signal transmission unit 300 generates an oscillation signal of the IF band and outputs the generated signal to the mixing unit 310.

In addition, the mixing unit 310 mounted in the signal transmitter 300 receives an I signal for transmission and a Q signal for transmission, and receives an oscillation signal of an IF band from an IF oscillation signal generator 305. By mixing the oscillation signal of the IF band, the transmission I signal and the transmission Q signal, respectively, upconvert the transmission I signal and the transmission Q signal to the IF band, and convert the upconverted signal into the limiter 315 and the power detector. It serves to output to (320).

On the other hand, the limiter 315 mounted in the signal transmission unit 300 receives a signal from the mixing unit 310 generates a limited transmission signal having a limited amplitude and the same phase as the input signal, and generates a limited transmission signal. It serves to output to the phase detector 325.

In addition, the power detector 320 mounted in the signal transmission unit 300 receives a signal from the mixing unit 310, detects an envelope component of the input signal, and converts the detected envelope signal into a phase detection signal. As a pre-compensation unit 360 serves to output.

Meanwhile, the phase detector 325 mounted in the signal transmitter 300 receives a down-converted signal from the mixer 350, receives a limited transmission signal from the limiter 315, and based on the limited transmission signal. By generating a phase synchronization signal reflecting the down-converted signal, and outputs the phase synchronization signal to the transmission oscillator 335.

Meanwhile, the transmission oscillator 335 mounted in the signal transmission unit 300 receives a phase synchronization signal from the phase detection unit 325, generates an RF oscillation signal having a phase of the phase synchronization signal, and generates an RF oscillation signal. It serves to output to the power amplifier 340.

In addition, the power amplifier (PAM) 340 mounted in the signal transmission unit 300 receives an RF oscillation signal from the transmission oscillator 335 and a precompensation signal for controlling gain from the precompensator 360. Receives a signal, and amplifies the RF oscillation signal by a gain according to the precompensation signal.

In addition, the RF oscillation signal generator 345 mounted in the signal transmission unit 300 serves to generate an oscillation signal of an RF band and output the generated signal to the mixer 350.

On the other hand, the mixer 350 mounted in the signal transmission unit 300, receives the signal amplified from the power amplifier 340, receives the oscillation signal of the RF band from the RF oscillation signal generator 345, By mixing the oscillation signal and the amplified signal of the RF band, the amplified signal is down-converted to the IF band, and serves to output the down-converted signal to the phase detector 325.

In addition, the predistorter 360 receives the power detection signal from the signal transmitter 300, and transmits the power detection signal to the predistortion signal as the voltage level of the power detection signal is equal to or less than a saturation reference voltage. The signal transmission unit 300 is transmitted to the signal transmission unit 300, and as the voltage level of the power detection signal exceeds the saturation reference voltage, the voltage level of the power detection signal is increased to the signal transmission unit 300 as the pre-compensation signal. It plays a role of outputting.

Here, the precompensator 360 receives the power detection signal from the signal transmitter 300 and includes a lookup table in which the voltage levels of the precompensation signals are mapped for each voltage level of the power detection signal. The precompensation signal generated by referring to the lookup table may be output to the signal transmitter 300, but is not limited thereto. In this case, the voltage level of the precompensation signal is a voltage level reflecting the amplification saturation characteristics of the signal transmission unit.

FIG. 4 is a circuit diagram illustrating the predistorter 360 of FIG. 3.

The amplification factor setting unit 410 mounted in the precompensator 360 may include a first resistance element 413 connected between an output terminal of the amplifier 420 and an inverting terminal, and a first terminal connected between the inverting terminal of the amplifier 420 and ground. 2 resistance elements 411 and 412, and serves to reduce the resistance of the second resistance elements 411 and 412 as the voltage level of the power detection signal exceeds the saturation reference voltage. Here, the second resistance elements 411 and 412 may be diodes connected in series such that an anode is connected to the inverting terminal side of the amplifier 420 and a cathode is connected to the ground side, but is not limited thereto.

In addition, the amplifier 420 mounted in the precompensator 360 amplifies the power detection signal input through the non-inverting terminal and outputs the amplified signal through the output terminal as the precompensation signal. do.

FIG. 5A is a graph illustrating input / output characteristics of the predistorter 360, FIG. 5B is a graph illustrating an output power value according to an input of a control voltage of the power amplifier 340, and FIG. 5C is a power amplifier. A graph showing an output power value according to an input of a precompensation signal (Input voltage), which is a gain control signal of 340, with reference to the precompensation transmitting device and a portable terminal having a precompensation transmitting function according to the present invention. Referring to the operation of as follows.

First, the predistorter 360 receives the power detection signal from the signal transmission unit 300, and converts a signal proportional to the power detection signal as the voltage level of the power detection signal is less than or equal to the saturation reference voltage. As to transmit to the signal transmission unit 300.

That is, when the output of the power amplifier 340 is not large enough to exhibit a saturation characteristic, the power amplifier 340 performs the power amplification operation according to the gain reflecting the level of the power detection signal as it is.

Meanwhile, the predistorter 360 receives the power detection signal from the signal transmission unit 300 and increases the voltage level of the power detection signal as the voltage level of the power detection signal exceeds the saturation reference voltage to compensate for the predistortion. The signal is output to the signal transmission unit 300.

That is, in the amplification factor setting unit 410, as the power detection signal exceeding the saturation reference voltage is applied to the non-inverting terminal of the amplifier 420, the resistance values of the diodes, which are the second resistance elements 411 and 412, are decreased. do. In other words, when a power detection signal having a voltage level equal to or higher than the threshold voltage set by the diode is applied to the non-inverting terminal of the amplifier 420, the resistance component of the diode is drastically reduced. Here, the threshold voltage can be arbitrarily adjusted according to the characteristics of the diode and the number of connections thereof.

Accordingly, the amplification factor of the amplifier 420 is increased according to the following equation, and the voltage level of the precompensation signal is increased.

That is, when the output of the power amplifier 340 is large enough to exhibit a saturation characteristic, the power amplifier 340 increases the amplification gain due to the precompensation signal more than the increase of the power detection signal. Power amplification operation is not affected.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

The present invention as described above, by mounting a predistorter in the transmitter, the saturation phenomenon with respect to the amplitude modulation (AM) component of the power amplifier in a polar loop type transmission apparatus There is an advantage that can be prevented while reducing the mounting area.

Claims (5)

In the precompensation transmitting apparatus, Receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, generates a power detection signal according to the envelope component, and amplifies the phase oscillation signal by a precompensation signal A signal transmission unit for transmitting the amplified signal; And Receiving the power detection signal from the signal transmission unit, and transferring the power detection signal as the pre-compensation signal to the signal transmission unit as the voltage level of the power detection signal is equal to or less than a saturation reference voltage, The predistorter increases the voltage level of the power detection signal as the voltage level exceeds the saturation reference voltage and outputs the predistortion signal to the signal transmitter as the predistortion signal. Pre-compensation transmission device comprising a. The method of claim 1, wherein the predistortion unit, An amplifier for amplifying the power detection signal input through the non-inverting terminal and outputting the amplified signal through the output terminal as the precompensation signal; And A first resistance element connected between the output terminal and the inverting terminal of the amplifier, and a second resistance element connected between the inverting terminal and the ground of the amplifier, wherein the second level is increased as the voltage level of the power detection signal exceeds a saturation reference voltage. Amplification factor setting unit for reducing the resistance value of the resistance element Pre-compensation transmitting apparatus comprising a. In a portable terminal having a pre-compensation transmission function, Receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, generates a power detection signal according to the envelope component, and amplifies the phase oscillation signal by a precompensation signal A signal transmission unit for transmitting the amplified signal; And Receiving the power detection signal from the signal transmission unit, and transferring the power detection signal as the pre-compensation signal to the signal transmission unit as the voltage level of the power detection signal is equal to or less than a saturation reference voltage, The predistorter increases the voltage level of the power detection signal as the voltage level exceeds the saturation reference voltage and outputs the predistortion signal to the signal transmitter as the predistortion signal. Portable terminal having a pre-compensation transmission function comprising a. The method of claim 3, wherein the predistortion unit, An amplifier amplifying the power detection signal input through the non-inverting terminal and outputting the amplified signal through the output terminal as the precompensation signal; And A first resistance element connected between the output terminal and the inverting terminal of the amplifier and a second resistance element connected between the inverting terminal and the ground of the amplifier, wherein the second resistance element is increased as the voltage level of the power detection signal exceeds a saturation reference voltage. Amplification factor setting unit for reducing the resistance value of the resistance element Portable terminal having a pre-compensation transmission function comprising a. In a portable terminal having a pre-compensation transmission function, Receives a transmission signal having a phase component and an envelope component, generates a phase oscillation signal according to the phase component, generates a power detection signal according to the envelope component, and amplifies the phase oscillation signal by a precompensation signal A signal transmission unit for transmitting the amplified signal; And The power detection signal is input from the signal transmission unit, and the voltage level of the precompensation signal for each voltage level of the power detection signal is a voltage level reflecting an amplification saturation characteristic of the signal transmission unit. And a predistorter for outputting the predistortion signal generated by referring to the lookup table to the signal transmitter. Portable terminal having a pre-compensation transmission function comprising a.

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