KR100625445B1 - Prediction apparatus with a varying order and its control method - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a variable order predistortion device and a control method thereof.

2. The technical problem to be solved by the invention

The present invention provides a nonlinear power amplifier or a variable order predistortion device for controlling nonlinear orders and coefficients so that input and output characteristics of a power amplifier having a deteriorated characteristic are linear in a wireless communication system, and a control method thereof and a method for realizing the method. To provide a computer-readable recording medium that records the program.

3. Summary of Solution to Invention

The present invention relates to a nonlinear power amplifier or a predistortion device for linearizing input / output characteristics of a power amplifier through a coefficient adaptation function to a power amplifier having a deteriorated characteristic in a wireless communication system. Variable order adjusting means for variably adjusting the order of the nonlinear element by determining an initialization coefficient of the nonlinear element; And comparing the difference between the two signals inputted from the input terminal of the predistortion device and the output terminal of the power amplifier and the error threshold for the order adjusted by the variable order adjusting means, and for changing the order and updating the coefficient of the nonlinear element. Including coefficient updating means.

4. Important uses of the invention

The present invention is used in a wireless communication system.

Predistortion, Variable Order, Coefficient, Order Adjustment, Error, Tolerance, Error Threshold

Description

Variable order predistortion device and its control method {PREDICTION APPARATUS WITH A VARYING ORDER AND ITS CONTROL METHOD}

1 is a block diagram of a conventional predistortion apparatus.

Figure 2 is a configuration diagram of an embodiment of a variable order predistortion apparatus according to the present invention.

3 is a flow diagram of one embodiment of a method for controlling a variable order predistortion device in accordance with the present invention.

* Explanation of symbols for the main parts of the drawings

21: low pass filter 22: predistorter

23: power amplifier 24: order regulator

25: coefficient adaptor

The present invention relates to a variable order predistortion device, a control method thereof, and a computer-readable recording medium having recorded thereon a program for realizing the method. More particularly, the present invention relates to a nonlinear power amplifier or degraded characteristics in a wireless communication system. A variable order predistortion device for controlling nonlinear orders and coefficients so that input and output characteristics of a power amplifier have linearity, and a control method thereof and a computer-readable recording medium having recorded thereon a program for realizing the method.

In general, power amplifiers used in mobile communication systems have linearity and nonlinearity, respectively, according to the maximum allowable output as input / output characteristics. In general, high power power amplifiers generally exhibit non-linear characteristics, while medium or low power power amplifiers exhibit linearity. These power amplifiers deteriorate their input / output characteristics when used for a long time, and exhibit different characteristics from the original characteristics. In the case of linear power amplifiers, they exhibit non-linear characteristics gradually. Inherent nonlinear characteristics of input / output characteristics for power amplifiers or nonlinear characteristics due to deterioration result in low power efficiency, increased intermodulation distortion, and increased interference of uncontrollability, resulting in poor performance of the communication system. Thus, a predistorter is used at the front of the power amplifier to deal with this nonlinear nature of the power amplifier. A predistorter, also called a linearizer, has a nonlinear characteristic that is an input / output characteristic opposite to that of a power amplifier, so that the synthesized input and output characteristics of the power amplifier coupled in series with the predistorter appear as linearity. Although the non-linearity of the power amplifier characteristics includes almost all orders of magnitude, it can be sufficiently approximated as a finite order polynomial, so the predistorter with its opposite characteristics is limited to finite high order components, i.e., considering hardware limitations. Can be approximated as a finite order polynomial.

Therefore, the structure of the predistortion apparatus generally has a form consisting of weighted sum of all order components, and its nonlinearity is determined by the order and its coefficient. That is, various forms of nonlinearity can be obtained by adjusting each coefficient of the higher order component or changing the order.

1 is a block diagram of a conventional predistortion apparatus.

As shown in FIG. 1, the conventional predistortion apparatus linearizes a low pass filter 11 for removing noise by filtering a transmission signal received from the outside and a signal filtered by the low pass filter 11. The predistorter 12, the power amplifier 13 for sufficiently amplifying the linearized signal from the predistorter 12, the signal input to the predistorter 12, and the power amplifier 13 A coefficient adaptor 14 for adaptively updating the coefficients of the predistorter 12 by using a signal output from

Here, the predistorter 12 has a structure of a fixed order or has a structure of a fixed order, but has a structure capable of varying each coefficient. In the latter case, the coefficient adaptor 14 is used to adaptively update the coefficient of the predistorter 12 by using the input signal of the predistorter 12 and the output signal of the power amplifier 13. Here, FIG. 1 is shown for the latter, and the transmission signal means a complex baseband signal or a complex envelope of a bandpass signal.

In addition, the predistorter 12 includes a square detector 121, a nonlinear portion 122, and a multiplier 123. The square detector 121 detects a square of magnitude, that is, a power level thereof, of the signal x input from the low pass filter 11 to the predistorter 12, and the nonlinear unit 122 | x | ^{With 2} as input, it has finite order polynomial of input / output characteristics as shown in [Equation 1].

Where x is the input signal, a _n is the coefficient of the 2n + 1st component, N is the number of higher order components constituting the polynomial, and is a fixed value determined at the beginning of the setting. The nonlinear characteristic expressed by Equation 1 above is inversely related to the input / output characteristic of the power amplifier 13.

Therefore, the conventional predistorter has a fixed-order nonlinear element that can adapt only to a nonlinear characteristic in a limited range, and thus cannot adapt to nonlinearity due to higher order components, and a power amplifier having a sufficient lifetime is severely degraded or In the case of showing abnormal characteristics, there was a problem that it was not possible to sufficiently track the characteristics of the power amplifier outside the operating range of the predistorter.

The present invention has been proposed to solve the above problems, and the variable order transposition for controlling the nonlinear orders and coefficients such that the input and output characteristics of the nonlinear power amplifier or the power amplifier having the deteriorated characteristics in the wireless communication system have linearity. SUMMARY OF THE INVENTION An object of the present invention is to provide a distortion device, a control method thereof, and a computer-readable recording medium having recorded thereon a program for realizing the method.

An apparatus of the present invention for achieving the above object is a pre-distortion device for linearizing the input and output characteristics of the power amplifier through a coefficient adaptation function for a non-linear power amplifier or a power amplifier having a deteriorated characteristic in a wireless communication system, the power Variable order adjusting means for variably adjusting the order of the nonlinear element by determining an initialization coefficient of the nonlinear element with respect to the nonlinear characteristic due to the higher order component of the amplifier; And comparing the difference between the two signals inputted from the input terminal of the predistortion device and the output terminal of the power amplifier and the error threshold for the order adjusted by the variable order adjusting means, and for changing the order and updating the coefficient of the nonlinear element. Coefficient updating means.

On the other hand, the method of the present invention for achieving the above object is a pre-distortion device control method for linearizing the input and output characteristics of the power amplifier through a coefficient adaptation function for a non-linear power amplifier or a power amplifier having a deteriorated characteristic in a wireless communication system The method of claim 1, further comprising: a first step of determining an order change by comparing an error threshold and an error threshold of two signals inputted from an input terminal of the predistorter and an output terminal of the power amplifier; A second step of generating an input / output reference signal necessary for determining a coefficient of the power amplifier approximated by a finite order as a predetermined test pattern according to the determination result of the first step; Determining a coefficient of the power amplifier based on the input / output reference signal; A fourth step of changing the order of the predistortion device based on the input / output reference signal; And a fifth step of determining all coefficients of the predistorter by removing all nonlinear coefficients for the higher order components from the synthesized characteristics of which the output of the predistorter is used as an input of the power amplifier.

On the other hand, the present invention provides a first order for determining an order change by comparing an error threshold and an error threshold value of two signals input from an input terminal of the predistorter and an output terminal of a power amplifier to a predistortion apparatus of a wireless communication system having a process. function; A second function of generating an input / output reference signal required for coefficient determination of the power amplifier approximated in a finite order as a predetermined test pattern according to the determination result in the first function; A third function of determining a coefficient of the power amplifier based on the input / output reference signal; A fourth function of changing the order of the predistortion device based on the input / output reference signal; And a program for realizing a fifth function of determining the coefficients of the predistorter by removing all nonlinear coefficients for the higher order components from the synthesized characteristics in which the output of the predistorter is used as the input of the power amplifier. Provide a readable recording medium.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of an embodiment of a variable order predistortion device according to the present invention.

As shown in FIG. 2, the variable order predistortion device according to the present invention includes a low pass filter 21 for removing noise by filtering a transmission signal received from the outside, and filtering by the low pass filter 21. A preamplifier 22 for linearizing the received signal, a power amplifier 23 for amplifying the power of the signal received from the predistorter 22 and the signal received from the order adjuster 24, and the power The order controller 24 for adjusting the order by receiving the signal output from the amplifier 23, and the signal and power input to the predistorter 22 for the order adjusted by the order adjuster 24. A coefficient adaptor 25 for adaptively updating the coefficients of the predistorter 22 using the signal output from the amplifier 23 is provided. However, both signals and coefficients are complex numbers.

Here, the predistorter 22 is a square detector 221 for detecting the square of the magnitude of the signal x input from the low pass filter 21 to the predistorter 22, that is, the power level thereof. ) And | x | output from the square detector 221. A nonlinear unit 222 having a finite order polynomial of input / output characteristics with ² as an input, the order and coefficient being updated according to the order adjustment value from the order adjuster 24 and the coefficient update value from the coefficient adjuster 25. And a multiplier 223 for multiplying the signal received from the low pass filter 21 and the signal output from the nonlinear unit 222.

In addition, the coefficient adaptor 25 calculates coefficients of the nonlinear element to be updated. First, | x | for the signal x input to the predistorter 22 | ² for the output signal of the power amplifier 23 and | z | ^{Using 2} , the error between the input and output of the composite characteristics of the predistorter 22 and the power amplifier 23 is calculated as shown in Equation 2 below.

Where G is the complex gain of the combined characteristics of the predistorter 22 and the power amplifier 23. The result of [Equation 2] is applied to the following [Equation 3] to obtain the coefficient to be used at the next time.

Where A = [a ₁ , a ₂ , ....., a _N ] ^T is the complex coefficient vector, subscript T is the row and column interchange, and μ is the complex size of the update step that determines the convergence rate.

The signals i in [Equation 2] and [Equation 3] represent the i-th signal, respectively. In addition, when the error calculated according to i in the coefficient adaptor 25 is outside the allowable error ε, the calculation is performed as shown in Equation 3 above, and the result is transmitted to the nonlinear part 222, which is acceptable. If present within the error, the coefficient of the non-linear portion 222 that is updated is not calculated. Through this process, the nonlinear unit 222 is adapted to the characteristics of the power amplifier 23, which is gradually deteriorated so that the synthesized characteristics can exhibit linear characteristics. As a result, the transmitted input signal is output as a linear amplified signal without nonlinear distortion. do.

In addition to the above functions, it further has a threshold e _T for error. This error threshold is for determining whether to update the nonlinear coefficients and orders of the nonlinear element with respect to the difference between the two input signals. The error threshold is set as an optimized value and is obtained through a separate optimization process.

In addition, the coefficient adaptor 25 updates the coefficient by comparing with the error threshold when the difference between the two signals input from the input terminal of the predistorter 22 and the output terminal of the power amplifier 23 is out of the tolerance e _t . Or, it is determined whether to update the order of the nonlinear portion 222.

On the other hand, the order adjuster 24 determines the order of the nonlinear portion 222 and its initialization coefficient. For this purpose, the order regulator 24 has a reference input / output generation function, an amplifier coefficient determination function, a predistorter order change function, and a nonlinear element coefficient determination function.

First, the reference input / output generation function uses a constant signal set to obtain the current characteristics of the power amplifier in operation. The signal set is defined as equally spaced signals in the maximum range of the input signal in order to evenly use signals existing in the maximum operating range of the power amplifier 23. That is, when a set of signals such as 0 <ρ ₁ <ρ ₂ <.... <ρ _Ns are input to the power amplifier 23, respectively, a signal affected by the current characteristics of the power amplifier 23 is applied to the input signal. It is output as a response. This process results in a complete output signal set for the reference input signal set.

Second, the amplifier coefficient determination function is a function of determining each coefficient of the approximate polynomial of the power amplifier 23 having 2N _max +1. For this purpose, the previously generated reference signals, that is, reference input / output signal sets, coefficient determination procedures, and measurement errors are used. The measurement error is determined as a value suitable for the coefficient determination procedure used, and the coefficient determination procedure is as follows.

The input and output characteristics of the power amplifier are approximate polynomials given by

Where y is the input signal of the power amplifier, 2N _max +1 is the polynomial order of the approximated power amplifier, and b _n is the coefficient of the 2n + first order component.

If the reference input signal set and the reference output signal set are ρ (= ρ ₁ , ρ ₂ , ... ρ _N ) and γ (= γ ₁ , γ ₂ , ... γ _N ), respectively, The measurement error E between the output of Equation 4 and the reference output signal is shown in Equation 5 below.

Where N _s is the number of reference signals. Therefore, in order to include the coefficient to be determined, Equation 4 is substituted into Equation 5. This is shown in Equation 6 below.

That is, when the measurement error E is 0, the coefficient constituting the right summation in the square brackets is accurately obtained in Equation 6 above. However, the above Equation 6 has some error E. Therefore, each coefficient b _n of the power amplifier polynomial is determined to a value that minimizes Equation 6 above.

Third, the order change function of the predistorter is for determining the order of the predistorter 22 based on the approximation amplifier characteristics. Since the characteristics of the predistorter 22 are inversely related to the characteristics of the power amplifier 23, the new order of the nonlinear portion 222 can be determined from the approximate order of the power amplifier 23. In addition, since the continuous characteristic of the power amplifier 23 in operation includes a myriad of higher order components when converted into discrete characteristic polynomials, the order determination of the nonlinear portion 222 based on the same results in an increase in hardware complexity. . Therefore, a limited finite order of nonlinearity needs to be considered as a characteristic of the predistorter 22. The order decision for the initial operation of the predistorter 22 is set by applying the optimal value recommended in the implementation or considering the characteristics of the power amplifier 23. The order of the predistorter 22 for application after the initial setting is changed to the second higher order than the current order. In this way, the order change to the increased value is a result of the characteristic polynomial of the power amplifier 23 being composed of the odd order terms, and the increase of nonlinearity means that the order of nonlinearity is increased.

Finally, the nonlinear element coefficient determination function is a function of determining the coefficient of the nonlinear portion 222 having the inverse characteristic thereto from the characteristic polynomial of the power amplifier 23 having the coefficient determined from Equation 6 above. The predistorter 22 for having the order determined above is expressed by Equation 7 below.

Where a _n is the coefficient of the predistorter to be determined and 2N + 1 is its order. The power amplifier 23 of the nonlinear characteristic having the coefficient determined from Equation 6 is expressed by Equation 8 below.

If the output of the predistorter 22 is used as the input of the power amplifier 23, and the composite characteristic thereof is maintained as the linear characteristic, the equation 7 is substituted into the equation 8, and the output of the result equation Is equal to the input signal x in Equation 7 above. Accordingly, the coefficients for the higher order components of the synthetic properties are all zero, and a _n is obtained in relation to b. N + 1 coefficients a _n , n = 0, 1, 2, ..., N corresponding to the determined new order are transmitted to the nonlinear part 222 and the coefficient adaptor 25 for next operation, respectively.

3 is a flowchart of an embodiment of a method for controlling a variable order predistortion device according to the present invention.

As shown in FIG. 3, first, the coefficient adaptor 25 detects an error e between two input signals based on Equation 2 above (301).

Subsequently, comparing the error e is greater than the tolerance e _t (302), if the error e is not greater than the tolerance e _t , repeating the '301' process until the error is detected, If large, the error e is compared with the threshold value e _T for the error (303).

As a result of the comparison 303, if the error e is not greater than the threshold value e _T for the error, the coefficient of the nonlinear element is updated (Equation 3 described in FIG. 2) 304, and the error e is If greater than the threshold value e _T for the error, it is checked whether the limit order is exceeded (305). However, the criterion is based on the maximum value (2N _max +1) of the variable order for the nonlinear portion 222.

On the other hand, if the result of the check 305 is exceeded (i.e., the order change is impossible), and if it is not exceeded (i.e., the order change is possible), the following process (306 to 310) is performed to change the order do.

That is, in order to generate the reference I / O signal, an output signal set of the power amplifier 23 corresponding thereto is generated from the determined signal set (306), and a characteristic polynomial coefficient of the power amplifier 23 is determined (307). Here, the power amplifier 23 is provided by a characteristic function approximated by a 2N _max + first order polynomial as its input / output characteristic. Therefore, the coefficient of the power amplifier 23 is determined through [Equation 6] described in FIG.

Next, the order of the predistorter 22 is changed (308). At this time, it is determined to be higher than the order currently being used.

Then, the coefficient of the predistorter 22 is determined (309). In this case, the coefficient obtained in the process 307 of determining the coefficient of the power amplifier 23 is obtained using the characteristic polynomial of the power amplifier 23, that is, Equation 8 described with reference to FIG. In addition, in order to determine the coefficient of the predistorter 22, the nonlinear element coefficient determination function of the order regulator 24 is used.

On the other hand, the determined coefficients are transmitted to the nonlinear unit 222 and the coefficient adaptor 25 for the next operation, and set (310).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, in order to linearize the input / output characteristics of the power amplifier through the adaptive function, the present invention can adaptively track even higher orders of nonlinearity than the power amplifier because the nonlinear coefficients and orders of the predistorter can be varied. In addition, even if a power amplifier having a sufficient lifespan is severely degraded or exhibits abnormal characteristics, there is an effect of sufficiently obtaining a linearization characteristic with respect to the characteristics of the power amplifier outside the operation range of the predistortion apparatus.

Claims (7)

A predistortion apparatus for linearizing the input / output characteristics of a power amplifier through a coefficient adaptation function to a nonlinear power amplifier or a power amplifier having a deteriorated characteristic in a wireless communication system, Variable order adjusting means for variably adjusting the order of the nonlinear element by determining an initialization coefficient of the nonlinear element with respect to the nonlinear characteristic due to the higher order component of the power amplifier; And A coefficient for updating the coefficient of the nonlinear element by comparing the difference between the two signals inputted from the input terminal of the predistorter and the output terminal of the power amplifier and the error threshold for the order adjusted by the variable order adjusting means. Means of renewal Variable order predistortion device comprising a. The method of claim 1, The variable order adjusting means, In order to adjust the order of the nonlinear element by determining the initialization coefficient of the nonlinear element with respect to the nonlinear characteristic due to the higher order component of the power amplifier, a reference signal generation function, a power amplifier number determination function, a predistortion device order changing function, A variable order predistortion device characterized in that it performs a nonlinear element coefficient determination function. A method of controlling a predistortion device which linearizes input / output characteristics of a power amplifier through a coefficient adaptation function to a nonlinear power amplifier or a power amplifier having a deteriorated characteristic in a wireless communication system, A first step of determining an order change by comparing an error threshold and an error threshold of two signals inputted from an input terminal of the predistorter and an output terminal of the power amplifier; A second step of generating an input / output reference signal necessary for determining a coefficient of the power amplifier approximated by a finite order as a predetermined test pattern according to the determination result of the first step; Determining a coefficient of the power amplifier based on the input / output reference signal; A fourth step of changing the order of the predistortion device based on the input / output reference signal; And A fifth step of determining the coefficients of the predistorter by removing all nonlinear coefficients for the higher order components from the synthesized characteristics of which the output of the predistorter is used as the input of the power amplifier; Variable order predistortion device control method comprising a. The method of claim 3, wherein The first step is, A sixth step of detecting an error (e) for two signals inputted from an input terminal of the predistorter and an output terminal of the power amplifier; Comparing whether the detected error is greater than the tolerance (e _t ), and if the detected error (e) is not large, repeating from the sixth step. If the detected error (e) is large, the error (e) and A seventh step of comparing the threshold e _T for the error; And As a result of the comparison in the seventh step, if the error e is not greater than the threshold e _T for the error, the coefficient of the nonlinear element is updated, and if the error e is greater than the threshold e _T for the error, 8th step to check for excess Variable order predistortion device control method comprising a. The method according to claim 3 or 4, The second step, In order to obtain a current characteristic of the power amplifier in operation, a certain signal set is used, and in order to use a signal existing in the maximum operating range of the power amplifier, a signal is acquired at equal intervals in the maximum range of the input signal. Control of variable order predistorter. The method of claim 5, wherein The third step, A method of controlling a variable order predistortion device, characterized in that each coefficient of the approximate polynomial is determined to represent the input / output characteristics of the power amplifier having 2N _max +1 as the order.

Where E is the measurement error, b _n is the coefficient of the 2n + 1st component, ρ (= ρ ₁ , ρ ₂ , ... ρ _N ) is the reference input signal set, γ (= γ ₁ , γ ₂ ,. γ _N ) is the reference output signal set, N _s is the number of reference signals) In the predistortion apparatus of the wireless communication system having a process, A first function of determining an order change by comparing an error and an error threshold of two signals inputted from an input terminal of the predistorter and an output terminal of a power amplifier; A second function of generating an input / output reference signal required for coefficient determination of the power amplifier approximated in a finite order as a predetermined test pattern according to the determination result in the first function; A third function of determining a coefficient of the power amplifier based on the input / output reference signal; A fourth function of changing the order of the predistortion device based on the input / output reference signal; And A fifth function of determining the coefficients of the predistorter by removing all nonlinear coefficients for the higher order components from the composite characteristic of which the output of the predistorter is used as the input of the power amplifier A computer-readable recording medium having recorded thereon a program for realizing this.

Images