JP5663261B2 - Predistorter - Google Patents

Description

  The present invention relates to a predistorter that compensates for distortion due to a memory effect of a compensated circuit such as a signal amplifier.

  As a conventional predistorter, distortion compensation is performed using a single lookup table (LUT) (see, for example, Patent Document 1), and a lookup table is obtained and then generated again using a distortion compensation polynomial. There is one that performs distortion compensation using a single lookup table (see, for example, Patent Document 2).

Japanese Patent No. 3560398 JP 2006-093947 A JP 2002-223171 A JP 2010-141725 A

  The conventional predistortion amplifier calculates the distortion compensation value (table value) by reducing the number of addresses when updating in order to reduce the amount of calculation of the distortion compensation value (table value) by adaptive signal processing and the memory amount. There is a method of interpolating table values between addresses (see, for example, Patent Document 3). However, this method has a problem in the accuracy of distortion compensation based on the interpolated distortion compensation value (table value).

  There is a technique (see, for example, Patent Document 4) in which the lookup table is replaced with a preliminary lookup table and the distortion compensation apparatus operates stably when the lookup table fails or when the characteristics are low. However, a specific technique for discarding the preliminary look-up table that is no longer appropriate as time passes and reducing the amount of memory has not been disclosed.

  Therefore, the present invention has been made to solve the above-described problem, and it is unnecessary to interpolate a distortion compensation value between addresses of the lookup table, and the preliminary lookup table that is no longer appropriate as aged deteriorates. An object of the present invention is to provide a predistorter that reduces the amount of memory.

  In order to achieve the above object, the predistorter according to the present invention updates the lookup table so that the relationship between the input signal and the output signal is linear.

  The two storage units store the lookup tables separately, and store a lookup table having high characteristics among the lookup table and the updated lookup table. However, the two storage units store the updated look-up table by discarding the look-up tables stored at different update timings at regular intervals and without comparing the characteristics of the look-up tables. .

  The distortion compensation circuit is usually loaded with an updated look-up table. However, the distortion compensation circuit is loaded with the stored lookup table when the updated lookup table is broken or when there is a load request for the stored lookup table. At this time, the distortion compensation circuit is loaded with the stored lookup table from the storage unit having a longer time from the lookup table discard timing to the lookup table load timing.

  Specifically, the present invention relates to a distortion compensation circuit that outputs a predistortion compensation signal generated by a lookup table based on an input signal to a compensated circuit, and the relationship between the input signal and the output signal of the compensated circuit. An update unit that updates the lookup table so as to be linear, a first storage unit and a second storage unit that store the lookup table separately, and every time the update unit updates a predetermined number of times. At the first timing, the lookup table stored in the first storage unit is overwritten with the updated lookup table of the update unit, and the characteristics of the lookup table stored in the second storage unit are set. Compared with the characteristics of the updated look-up table of the update unit, a look-up table with high characteristics is stored in the second storage unit, and the post-first timing At a second timing when the number of updates of the new part is less than the predetermined number of times, the look-up table stored in the second storage part is overwritten with the look-up table updated by the update part, and the first storage part The characteristic of the look-up table stored is compared with the characteristic of the look-up table updated by the updating unit, and a look-up table having a high characteristic is stored in the first storage unit, and the first timing and the second timing are stored. Compare the characteristics of the lookup table stored in the first storage unit with the characteristics of the updated lookup table of the update unit at a timing other than the above, and store the lookup table having a high characteristic in the first storage unit In addition, the characteristics of the lookup table stored in the second storage unit are changed to the lookup table updated by the update unit. A comparison unit that stores a lookup table having high characteristics in the second storage unit, a lookup table stored in the first storage unit and the second storage unit, and an update unit When selecting one of the updated look-up tables as a look-up table to be loaded into the distortion compensation circuit, when selecting the look-up table stored in the first storage unit or the second storage unit, When the time from the first timing to the selection time is longer than the latest time from the second timing to the selection time, the lookup table stored in the first storage unit is selected, and the latest first When the time from the second timing to the selection time is longer than the latest time from the first timing to the selection time, the second storage unit stores the time. And a selection unit that selects a lookup table.

  Since the look-up table is updated so that the relationship between the input signal and the output signal is linear, there is no need to interpolate table values between addresses. Therefore, the present invention can provide a predistorter in which it is not necessary to interpolate a distortion compensation value between addresses in the lookup table.

  Here, one storage unit stores the updated lookup table at the time of discarding the stored lookup table, and the updated lookup table is a lookup table with high characteristics. Is not limited. However, the other storage unit stores a lookup table having a high characteristic through comparison of the characteristics of the lookup table from when the saved lookup table was last discarded until the time point. Therefore, the distortion compensation circuit loads a look-up table having high characteristics from the other storage unit instead of being loaded from one storage unit. Therefore, the present invention can provide a predistorter that reduces the memory amount by discarding the preliminary look-up table that is no longer appropriate as time passes.

  Further, the present invention resets the counter value at the first timing, increments the counter value every time the updating unit updates the lookup table, and when the counter value reaches a value equal to the predetermined number of times. A first counter for notifying the comparison unit of the next first timing, and a counter value is reset at the second timing, and the counter value is incremented each time the update unit updates the lookup table. The predistorter further comprising: a second counter that notifies the comparison unit of the next second timing when the value reaches a value equal to the predetermined number of times.

  According to this configuration, the discard timing of the stored lookup table can be measured for each storage unit.

  The present invention also resets the counter value at the first timing, increments the counter value every time the updating unit updates the lookup table, and the counter value continues from the first timing to the first timing. When a value equal to the number of updates of the update unit up to the second timing is reached, the second timing following the first timing is notified to the comparison unit, and the counter value reaches a value equal to the predetermined number of times. And a counter that notifies the comparison unit of the next first timing.

  According to this configuration, the discard timing of the stored lookup table can be measured with only one counter for each storage unit.

  The present invention is the predistorter characterized in that the number of updates of the updating unit from the first timing to the second timing following the first timing is equal to half the predetermined number of times. .

  According to this configuration, the distortion compensation circuit always loads a lookup table having a high characteristic stored through comparison of the characteristics of the lookup table over a half of the predetermined number of times from any storage unit. can do.

  The comparison unit may determine that the characteristics of the lookup table are high when the difference between the predistortion compensation signal and the output calculation signal generated by the lookup table based on the output signal is small. Is a predistorter characterized by

  According to this configuration, the relationship between the input signal and the output signal can be made linear.

  Further, according to the present invention, the comparison unit determines that the characteristics of the lookup table are high when the adjacent channel leakage power ratio indicating the ratio of leakage of the output signal to a frequency channel deviating from a predetermined frequency channel is small. This is a predistorter characterized by the above.

  According to this configuration, distortion of the frequency spectrum of the output signal can be eliminated.

  The present invention provides a predistorter that eliminates the need to interpolate a distortion compensation value between addresses of a lookup table, and discards a preliminary lookup table that is no longer appropriate as time passes, thereby reducing the amount of memory. it can.

It is a block diagram explaining the structure of the predistorter which concerns on this invention. It is a block diagram explaining the structure of the predistorter which concerns on this invention. It is a block diagram explaining the distortion compensation circuit of the predistorter concerning the present invention. It is the figure which modeled the amplifier circuit comprised with the some amplifier. It is a block diagram explaining the 1st control part concerning the present invention. It is a flowchart explaining a comparison part among the 1st control parts concerning the present invention. It is a flowchart explaining a selection part among the 1st control parts concerning the present invention. It is a block diagram explaining the 2nd control part concerning the present invention. It is a flowchart explaining a comparison part among the 2nd control parts concerning the present invention. It is a flowchart explaining a selection part among the 2nd control parts which concern on this invention.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiment described below is an example of the configuration of the present invention, and the present invention is not limited to the following embodiment. In the present specification and drawings, the same reference numerals denote the same components. In addition, the description with the reference numerals without the branch numbers is the description common to all the components and signals with the reference numerals assigned with the branch numbers.

(Predistorter configuration)
FIG. 1 is a block diagram illustrating the configuration of the predistorter 301 of this embodiment. The predistorter 301 outputs the predistortion compensation signal A generated by the loaded look-up table based on the input signal X to the compensated circuit 401, the input signal X, and the output of the compensated circuit 401. A control unit 13 that receives the signal Y and updates the look-up table so that the relationship between the input signal X and the output signal Y is linear.

  FIG. 2 is a block diagram illustrating the configuration of the predistorter 302 of this embodiment. The predistorter 302 outputs the predistortion compensation signal A generated by the loaded look-up table based on the input signal X to the compensated circuit 401, and the predistortion signal A and the compensated circuit 401. And a control unit 13 that updates the look-up table so that the relationship between the input signal X and the output signal Y is linear.

  For example, the compensated circuit 401 is an amplifier. In the following description, the compensated circuit 401 is described as an amplifier.

  FIG. 3 is a block diagram for explaining the distortion compensation circuit 11 of the predistorter 301 and the predistorter 302. The distortion compensation circuit 11 includes a delay unit 31 that generates a plurality of sampling signals S captured at different times from the input signal X, and the latest sampling signal S or at least one sampling signal S delayed by the delay unit 31. A plurality of lookup tables 23 for referring to the intensity, calculating the distortion compensation value by directly quoting the sampling signal S, and applying the distortion compensation value to any one of the sampling signals S to generate the distortion signal H; A control unit 13 that outputs an instruction to generate a distortion signal H by calculating a distortion compensation value for each of the lookup tables 23, and a predistortion compensation signal generated by adding the distortion signals generated by the lookup table 23 And a distortion compensation value generation unit 33 that outputs A to the compensated circuit 401.

The delay unit 31 includes, for example, a plurality of delay elements 21 connected in series. The input signal X that has been input passes through the delay element 21 continuously, and is delayed by a predetermined amount (that is, the sampling period T _s ) each time it passes. The sampling signal S delayed by a predetermined amount from the input signal X can be extracted by extracting the output after passing a predetermined number of delay elements 21. In other words, by extracting the outputs of the different delay elements 21, a plurality of sampling signals S captured at different times from the input signal X can be obtained. The delay unit 31 in FIG. 3 includes a sampling signal S-0 that is not delayed from the input signal X, an input signal sampling signal S-5 that has passed five delay elements 21, and an input signal that has passed nine delay elements 21. Sampling signal S-9, sampling signal S-11 of the input signal that has passed 11 delay elements 21, sampling signal S-13 of the input signal that has passed 13 delay elements 21, and input signal that has passed 17 delay elements 21 Sampling signal S-17 is extracted.

  The distortion signal generation unit 32 includes an intensity calculation unit 22 that measures the intensity of the input sampling signal S, a lookup table 23 that calculates a distortion compensation value with reference to the intensity of the sampling signal S measured by the intensity calculation unit 22, and A multiplier 24 that multiplies the distortion compensation value from the lookup table 23 and the sampling signal S is provided. Here, the intensity of the sampling signal S is, for example, amplitude or power.

  The distortion signal generator 32-0 multiplies the sampling signal S-0 with reference to the intensity by the multiplier 24 by the distortion compensation value calculated from the sampling signal S-0 by the lookup table 23-0, and generates the distortion signal H-0. , 0 is output. Similarly, the distortion signal generation unit 32-13 multiplies the distortion signal calculated by the lookup table 23-13 from the sampling signal S-13 by the multiplier 24 to the sampling signal S-13 with reference to the intensity, and the distortion signal. H-13 and 13 are output. Note that the distortion signal generation unit 32-0 corresponds to a conventional distortion signal generation unit (predistorter) that does not consider measures against nonlinear distortion generated by the memory effect of the amplification device.

  The distortion signal generator 32-5 uses the multiplier 24 to calculate the distortion compensation value calculated from the sampling signal S-5 by the lookup table 23-5 to the sampling signal S-9 different from the sampling signal S-5 with reference to the intensity. Multiply and output distortion signals H-9,5. Note that the signals used for quoting the lookup table may be the same. Specifically, the sampling signal S-5 used for quoting by the lookup table 32-5 is quoted by another lookup table (not shown) and multiplied by the sampling signal S-7, and the distortion signals H-7 and 5 are obtained. It may be output. Here, the lookup table 23-0, the lookup table 23-5, and the lookup table 23-13 are univariate lookup tables.

  The distortion signal generation unit 32-11 calculates a distortion compensation value by referring to the intensity of the sampling signal S-11 and the sampling signal S-17 in the lookup table 23-11, and the multiplier 24 calculates the distortion compensation value to the sampling signal. The distortion signal H-11, 17 is output by multiplying S-11. Here, the lookup table 23-11 is a two-variable lookup table.

  The distortion compensation value generation unit 33 adds the distortion signal H output from the distortion signal generation unit 32 to generate a predistortion compensation signal A. Specifically, the distortion compensation value generation unit 33 includes distortion signals H-0 and 0 output from the distortion signal generation unit 32-0, distortion signals H-9 and 5 output from the distortion signal generation unit 32-5, and distortion. The distortion signals H-13 and 13 output from the signal generation unit 32-13 and the distortion signals H-11 and 17 output from the distortion signal generation unit 32-11 are added to generate the predistortion compensation signal A. Since the predistortion compensation signal A is added with the inverse distortion characteristic (distortion compensation characteristic) of the distortion characteristic of the compensated circuit 401, the distortion of the output signal Y of the compensated circuit 401 can be reduced.

  The control unit 13 adds the plurality of signals generated by multiplying the distortion compensation values obtained by quoting the values of the plurality of lookup tables not shown in FIG. Output obtained by adding a plurality of signals generated by multiplying the calculated signal or predistortion compensation signal A and distortion compensation values obtained by quoting values of a plurality of lookup tables with the intensity of the output signal Y by the output signal Y The table values of the respective lookup tables 23 are updated so that the relationship with the calculation signal is linear. The table values of all the lookup tables 23 may be updated, or the table values of only the lookup tables 23 that need to be updated may be updated.

とし，要素増幅器を合成する比率が入力信号の振幅値の関数（合成多項式）

として図４のモデルを数式で表現した数式３において、同じサンプリング時刻の入力信号、および入力信号の強度を有する項を数式７のようにまとめて分類する。この多項式の分類により、入力信号の強度から歪補償値の一部を算出する複数のルックアップテーブルが作成できる。

ここで、各パラメータの定義を整理しておく。
ｊ：要素増幅器の番号
Ｊ：要素増幅器の総数
ｒ：正規化先行時間、または正規化遅延時間
Ｒ１_ｊ：ｊ番目要素増幅器に対応する合成多項式の最大の正規化先行時間
Ｒ２_ｊ：ｊ番目要素増幅器に対応する合成多項式の最大の正規化遅延時間
ｄ：入力信号の正規化先行時間、または正規化遅延時間
Ｄ１_ｊ：ｊ番目要素増幅器の最大の正規化先行時間
Ｄ２_ｊ：ｊ番目要素増幅器の最大の正規化遅延時間
ｌ：要素増幅器の合成多項式の次数
Ｌ_ｊ：ｊ番目要素増幅器の合成多項式の最大次数
ｋ：要素増幅器の歪特性多項式の次数
Ｋ_ｊ：ｊ番目要素増幅器の歪多項式の最大次数 (Distortion compensation algorithm)
Next, details of the lookup table 23 of the predistorter 301 will be described. FIG. 4 is a diagram modeling an amplifier circuit composed of a plurality of amplifiers. An input signal X is input and an output signal Y is output. Here, the discrete-time signals obtained by sampling the input signal X and the output signal Y with the period T _s are x (nT _s ) and y (nT _s ), respectively, and x (n) for simplicity of description. And y (n). Further, both x (n) and y (n) are complex signals having a real component and an imaginary component, and multiplication and addition for x (n) and y (n) indicate complex multiplication and complex addition, respectively. Shall. That is, in FIGS. 1 and 2 described above, a complex signal is input to the distortion compensation circuit 11, and an unillustrated quadrature modulator and D / A conversion are provided between the distortion compensation circuit 11 and the compensated circuit 401. And a down converter (not shown), an A / D converter, and a quadrature demodulator between the compensated circuit 401 and the control unit 13. A plurality of look-up tables are used to obtain distortion compensation values of the amplifier modeled as shown in FIG. In other words, the distortion characteristic polynomial representing the distortion characteristics of the element amplifiers constituting the amplifier is

And the ratio of combining the element amplifiers is a function of the amplitude value of the input signal (synthesis polynomial)

4, the input signal at the same sampling time and the term having the intensity of the input signal are grouped together as shown in Expression 7. By this polynomial classification, a plurality of lookup tables for calculating a part of the distortion compensation value from the intensity of the input signal can be created.

Here, the definition of each parameter is organized.
j: Element amplifier number J: Total number of element amplifiers r: Normalization lead time or normalized delay time R1 _j : Maximum normalized lead time R2 _{j of} the composite polynomial corresponding to the jth element amplifier _j : jth element amplifier The maximum normalization delay time d of the composite polynomial corresponding to: d: the normalization leading time of the input signal, or the normalization delay time D1 _j : the maximum normalization leading time D2 _{j of the} jth element amplifier: the maximum of the jth element amplifier Normalization delay time l: The order of the synthesis polynomial of the element amplifier L _j : The maximum order of the synthesis polynomial of the j-th element amplifier k: The order of the distortion characteristic polynomial of the element amplifier K _j : The maximum order of the distortion polynomial of the j-th element amplifier

である。なお、ここでｍａｘ（ｃ１、ｃ２、・・・、ｃＪ）はｃ１、ｃ２、・・・、ｃＪの最大値である。 Here, Formula 3 is arranged. First, the same terms for different amplifiers (different j)

It is. Here, max (c1, c2,..., CJ) is the maximum value of c1, c2,.

である。 Next, if the term of r = d of Formula 4 is put together,

It is.

である。 Equation 5 is

It is.

である。 further,

It is.

Here, a distortion compensation method for an amplifier having a distortion characteristic polynomial modeled by Expression 3 obtained by rearranging Expression 3 and Expression 3 will be described. The relationship between the input signal of the entire amplifying apparatus and the corresponding output signal is y (n) = Gx (n)
Ideally, it should be linear. Here, G is a real constant representing the gain of the amplifier. Here, G = 1 is set for the purpose of simplifying the following discussion.

を満たす複素数係数ｗ’_ｄ，ｋ、ｗ’_{ｒ，ｄ，ｌ}、およびｗ’_{ｒ，ｄ，ｌ，ｋ}を求め、歪補償回路１１において、

なる予歪補償信号Ａのａ（ｎ）を出力すればよい。ここで、数式８を満たす係数ｗ’_ｄ，ｋ、ｗ’_{ｒ，ｄ，ｌ}、およびｗ’_{ｒ，ｄ，ｌ，ｋ}を求めるには、係数の個数よりも多い個数Ｎの入力信号ｘ（ｎ）と出力信号ｙ（ｎ）の組を数式８のｘ（ｎ）とｙ（ｎ）に代入してＮ個の連立方程式を作成し、掃き出し法、あるいは最小２乗法などで解けばよい。 However, in an actual amplifying device, when the amplitude (or power) of the input signal increases, the relationship between the input and output signals is not linear, but becomes nonlinear as expressed in Formula 3 or Formula 7 in which Formula 3 is arranged. On the other hand, when the relationship between the input signal and the output signal is ideal in Equation 3 or Equation 7, the relationship y (n) = x (n) is established. Therefore, in order to compensate the distortion of the amplifier circuit based on the model of FIG. 4, the input signal X and the output signal Y are interchanged in Equation 3 or Equation 7, which is a distortion characteristic polynomial expressing the model of FIG.

Complex number coefficients w ′ _{d, k} , w ′ _{r, d, l} and w ′ _{r, d, l, k} satisfying

A (n) of the predistortion compensation signal A may be output. Here, in order to obtain the coefficients w ′ _{d, k} , w ′ _{r, d, l} and w ′ _{r, d, l, k} satisfying Expression 8, the number N of input signals x () is larger than the number of coefficients. n) and a set of output signals y (n) are substituted into x (n) and y (n) in Equation 8 to create N simultaneous equations and solved by the sweep-out method or the least square method.

However, in actuality, the number of x's that is larger than the number of coefficients necessary to obtain the coefficients w ′ _{d, k} , w ′ _{r, d, l} , and w ′ _{r, d, l, k} satisfying Equation 8 is satisfied. Even if a set of (n) and y (n) can be secured, there is a case where the accuracy of the distortion compensation amount cannot be sufficiently secured due to the influence of noise. Therefore, N is more than the number of coefficients w ′ _{d, k} , w ′ _{r, d, l} , and w ′ _{r, d, l, k} for the purpose of improving the accuracy of the distortion compensation amount even under the influence of noise. Often increased significantly. However, in reality, there is a case where a sufficient amount of memory for holding x (n) and y (n) cannot be secured and the accuracy of distortion compensation cannot be obtained sufficiently. In such a case, the coefficients w ′ _{d, k} , w ′ _{r, d, l} , and w ′ _{r, d, l, k} can be determined and N x can be stored in the memory. Create simultaneous equations with a set of (n) and y (n) to obtain coefficients w ′ _{d, k} , w ′ _{r, d, l} , and w ′ _{r, d, l, k} and update with adaptive signal processing To do.

(Configuration and processing of first control unit)
FIG. 5 is a block diagram illustrating the first control unit 13-1 according to the present invention. The control unit 13-1 includes an update unit 131-1, a first storage unit 132-1, a second storage unit 133-1, a comparison unit 134-1 and a selection unit 135-1.

  The updating unit 131-1 updates the lookup table so that the relationship between the input signal X and the output signal Y is linear, and performs the processing described with reference to FIGS. 1 to 4.

  The 1st preservation | save part 132-1 preserve | saves the 1st preservation | save lookup table 1321-1 and its 1st characteristic evaluation value 1322-1, and is provided with the 1st counter 1323-1. The second storage unit 133-1 stores the second storage lookup table 1331-1 and the second characteristic evaluation value 1332-1 and includes a second counter 1333-1.

  The comparison unit 134-1 stores the first storage lookup table 1321-1 stored in the first storage unit 132-1 at the first timing every time the update unit 131-1 adds the predetermined number of times. The look-up table updated by the update unit 131-1 is overwritten, and the characteristics of the second storage lookup table 1331-1 stored in the second storage unit 133-1 are updated by the update unit 131-1. Compared with the characteristics of the table, a lookup table having higher characteristics is stored in the second storage unit 133-1. That is, the comparison unit 134-1 discards the first storage lookup table 1321-1 stored in the first storage unit 132-1 at the first timing.

  The comparison unit 134-1 is a second storage lookup table 1331- stored in the second storage unit 133-1 at a second timing in which the number of updates of the update unit 131-1 after the first timing is less than a predetermined number. 1 is overwritten with the updated lookup table of the updating unit 131-1 and the characteristics of the first storage lookup table 1321-1 stored in the first storage unit 132-1 are updated by the updating unit 131-1. Compared with the characteristics of the lookup table, a lookup table having higher characteristics is stored in the first storage unit 132-1. That is, the comparison unit 134-1 discards the second storage lookup table 1331-1 stored in the second storage unit 133-1 at the second timing.

  The comparison unit 134-1 updates the characteristics of the first storage lookup table 1321-1 stored in the first storage unit 132-1 at a timing other than the first timing and the second timing. Compared with the characteristics of the look-up table, a look-up table with high characteristics is stored in the first storage unit 132-1, and the second storage lookup table 1331-1 stored in the second storage unit 133-1 is stored. Are compared with the characteristics of the look-up table updated by the updating unit 131-1, and the look-up table having high characteristics is stored in the second storage unit 133-1.

  When the comparison unit 134-1 stores the first storage lookup table 1321-1 and the second storage lookup table 1331-1 in the first storage unit 132-1 and the second storage unit 133-1, respectively, The characteristic evaluation value 1322-1 and the second characteristic evaluation value 1332-1 are stored in the first storage unit 132-1 and the second storage unit 133-1, respectively.

  When the comparing unit 134-1 determines the superiority or inferiority of the lookup table updated by the first storage lookup table 1321-1 and the updating unit 131-1, the first characteristic evaluation value 1322-1 is determined by the updating unit 131-1. Compare with the updated lookup table characterization value. When the comparing unit 134-1 determines the superiority or inferiority of the lookup table updated by the second storage lookup table 1331-1 and the updating unit 131-1, the second characteristic evaluation value 1332-1 is determined by the updating unit 131-1. Compare with the updated lookup table characterization value.

  The selection unit 135-1 includes a first storage lookup table 1321-1 and a second storage lookup table 1331-1 stored in the first storage unit 132-1 and the second storage unit 133-1, respectively, and an update unit. One of the updated lookup tables 131-1 is selected as a lookup table to be loaded into the distortion compensation circuit 11.

  The selection unit 135-1 stores the first storage stored in the first storage unit 132-1 or the second storage unit 133-1 when the updated lookup table of the update unit 131-1 has failed, or When there is a load request for the lookup table 1321-1 or the second saved lookup table 1331-1, the first saved lookup table 1321-1 or the second saved lookup table 1331-1 is selected.

  The selection unit 135-1 stores the first storage stored in the first storage unit 132-1 or the second storage unit 133-1 when the updated lookup table of the update unit 131-1 has not failed. When there is no load request for the lookup table 1321-1 or the second saved lookup table 1331-1, the update lookup table is selected.

  The selection unit 135-1 selects the first storage lookup table 1321-1 or the second storage lookup table 1331-1 stored in the first storage unit 132-1 or the second storage unit 133-1, respectively. Sometimes, the following processing is executed.

  When the time from the most recent first timing to the selection time is longer than the time from the most recent second timing to the selection time, the selection unit 135-1 saves the first storage stored in the first storage unit 132-1. The lookup table 1321-1 is selected.

  When the time from the most recent second timing to the selection time is longer than the time from the most recent first timing to the selection time, the selection unit 135-1 saves the second storage stored in the second storage unit 133-1. Lookup table 1331-1 is selected.

  The first counter 1323-1 resets the counter value at the first timing, increments the counter value every time the update unit 131-1 updates the lookup table, and the counter value becomes equal to the predetermined number of times described above. When it arrives, the next first timing is notified to the comparison unit 134-1. The comparison unit 134-1 can execute the above-described processing according to whether the current time is the first timing or another timing.

  The second counter 1333-1 resets the counter value at the second timing, increments the counter value every time the updating unit 131-1 updates the lookup table, and the counter value becomes equal to the predetermined number of times described above. When it arrives, the next second timing is notified to the comparison unit 134-1. The comparison unit 134-1 can execute the above-described processing according to whether the current time is the second timing or another timing.

  FIG. 6 is a flowchart illustrating the comparison unit 134-1 in the first control unit 13-1 according to the present invention. The first counter 1323-1 and the second counter 1333-1 increment the counter value every time the updating unit 131-1 updates the lookup table (step S1-1).

  A case where the counter value of the first counter 1323-1 coincides with the first timing will be described (YES in step S2-1). The comparison unit 134-1 overwrites the updated lookup table of the update unit 131-1 on the first saved lookup table 1321-1 stored in the first storage unit 132-1, and the first storage unit 132- The first stored lookup table 1321-1 stored in 1 is discarded (step S4-1).

  The case where the counter value of the first counter 1323-1 does not coincide with the first timing will be described (NO in step S2-1). The comparison unit 134-1 compares the characteristic of the first storage lookup table 1321-1 stored in the first storage unit 132-1 with the characteristic of the updated lookup table of the update unit 131-1 (Step S134-1). S3-1).

  When the characteristic of first storage lookup table 1321-1 stored in first storage unit 132-1 is lower than the characteristic of the lookup table updated by update unit 131-1 (YES in step S3-1). The comparison unit 134-1 overwrites the updated lookup table of the update unit 131-1 on the first saved lookup table 1321-1 stored in the first storage unit 132-1 (step S4-1).

  When the characteristic of the first storage lookup table 1321-1 stored in the first storage unit 132-1 is higher than the characteristic of the updated lookup table of the update unit 131-1 (NO in step S3-1). The first storage lookup table 1321-1 stored in the first storage unit 132-1 is stored as it is.

  A case where the counter value of the second counter 1333-1 coincides with the second timing will be described (YES in step S <b> 5-1). The comparison unit 134-1 overwrites the second storage lookup table 1331-1 stored in the second storage unit 133-1 with the lookup table updated by the update unit 131-1, and the second storage unit 133- The second stored lookup table 1331-1 stored in 1 is discarded (step S7-1).

  A case where the counter value of the second counter 1333-1 does not coincide with the second timing will be described (NO in step S <b> 5-1). The comparison unit 134-1 compares the characteristics of the second storage lookup table 1331-1 stored in the second storage unit 133-1 with the characteristics of the updated lookup table of the update unit 131-1. S6-1).

  When the characteristic of second storage lookup table 1331-1 stored in second storage unit 133-1 is lower than the characteristic of the lookup table updated by update unit 131-1 (YES in step S6-1). The comparison unit 134-1 overwrites the lookup table updated by the update unit 131-1 on the second storage lookup table 1331-1 stored in the second storage unit 133-1 (step S7-1).

  When the characteristic of the second storage lookup table 1331-1 stored in the second storage unit 133-1 is higher than the characteristic of the lookup table updated by the update unit 131-1 (NO in step S6-1). The second storage lookup table 1331-1 stored in the second storage unit 133-1 is stored as it is.

  FIG. 7 shows a flowchart for explaining the selection unit 135-1 in the first control unit 13-1 according to the present invention. The selection unit 135-1 is notified from the update unit 131-1 of updated lookup table failure information indicating that the updated lookup table of the update unit 131-1 has failed (step S11-1). The selection unit 135-1 loads the first storage lookup table 1321-1 or the second storage lookup table 1331-1 stored in the first storage unit 132-1 or the second storage unit 133-1, respectively. Is notified from an upper module (not shown in FIG. 5) (step S11-1).

  When notified of the updated lookup table failure information or the stored lookup table load request (YES in step S11-1), the selection unit 135-1 is notified of the first stored lookup table 1321-1 or the second stored lookup. The table 1331-1 is loaded into the distortion compensation circuit 11 (step S13-1).

  Here, when the time from the most recent first timing to the selection time is longer than the time from the most recent second timing to the selection time, the selection unit 135-1 uses the first storage lookup table 1321-1 as the distortion compensation circuit. 11 is loaded. When the time from the most recent second timing to the selection time is longer than the time from the most recent first timing to the selection time, the selection unit 135-1 stores the second storage lookup table 1331-1 in the distortion compensation circuit 11. To load. At this time, the selection unit 135-1 refers to the counter values of the first counter 1323-1 and the second counter 1333-1, so that the time from the most recent first timing and the most recent second timing to the selection time, respectively. Can be measured.

  When the update lookup table failure information and the stored lookup table load request are not notified (NO in step S11-1), the selection unit 135-1 loads the update lookup table into the distortion compensation circuit 11 (step S12). -1).

  One storage unit stores the updated lookup table when the stored lookup table is discarded, but the updated lookup table is not necessarily a lookup table with high characteristics. The other storage unit stores a lookup table having a high characteristic through a comparison of the characteristics of the lookup table from when the saved lookup table was last discarded until the time point. Therefore, the distortion compensation circuit 11 loads a look-up table with high characteristics from one storage unit rather than one storage unit. Therefore, the present invention can provide a predistorter that reduces the memory amount by discarding the preliminary look-up table that is no longer appropriate as time passes.

(Configuration and processing of second control unit)
FIG. 8 is a block diagram illustrating the second control unit 13-2 according to the present invention. The control unit 13-2 includes an update unit 131-2, a first storage unit 132-2, a second storage unit 133-2, a comparison unit 134-2, a selection unit 135-2, and a counter 136-2.

  The configurations of the update unit 131-2, the comparison unit 134-2, and the selection unit 135-2 correspond to the configurations of the update unit 131-1, the comparison unit 134-1, and the selection unit 135-1, respectively.

  The first storage unit 132-2 stores the first storage lookup table 1321-2, the first characteristic evaluation value 1322-2, and the first discard timing 1323-2. The second storage unit 133-2 stores the second storage lookup table 1331-2, the second characteristic evaluation value 1332-2, and the second discard timing 1333-2.

  The counter 136-2 resets the counter value at the first timing, and increments the counter value every time the updating unit 131-2 updates the lookup table. The counter 136-2 compares the second timing following the first timing when the counter value reaches a value equal to the number of updates of the updating unit 131-2 from the first timing to the second timing following the first timing. Notification to the unit 134-2. When the counter value reaches a value equal to the predetermined number of times, the counter 136-2 notifies the comparison unit 134-2 of the next first timing. The comparison unit 134-2 can execute the above-described processing according to whether the current time is the first timing, the second timing, or another timing.

  The first timing at which the counter value of the counter 136-2 reaches a value equal to the predetermined number of times described above is stored in the first storage unit 132-2 as the first discard timing 1323-2. The second timing that the counter value of the counter 136-2 has reached a value equal to the number of updates of the updating unit 131-2 from the first timing to the second timing following the first timing is a second discard timing 1333-2. It is stored in the second storage unit 133-2.

  FIG. 9 shows a flowchart illustrating the comparison unit 134-2 in the second control unit 13-2 according to the present invention. Steps S1-2, S2-2, S3-2, S4-2, S5-2, S6-2, and S7-2 in FIG. 9 are respectively performed in steps S1-1, S2-1, S3-1, and FIG. This corresponds to S4-1, S5-1, S6-1, and S7-1.

  FIG. 10 shows a flowchart for explaining the selection unit 135-2 of the second control unit 13-2 according to the present invention. Steps S11-2, S12-2, and S13-2 in FIG. 10 correspond to steps S11-1, S12-1, and S13-1 in FIG. 7, respectively.

  The effect of the second control unit 13-2 is substantially the same as the effect of the first control unit 13-1. The second controller 13-2 only needs to include one counter 136-2.

(Other configuration and processing)
In the first and second control units 13-1 and 13-2, the number of updates of the update units 131-1 and 131-2 from the first timing to the second timing following the first timing is greater than the predetermined number of times described above. Less. In another configuration and process, the number of updates of the update units 131-1 and 131-2 from the first timing to the second timing following the first timing may be made equal to half the number of times described above. The distortion compensation circuit 11 may always load a lookup table having a high characteristic stored through a comparison of the characteristics of the lookup table over half of the above-mentioned predetermined number of times from any storage unit. it can.

  The comparison units 134-1 and 134-2 determine that the characteristics of the lookup table are high when the difference between the predistortion compensation signal A and the output calculation signal generated by the lookup table based on the output signal Y is small. Can do. Thereby, the relationship between the input signal X and the output signal Y can be made linear. The comparison units 134-1 and 134-2 determine that the characteristics of the lookup table are high when the adjacent channel leakage power ratio indicating the ratio of the output signal Y leaking to a frequency channel deviating from a predetermined frequency channel is small. be able to. Thereby, the distortion of the frequency spectrum of the output signal Y can be eliminated.

  The predistorter according to the present invention can be applied to a power amplifier of a radio transmitter used in a mobile communication base station or the like.

301, 302: Predistorter 11: Distortion compensation circuit 13: Control unit 21: Delay element 22: Intensity calculation unit 23, 23-0, 23-5, 23-11, 23-13: Look-up table 24: Complex multiplication Device 31: Delay units 32, 32-0, 32-5, 32-11, 32-13: Distortion signal generation unit 33: Distortion compensation value generation unit 131-1 and 131-2: Update units 132-1, 132- 2: 1st preservation | save part 133-1, 133-2: 2nd preservation | save part 134-1, 134-2: Comparison part 135-1, 135-2: Selection part 136-2: Counter 1321-1, 1321-2 : First storage lookup tables 1322-1 and 1322-2: first characteristic evaluation value 1323-1: first counter 1322-2: first discard timing 1331-1, 1331-2: second storage lookup table 133 -1,1332-2: second characteristic evaluation value 1333-1: second counter 1333-2: second discard timing 401: the compensation circuit 511: delay elements 512-j: amplitude value function (j is a natural number)
513: Element amplifier 514: Complex multiplier 515: Accumulator X: Input signal Y: Output signal A: Predistortion compensation signals S, S-0, S-5, S-9, S-11, S-13: Sampling Signal H, H-0, 0, H-9, 5, H-11, 17: Distortion signal

Claims (6)

A distortion compensation circuit for outputting a predistortion compensation signal generated based on the lookup table and the input signal to the compensated circuit;
An update unit for updating a lookup table so that a relationship between the input signal and the output signal of the compensated circuit is linear;
A first storage unit and a second storage unit that store the lookup tables separately;
The update table updated by the update unit is overwritten on the lookup table stored in the first storage unit at a first timing each time the update number of the update unit adds a predetermined number of times. Comparing the characteristics of the lookup table stored in the storage unit with the characteristics of the updated lookup table in the update unit, and storing the lookup table having a high characteristic in the second storage unit;
At the second timing when the number of updates of the update unit after the first timing is less than the predetermined number of times, the look-up table stored in the second storage unit is overwritten with the look-up table updated by the update unit. Comparing the characteristics of the lookup table stored in the first storage unit with the characteristics of the updated lookup table of the update unit, and storing the lookup table having a high characteristic in the first storage unit,
Compare the characteristics of the look-up table stored in the first storage unit with the characteristics of the look-up table updated by the update unit at a timing other than the first timing and the second timing. The table is stored in the first storage unit, and the characteristics of the lookup table stored in the second storage unit are compared with the characteristics of the updated look-up table in the update unit. A comparison unit stored in the second storage unit;
In selecting one of the lookup table stored in the first storage unit and the second storage unit and the updated lookup table of the update unit as a lookup table to be loaded into the distortion compensation circuit, When selecting the lookup table stored in the first storage unit or the second storage unit, the time from the most recent first timing to the selection time is longer than the time from the most recent second timing to the selection time. If the lookup table stored in the first storage unit is selected, and the time from the most recent second timing to the selection time is longer than the time from the most recent first timing to the selection time, A selection unit for selecting a lookup table stored in the second storage unit;
A predistorter characterized by comprising: The counter value is reset at the first timing, and the counter value is incremented every time the update unit updates the look-up table. When the counter value reaches a value equal to the predetermined number of times, the next first A first counter for notifying the timing to the comparison unit;
The counter value is reset at the second timing, and the counter value is incremented every time the update unit updates the look-up table. When the counter value reaches a value equal to the predetermined number of times, the next second A second counter for notifying the timing to the comparison unit;
The predistorter according to claim 1, further comprising: The counter value is reset at the first timing, and the counter value is incremented every time the update unit updates the look-up table. The counter value is from the first timing to the second timing following the first timing. When a value equal to the number of updates of the update unit is reached, the second timing following the first timing is notified to the comparison unit, and when the counter value reaches a value equal to the predetermined number of times, A counter for notifying the comparison unit of the first timing;
The predistorter according to claim 1, further comprising:   The number of updates of the update unit from the first timing to the second timing following the first timing is equal to a half of the predetermined number of times. One of the predistorters. The comparison unit, wherein the predistortion compensation signal and the look-up table and output calculation signal generated based on the output signal, the when the difference is small, determining that high characteristics of a look-up table The predistorter according to any one of claims 1 to 4.   The comparison unit may determine that the characteristics of the lookup table are high when the adjacent channel leakage power ratio indicating the ratio of leakage of the output signal to a frequency channel deviating from a predetermined frequency channel is small. The predistorter according to any one of claims 1 to 4.

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