JPH08251246A - Transmitter - Google Patents

Abstract

PURPOSE: To suppress and highly accurately compensate nonlinear distortion generated in an amplifier relating to the communication equipment of a radio communication system using a digital modulation system. CONSTITUTION: This transmitter is provided with a power calculation part 102 for obtaining the power of transmission signals from digitally modulated transmission orthogonal base band signals 101 by calculation, a table reference part 014 for referring to a prepared nonlinear distortion compensation table by using the value 103 of the calculated power and a nonlinear distortion compensation part 106 for compensating the nonlinear distortion of the orthogonal base band signals by using complex distortion compensation data 105 referred to. Then, by referring to the table by using the power value 103 of the transmission signals, the size of the table reference part 104 is substantially reduced. Also, by compensating the nonlinear distortion by using a digital complex product in the nonlinear distortion compensation part 106, the effect of an analog circuit is suppressed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmitter for use in a communication device of a wireless communication system using a digital modulation method, and compensating for non-linear distortion generated in an amplifier of a transmission system with a simple calculation and a small number of reference tables. It is a thing.

[0002]

2. Description of the Related Art In recent years, research and development of mobile communication systems using a digital modulation method have been actively conducted. If a high efficiency amplifier is applied to the transmission system in order to save power in the wireless terminal, a large amount of nonlinear distortion is likely to occur. Therefore, it is necessary to compensate the nonlinear distortion by some method,
As one means, there is a method of performing non-linear distortion compensation of amplitude and phase by referring to the distortion compensation table using the value of the transmission baseband signal.

A conventional transmitter will be described below.
FIG. 8 shows a block configuration of a conventional transmitter. In FIG. 8, 801 is a transmission digital quadrature baseband signal. Reference numeral 802 is a reference table for nonlinear distortion compensation, 803 is amplitude distortion compensation data, and 804 is phase distortion compensation data. Reference numeral 805 is a D / A converter for converting digital data into an analog value, and 806 is a converted analog quadrature baseband signal. Reference numeral 807 is a low pass filter for band limiting the transmission signal, and 808 is a band limited orthogonal baseband signal. Reference numeral 809 is a quadrature modulator, and 810 is a modulated signal. Reference numeral 811 is a gain control amplifier for amplitude distortion compensation, 812 is a modulation signal for amplitude distortion compensation, 813 is a phase shifter for phase distortion compensation, 814 is a modulation signal for amplitude and phase shift distortion compensation, and 816 is a transmission system. , 817 is a transmission modulation signal.

The operation of the transmitting apparatus configured as described above will be described below. First, the transmission digital quadrature baseband signal 801 is transmitted to the D / A converter 805.
Is converted into an analog value by the low-pass filter 807, and is then quadrature-modulated by the quadrature modulator 809 to be a modulated signal 810. At the same time, the reference table 802 is referred to using the value of the transmission digital quadrature baseband signal 801 as an address to obtain amplitude distortion compensation data 803 and phase distortion compensation data 804.

Next, the gain control amplifier 811 performs amplitude distortion compensation using the amplitude distortion compensation data 803, and the phase shifter 81
In step 3, phase distortion compensation data 804 is used to perform phase distortion compensation, and an amplitude and phase distortion compensated modulated signal 814 is obtained.

Finally, the amplitude and phase distortion-compensated modulation signal 814 is amplified by a transmission system amplifier 816 to output a transmission modulation signal 817.

[0007]

However, in the above-mentioned conventional configuration, an address having twice the number of bits of the data of the digital quadrature baseband signal is required, so that the lookup table for nonlinear distortion compensation becomes very large. However, there are problems that the gain control amplifier and the phase shifter itself need to be distortion-free.

The present invention solves the above-mentioned conventional problems, and compensates for the non-linear distortion generated in the amplifier of the transmission system with a simple calculation and a small number of reference tables in a communication device of a wireless communication system using a digital modulation method. It is an object of the present invention to provide a transmission device that

[0009]

In order to achieve this object, a transmitter of the present invention comprises a power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal and a calculated power. A table reference unit that uses a value to refer to a non-linear distortion compensation table prepared in advance, and a non-linear distortion compensation unit that performs non-linear distortion compensation of the orthogonal baseband signal using the referred non-linear distortion compensation data are provided. It has a configuration in which the non-linear distortion compensation table is referred to using the power value and the non-linear distortion is compensated by digital operation using complex data.

[0010]

With this configuration, the size of the lookup table can be greatly reduced. In addition, since the nonlinear distortion compensation is performed by digital complex operation without using the gain control amplifier and the phase shifter which are analog circuits, it is not necessary to consider the distortion of the gain control amplifier and the phase shifter, and a simple digital operation is possible. Thus, non-linear distortion compensation can be realized.

[0011]

【Example】

(Embodiment 1) Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block connection diagram of a transmission device according to a first embodiment of the present invention.

In FIG. 1, 101 is a transmission digital quadrature baseband signal, 102 is a power calculation unit, 103 is an amplitude value calculated by the power calculation unit 102, 104 is a reference table for nonlinear distortion compensation, and 105 is an orthogonalized nonlinear. Distortion compensation data, 106 is a non-linear distortion compensator, 107 is a non-linear distortion-compensated quadrature baseband signal, 108 is a D / A converter, 109 is an analog quadrature baseband signal, 110
Is a low pass filter for band limiting, 111 is a band limited analog quadrature baseband signal, 112 is a quadrature modulator, 113 is a modulation signal, 114 is a transmission system amplifier, 11
Reference numeral 5 is an amplified transmission modulation signal.

The operation of the transmitter configured as described above will be described with reference to FIG.

First, the power calculator 102 calculates the amplitude value 103 of the transmission signal from the transmission digital quadrature baseband signal 101. Next, the calculated amplitude value 103 of the transmission signal is used as an address to refer to the reference table 104 for nonlinear distortion compensation, and the nonlinear distortion obtained by orthogonalizing the nonlinear distortion compensation data having the inverse characteristic of the nonlinear distortion characteristic of the transmission system calculated in advance. Obtained as compensation data 105.

The nonlinear distortion compensating unit 106 performs a complex product of the transmission digital quadrature baseband signal 101 and the orthogonalized nonlinear distortion compensation data 105, and outputs a nonlinear distortion-compensated orthogonal baseband signal 107. The non-linear distortion-compensated quadrature baseband signal 107 is converted into an analog signal by the D / A conversion unit 108 and band-limited by the low-pass filter 110.
Get.

Then, the quadrature modulator 112 performs quadrature modulation to form a modulated signal 113, which is then amplified by a transmission system amplifier 114 to a required level and output as a transmission modulated signal 115.

As described above, according to the present embodiment, the power calculation unit 10
2. A reference table 104 for non-linear distortion compensation and a non-linear distortion compensating unit 106 are provided, and the reference table 104 for non-linear distortion compensation is referred to by the amplitude value 103 of the transmission digital quadrature baseband signal 101. Non-linear distortion compensation data 105 orthogonalized to
By performing the complex product of
Non-linear distortion generated in the amplifier of the transmission system can be compensated with a simple calculation and a small number of reference tables.

(Second Embodiment) A second embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is a block connection diagram of a transmission device according to the second embodiment of the present invention.

In FIG. 2, 201 is a transmission digital quadrature baseband signal, 202 is a power calculation unit, 203 is an amplitude value calculated by the power calculation unit 202, 204 is a reference table for amplitude distortion compensation, and 205 is amplitude distortion compensation data. Two
Reference numeral 06 is a D / A conversion unit, 207 is an analog quadrature baseband signal, 208 is a low pass filter for band limitation, and 20
9 is a band-limited analog quadrature baseband signal, 2
Reference numeral 10 is a quadrature modulator, 211 is a modulation signal, 212 is a gain control amplifier for amplitude distortion compensation, 213 is an amplitude distortion compensated modulation signal, 214 is a transmission system amplifier, and 215 is an amplified transmission modulation signal.

The operation of the transmitting apparatus configured as above will be described with reference to FIG.

First, the power calculator 202 calculates the amplitude value 203 of the transmission signal from the transmission digital quadrature baseband signal 201. Next, using the calculated amplitude value 203 of the transmission signal as an address, a reference table 2 for amplitude distortion compensation
04, the amplitude distortion compensation data 205 having the inverse characteristic of the amplitude distortion characteristic of the transmission system calculated in advance is obtained.

On the other hand, the transmission digital quadrature baseband signal 201 is converted into an analog signal by the D / A converter 206, and the band is limited by the low-pass filter 208 to obtain an analog quadrature baseband signal 209.

After the quadrature modulator 210 performs quadrature modulation to form a modulated signal 211, the gain control amplifier 212 for amplitude distortion compensation performs amplitude distortion compensation on the basis of the amplitude distortion compensation data 205, and the amplitude distortion compensated modulation is performed. The signal 213 is obtained. Finally, the amplifier 214 amplifies the signal to a required level and outputs the transmission modulation signal 215.

As described above, according to the present embodiment, the power calculation unit 20
2. A reference table 204 for amplitude distortion compensation and a gain control amplifier 212 for amplitude distortion compensation are provided, the reference table 204 for amplitude distortion compensation is referred to by the amplitude value 203 of the transmission digital quadrature baseband signal 201, and the modulated signal 211 By performing amplitude distortion compensation by the gain control amplifier 212 for amplitude distortion compensation based on the amplitude distortion compensation data 205, the amplitude generated in the amplifier of the transmission system can be compensated by a simple calculation and a small number of reference tables. .

(Embodiment 3) A third embodiment of the present invention will be described below with reference to the drawings. FIG. 3 is a block connection diagram of a transmitting apparatus according to the third embodiment of the present invention.

In FIG. 3, reference numeral 301 is a transmission digital quadrature baseband signal, 302 is a power calculation unit, 303 is an amplitude value calculated by the power calculation unit 302, 304 is a reference table for nonlinear distortion compensation, and 305 is orthogonalized nonlinear. Distortion compensation data, 306 is a non-linear distortion compensation unit, 307 is a non-linear distortion-compensated orthogonal baseband signal, 308 is a D / A conversion unit, 309 is an analog orthogonal baseband signal, 310
Is a low pass filter for band limitation, 311 is a band limited analog quadrature baseband signal, 312 is a quadrature modulator, 313 is a modulation signal, 314 is a transmission system amplifier, 31
5 is an amplified transmission modulation signal, 316 is a distributor, 317 is a transmission modulation signal that has been distributed, 318 is a quadrature detection unit, 319
Is a quadrature baseband signal subjected to quadrature detection, 320 is a low pass filter for band limitation, 321 is a quadrature baseband signal with band limitation, 322 is an A / D converter, 323 is a digital quadrature baseband signal, and 324 is data. A delay unit, 325 is a delayed transmission digital quadrature baseband signal, 326 is a delayed amplitude value, 327 is an error calculation unit, 328 is an orthogonal error signal calculated by the error calculation unit 327, 329 is a reference table update unit, Reference numeral 330 is orthogonal distortion compensation data.

The operation of the transmitting apparatus configured as described above will be described with reference to FIG.

First, the power calculator 302 calculates the amplitude value 303 of the transmission signal from the transmission digital quadrature baseband signal 301. Next, the calculated amplitude value 303 of the transmission signal is used as an address to refer to the reference table 304 for non-linear distortion compensation, and the non-linear distortion obtained by orthogonalizing the non-linear distortion compensation data having the inverse characteristic of the non-linear distortion characteristic of the transmission system calculated in advance. Obtained as compensation data 305.

The non-linear distortion compensating section 306 performs a complex product of the transmission digital quadrature baseband signal 301 and the non-linear distortion compensation data 305 orthogonalized, and outputs a non-linear distortion compensated quadrature baseband signal 307. The D / A conversion unit 308 converts the non-linear distortion-compensated quadrature baseband signal 307 into an analog signal, and the low-pass filter 310 limits the band.
Get.

Then, the quadrature modulator 312 performs quadrature modulation to form a modulation signal 313, which is then amplified by a transmission system amplifier 314 to a required level and output as a transmission modulation signal 315.
At this time, the distributor 316 distributes the transmission modulation signal 315. The distributed transmission modulation signal 317 is quadrature-detected by the quadrature detection unit 318, passed through the low-pass filter 320 for band limitation, and then converted into a digital signal by the A / D conversion unit 322 to convert the digital quadrature baseband signal 323. obtain.

On the other hand, the data delay unit 324 delays the transmission digital quadrature baseband signal 301 and the amplitude value 303 of the transmission signal by the time constant of the feedback loop, and delays the transmission digital quadrature baseband signal 3
25 and the delayed amplitude value 326 is output. The error calculator 327 takes the difference between the digital quadrature baseband signal 323 and the delayed transmission digital quadrature baseband signal 325 and outputs it as a quadrature error signal 328.

In the reference table updating unit 329, the orthogonalized non-linear distortion compensation data 33 is referred to by using the delayed amplitude value 326 as an address based on the orthogonal error signal 328.
Update 0.

As described above, according to this embodiment, the power calculator 30
2. A reference table 304 for non-linear distortion compensation, a non-linear distortion compensator 306, a distributor 316, a quadrature detector 318, a data delay unit 324, an error calculator 327, and a reference table update unit 329 are provided to transmit digital quadrature baseband signals. Three
The nonlinear distortion compensation reference table 304 is referred to by the amplitude value 303 of 01, and the nonlinear distortion compensation unit 306 performs a complex product of the transmitted digital quadrature baseband signal 301 and the orthogonalized distortion compensation data 305. The digital quadrature baseband signal 323 obtained by the quadrature detection by the quadrature detection unit 318, which is distributed, and the data delay unit 32.
Transmission digital quadrature baseband signal 3 delayed by 4
The difference of 01 is taken by the error detection unit 327, and the reference table update unit 329 updates the contents of the reference table 304 for nonlinear distortion compensation based on the orthogonal error signal 328, so that the nonlinear distortion compensation in the reference table is compensated. Data error can be reduced by using a feedback loop, and highly accurate nonlinear distortion compensation can be performed.

(Embodiment 4) A fourth embodiment of the present invention will be described below with reference to the drawings. FIG. 4 is a block connection diagram of a transmission device according to the fourth embodiment of the present invention.

In FIG. 4, 401 is a transmission digital quadrature baseband signal, 402 is a power calculation section, 403 is an amplitude value calculated by the power calculation section 402, 404 is a reference table for amplitude distortion compensation, and 405 is amplitude distortion compensation data. Four
Reference numeral 06 is a D / A conversion unit, 407 is an analog quadrature baseband signal, 408 is a low pass filter for band limitation, and 40
9 is a band-limited analog quadrature baseband signal, 4
10 is a quadrature modulator, 411 is a modulation signal, 412 is a gain control amplifier for amplitude distortion compensation, 413 is an amplitude distortion compensated modulation signal, 414 is a transmission system amplifier, 415 is an amplified transmission modulation signal, and 416 is distribution. 417 is a distributed transmission modulation signal, 418 is a quadrature detection unit, 419 is a quadrature baseband signal subjected to quadrature detection, 420 is a low pass filter for band limitation, 421 is a quadrature baseband signal with band limitation, 422 Is an A / D conversion unit, 423 is a digital quadrature baseband signal, 424 is a data delay unit, 425 is a delayed transmission digital quadrature baseband signal, 426 is a delayed amplitude value, 427 is an error calculation unit, 428 is an error. The orthogonal error signal calculated by the calculating unit 427, 429 is a reference table updating unit, and 430 is amplitude distortion compensation data.

The operation of the transmitting apparatus configured as described above will be described with reference to FIG.

First, the power calculator 402 calculates the amplitude value 403 of the transmission signal from the transmission digital quadrature baseband signal 401. Next, using the calculated amplitude value 403 of the transmission signal as an address, the lookup table 4 for amplitude distortion compensation is used.
04, the amplitude distortion compensation data 405 having the inverse characteristic of the amplitude distortion characteristic of the transmission system calculated in advance is obtained.

On the other hand, the transmission digital quadrature baseband signal 401 is converted into an analog signal by the D / A converter 406, and the band is limited by the low pass filter 408 to obtain an analog quadrature baseband signal 409.

Then, the quadrature modulator 410 performs quadrature modulation to form a modulated signal 411, the gain control amplifier 412 for amplitude distortion compensation performs amplitude distortion compensation based on the amplitude distortion compensation data 405, and then the amplifier 414. The transmission modulation signal 415 is output after being amplified to a required size. At this time, the distributor 4
At 16, the transmission modulation signal 415 is distributed. The distributed transmission modulation signal 417 is quadrature-detected by the quadrature detection unit 418, passed through the low-pass filter 420 for band limitation, converted into a digital signal by the A / D conversion unit 422, and the digital quadrature baseband signal 423 is converted. obtain.

On the other hand, in the data delay section 424, the transmission digital quadrature baseband signal 401 and the amplitude value 403 of the transmission signal are delayed by the time constant of the feedback loop, and the delayed transmission digital quadrature baseband signal 4 is delayed.
25 and the delayed amplitude value 426 is output. The error calculator 427 takes the difference between the digital quadrature baseband signal 423 and the delayed transmission digital quadrature baseband signal 425 and outputs it as a quadrature error signal 428.

The reference table updating unit 429 updates the amplitude distortion compensation data 430 referenced with the delayed amplitude value 426 as an address, based on the quadrature error signal 428.

As described above, according to this embodiment, the power calculator 40
2, reference table 404 for amplitude distortion compensation, gain control amplifier 412 for amplitude distortion compensation, distributor 416, quadrature detection unit 4
18, a data delay unit 424, an error calculation unit 427, and a reference table update unit 429 are provided, and the reference signal 404 for amplitude distortion compensation is referred to by the amplitude value 403 of the transmission digital quadrature baseband signal 401, and the modulation signal 411 is subjected to amplitude distortion. Amplitude distortion compensation data 4 by the gain control amplifier 412 for compensation
Amplitude distortion compensation is performed based on 05, the digital quadrature baseband signal 423 obtained by quadrature detection by the quadrature detection section 418, and the data delay section 424.
Transmission digital quadrature baseband signal 40 delayed by
The error detection unit 427 takes the difference of 1 and the reference table updating unit 429 updates the contents of the reference table 404 for amplitude distortion compensation based on the orthogonal error signal 428, thereby compensating for the amplitude distortion in the reference table. Data error can be reduced by using a feedback loop, and highly accurate amplitude distortion compensation can be performed.

(Embodiment 5) Hereinafter, a fifth embodiment of the present invention will be described with reference to the drawings. FIG. 5 is a block connection diagram of a transmitting apparatus according to the fifth embodiment of the present invention.

In FIG. 5, reference numeral 501 is a transmission digital quadrature baseband signal, 502 is a power calculation section, 503 is an amplitude value calculated by the power calculation section 502, 504 is an address reference section which determines an address using the amplitude value 503, 5
Reference numeral 05 is a reference address, 506 is a reference table for nonlinear distortion compensation, 507 is orthogonalized nonlinear distortion compensation data, 508 is a nonlinear distortion compensation unit, 509 is a nonlinear distortion-compensated orthogonal baseband signal, and 510 is D / A converter, 5
Reference numeral 11 is an analog quadrature baseband signal, 512 is a low pass filter for band limitation, 513 is a band limited analog quadrature baseband signal, 514 is a quadrature modulator, 51
5 is a modulation signal, 516 is a transmission system amplifier, 517 is an amplified transmission modulation signal, 518 is a distributor, 519 is a distributed transmission modulation signal, 520 is a quadrature detection unit, 521 is a quadrature detection quadrature baseband signal, 522 is a low-pass filter for band limitation, 523 is a quadrature baseband signal whose band is limited, 524 is an A / D conversion unit, 525 is a digital quadrature baseband signal, 526 is a data delay unit, 527
Is the delayed transmit digital quadrature baseband signal, 5
28 is a delayed amplitude value, 529 is an error calculation unit, 530
Is the orthogonal error signal 531 calculated by the error calculator 529.
Is a reference table updating unit, 532 is address reference unit data, and 533 is orthogonalized nonlinear distortion compensation data.

The operation of the transmitting apparatus configured as above will be described with reference to FIG.

First, the power calculator 502 calculates the amplitude value 503 of the transmission signal from the transmission digital quadrature baseband signal 501. Next, the calculated amplitude value 503 of the transmission signal is used as an address to refer to the address reference unit 504 to perform address conversion. The reference table 506 for non-linear distortion compensation is referenced using the referenced address 505, and the non-linear distortion compensation data having the inverse characteristic of the non-linear distortion characteristic of the transmission system calculated in advance is orthogonalized to the non-linear distortion compensation data 5
Get as 07.

The nonlinear distortion compensator 508 performs a complex product of the transmission digital quadrature baseband signal 501 and the orthogonalized nonlinear distortion compensation data 507, and outputs a nonlinear distortion-compensated orthogonal baseband signal 509. The non-linear distortion-compensated quadrature baseband signal 509 is converted into an analog signal by the D / A conversion unit 510 and band-limited by the low-pass filter 512.
Get.

Then, the quadrature modulator 514 performs quadrature modulation to form a modulation signal 515, which is then amplified by a transmission system amplifier 516 to a required level and output as a transmission modulation signal 517.

At this time, the transmitter modulation signal 5 is transmitted by the distributor 518.
Distribute 17 The distributed transmission modulation signal 519 is quadrature-detected by the quadrature detection unit 520, passed through a low-pass filter 522 for band limitation, converted into a digital signal by an A / D conversion unit 524, and a digital quadrature baseband signal 525.
Get.

On the other hand, in the data delay unit 526, the transmission digital quadrature baseband signal 501 and the amplitude value 503 of the transmission signal are delayed by the time constant of the feedback loop, and the delayed transmission digital quadrature baseband signal 5 is delayed.
27 and the delayed amplitude value 528 are output. The error calculator 529 takes the difference between the digital quadrature baseband signal 525 and the delayed transmission digital quadrature baseband signal 527 and outputs it as a quadrature error signal 530.

The reference table updating unit 531 updates the data 532 of the address reference unit referenced with the delayed amplitude value 528 as an address, using the orthogonal distortion signal 530 and the nonlinear distortion compensation data 533 orthogonalized.

As described above, according to this embodiment, the power calculation unit 50
2, address reference unit 504, reference table 506 for nonlinear distortion compensation, nonlinear distortion compensation unit 508, distributor 518, quadrature detection unit 520, data delay unit 526, error calculation unit 52.
9. The reference table updating unit 531 is provided, the amplitude value 503 of the transmission digital quadrature baseband signal 501 is address-converted by the address reference unit 504, and the reference address 50
5, the nonlinear distortion compensation reference table 506 is used to perform the complex product of the transmission digital quadrature baseband signal 501 and the orthogonalized nonlinear distortion compensation data 507 in the nonlinear distortion compensator 508, and the distributor 518 distributes the complex product. The error detection unit 529 calculates the difference between the digital quadrature baseband signal 525 obtained by quadrature detection by the quadrature detection unit 520 and the transmission digital quadrature baseband signal 501 delayed by the data delay unit 526, and the reference table update unit is obtained. 531, the non-linear distortion compensation data 53 orthogonalized to the orthogonal error signal 530.
3 is used to update the data 532 of the address reference unit which is referred to by using the delayed amplitude value 528 as an address, it becomes possible to configure a feedback loop with a small number of rewritable reference tables. It is possible to perform highly accurate non-linear distortion compensation with various circuit configurations.

(Embodiment 6) A sixth embodiment of the present invention will be described below with reference to the drawings. FIG. 6 is a block connection diagram of a transmission device according to a sixth embodiment of the present invention.

In FIG. 6, 601 is a transmission digital quadrature baseband signal, 602 is a power calculation unit, 603 is an amplitude value calculated by the power calculation unit 602, 604 is an address calculation unit which calculates an address using the amplitude value 603, 6
Reference numeral 05 is a calculated address, 606 is a reference table for nonlinear distortion compensation, 607 is orthogonalized nonlinear distortion compensation data, 608 is a nonlinear distortion compensation unit, 609 is a nonlinear distortion-compensated orthogonal baseband signal, and 610 is D / A converter, 6
11 is an analog quadrature baseband signal, 612 is a low pass filter for band limitation, 613 is a band limited analog quadrature baseband signal, 614 is a quadrature modulator, 61
5 is a modulation signal, 616 is a transmission system amplifier, 617 is an amplified transmission modulation signal, 618 is a distributor, 619 is a distributed transmission modulation signal, 620 is a quadrature detection unit, and 621 is a quadrature-detected quadrature baseband signal, 622 is a low pass filter for band limitation, 623 is a band limited quadrature baseband signal, 624 is an A / D conversion unit, 625 is a digital quadrature baseband signal, 626 is a data delay unit, 627.
Is the delayed transmit digital quadrature baseband signal, 6
28 is a delayed amplitude value, 629 is an error calculator, 630
Is an orthogonal error signal calculated by the error calculation unit 629, 631
Is a coefficient updating unit, and 632 is a coefficient of the address calculating unit.

The operation of the transmitting apparatus configured as described above will be described with reference to FIG.

First, the power calculator 602 calculates the amplitude value 603 of the transmission signal from the transmission digital quadrature baseband signal 601. Next, the address calculation unit 604 performs address conversion using the calculated amplitude value 603 of the transmission signal. By referring to the non-linear distortion compensation reference table 606 using the calculated address 605, the non-linear distortion compensation data having the inverse characteristic of the non-linear distortion characteristic of the transmission system calculated in advance is obtained as the orthogonalized non-linear distortion compensation data 607. .

The nonlinear distortion compensator 608 performs a complex product of the transmission digital quadrature baseband signal 601 and the orthogonalized nonlinear distortion compensation data 607, and outputs a nonlinear distortion-compensated orthogonal baseband signal 609. The non-linear distortion-compensated quadrature baseband signal 609 is converted into an analog signal by the D / A converter 610, and the band is limited by the low-pass filter 612.
Get.

Then, the quadrature modulator 614 performs quadrature modulation to form a modulation signal 615, which is then amplified by a transmission system amplifier 616 to a required level and output as a transmission modulation signal 617.

At this time, the transmission modulation signal 5 is transmitted by the distributor 618.
Distribute 17 The distributed modulation signal 619 is quadrature-detected by the quadrature detection unit 620, passed through a low-pass filter 622 for band limitation, converted into a digital signal by the A / D conversion unit 624, and a digital quadrature baseband signal 625.
Get.

On the other hand, the data delay unit 626 delays the transmission digital quadrature baseband signal 601 and the transmission signal amplitude value 603 by the time constant of the feedback loop, and delays the transmission digital quadrature baseband signal 6
27 and the delayed amplitude value 628 are output. The error calculator 629 takes the difference between the digital quadrature baseband signal 625 and the delayed transmission digital quadrature baseband signal 627 and outputs it as a quadrature error signal 630. The coefficient updating unit 631 updates the coefficient 632 of the address calculation unit based on the orthogonal error signal 630.

As described above, according to this embodiment, the power calculator 60
2, address calculation unit 604, lookup table 606 for nonlinear distortion compensation, nonlinear distortion compensation unit 608, distributor 618, quadrature detection unit 620, data delay unit 626, error calculation unit 62.
9. The coefficient updating unit 631 is provided, the address calculation unit 604 performs address calculation using the amplitude value 603 of the transmission digital quadrature baseband signal 601, and the calculated address 6
05, the nonlinear distortion compensation reference table 606 is used to perform the complex product of the transmitted digital quadrature baseband signal 601 and the orthogonalized nonlinear distortion compensation data 607 in the nonlinear distortion compensator 608, which is then distributed by the distributor 618. The error detection unit 629 calculates the difference between the digital quadrature baseband signal 625 obtained by quadrature detection in the quadrature detection unit 620 and the transmission digital quadrature baseband signal 601 delayed in the data delay unit 626, and the reference table update unit is obtained. 631
By updating the coefficient 632 of the address calculation unit based on the quadrature error signal 630, it becomes possible to configure a feedback loop without having a rewritable reference table, and a highly accurate non-linear circuit with a small circuit configuration. Distortion can be compensated.

(Embodiment 7) Hereinafter, a seventh embodiment of the present invention will be described with reference to the drawings. FIG. 7 is a block connection diagram of a transmission device according to the seventh embodiment of the present invention.

In FIG. 7, 701 is a transmission digital quadrature baseband signal, 702 is a changeover switch, and 70
3 is a tone signal generator, 704 is the generated tone signal,
Reference numeral 705 is a power calculation unit, 706 is an amplitude value calculated by the power calculation unit 705, 707 is a reference table for nonlinear distortion compensation, 708 is orthogonalized nonlinear distortion compensation data, 709 is a nonlinear distortion compensation unit, and 710 is a nonlinear distortion compensation. Quadrature baseband signal, 711 D / A converter, 712 analog quadrature baseband signal, 713 band-pass low-pass filter, 714 band-limited analog quadrature baseband signal, and 715 quadrature modulation , 716 is a modulation signal, 717 is a transmission system amplifier, 718 is an amplified transmission modulation signal, 719 is a changeover switch, 720 is an attenuator,
721 is an attenuated transmission modulation signal, 722 is a band-limiting filter for detecting third-order distortion, 723 is a third-order distortion component extracted by band-limiting, 724 is a power detection unit, 725 is a detected power value, 726 Is a data delay unit, 727 is a delayed amplitude value, 728 is a reference table update unit, and 729 is orthogonalized nonlinear distortion compensation data.

The operation of the transmitting apparatus configured as above will be described with reference to FIG.

First, the changeover switch 702 is changed over to the tone signal generator 703 side and the changeover switch 719 is changed over toward the attenuator 720 side to enter the training mode. The tone signal generator 703 generates the tone signal 704, and the power calculator 705 calculates the amplitude value 706 of the tone signal 704.

Next, the calculated tone signal amplitude value 70
Reference table 70 for nonlinear distortion compensation with 6 as an address
7, the non-linear distortion compensation data having the inverse characteristic of the non-linear distortion characteristic of the transmission system calculated in advance is obtained as the orthogonalized non-linear distortion compensation data 708. Non-linear distortion compensator 70
In step 9, the tone signal 704 and the orthogonalized nonlinear distortion compensation data 708 are subjected to a complex product, and the orthogonal distortion-compensated orthogonal baseband signal 710 is output. The D / A conversion unit 711 converts the nonlinear distortion-compensated quadrature baseband signal 710 into an analog signal, and the low-pass filter 713 performs band limitation to obtain an analog quadrature baseband signal 714.

Then, the quadrature modulator 715 performs quadrature modulation to form a modulation signal 716, which is then amplified by a transmission system amplifier 717 to a required level and output as a transmission modulation signal 718.
Transmit modulated signal 718 via changeover switch 719
Is attenuated by attenuator 720. The third-order distortion component 723 is extracted from the attenuated transmission modulation signal 721 by the third-order distortion detection band limiting filter 722, the power of the third-order distortion component is detected by the power detection unit 724, and the digital power detection value 725 is detected. To get

On the other hand, the data delay unit 726 delays the amplitude value 706 of the tone signal by the time constant of the feedback loop and outputs the delayed amplitude value 727. The reference table updating unit 728 delays the amplitude value 72 so that the detected power value 725 of the third-order distortion component becomes small.
The orthogonalized non-linear distortion compensation data 729 referred to by using 7 as an address is updated.

Finally, a lookup table 7 for nonlinear distortion compensation
When the update of 07 is completed, the changeover switch 702
To the transmission digital quadrature baseband signal 701 side and the changeover switch 719 to the output side to enter the data transmission mode.

As described above, according to the present embodiment, the changeover switch 702, the tone signal generator 703, the power calculator 70.
4, a non-linear distortion compensation reference table 707, a non-linear distortion compensation unit 709, a changeover switch 719, an attenuator 720,
Band-limiting filter 722 for detecting third-order distortion, power detection unit 724, data delay unit 726, reference table update unit 72
8 is provided, and after the changeover switches 702 and 719 are switched to the training mode, the reference value 707 for non-linear distortion compensation is referred to by the amplitude value 706 of the tone signal 704 generated by the tone signal generation unit 703.
Nonlinear distortion compensation data 70 orthogonalized to the tone signal 704
The complex product of 8 is performed by the non-linear distortion compensator 709, the transmission modulation signal 718 fed back by the changeover switch 719 is attenuated by the attenuator 720, and the band limiting filter 7
After extracting only the third-order distortion component at 22, the power detection unit 7
In order to reduce the power 725 of the third-order distortion component detected at 24, the reference table updating unit 728 causes the data delay unit 7
Orthogonalized non-linear distortion compensation data 729 referenced with the amplitude value 727 of the tone signal delayed by 26 as an address.
By updating, it becomes possible to configure the feedback loop with a simple system having no quadrature detection section, and it is possible to perform highly accurate nonlinear distortion compensation with a small-scale circuit configuration.

[0071]

As described above, according to the present invention, a power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal and a nonlinear distortion compensation prepared in advance using the calculated power value. A table reference unit that refers to a table, a nonlinear distortion compensation unit that performs nonlinear distortion compensation of an orthogonal baseband signal using the referenced nonlinear distortion compensation data, an orthogonal modulation unit that orthogonally modulates the orthogonal baseband signal, and a modulated signal , An amplifier for amplifying the modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detecting section for quadrature detecting the distributed modulated signal, and an A / D converting section for digitally converting the quadrature detected quadrature baseband signal. An error calculator that compares the baseband signal with the transmitted baseband signal to calculate the error, and a reference table based on the calculated error Comprising a table update unit to update the contents, the value of the nonlinear distortion compensation data in the lookup table using the feedback loop has a configuration to be updated.

With this configuration, an excellent transmission device capable of compensating the non-linear distortion generated in the amplifier of the transmission system with high accuracy by suppressing the influence of the distortion of the analog circuit with a small number of reference tables and a simple digital operation. Can be realized.

[Brief description of drawings]

FIG. 1 is a block connection diagram of a transmission device according to a first embodiment of the present invention.

FIG. 2 is a block connection diagram of a transmission device according to a second embodiment of the present invention.

FIG. 3 is a block connection diagram of a transmission device according to a third embodiment of the present invention.

FIG. 4 is a block connection diagram of a transmission device according to a fourth embodiment of the present invention.

FIG. 5 is a block connection diagram of a transmission device according to a fifth embodiment of the present invention.

FIG. 6 is a block connection diagram of a transmitter according to a sixth embodiment of the present invention.

FIG. 7 is a block connection diagram of a transmission device according to a seventh embodiment of the present invention.

FIG. 8 is a block connection diagram of a conventional transmitter.

[Explanation of symbols]

102, 202, 302, 402, 502, 602, 7
05 power calculator 104, 304, 506, 606, 707, 802 reference table 106, 306, 508, 608, 709 non-linear distortion compensator 108, 206, 308, 406, 510, 610, 7
11, 805 D / A converter 110, 208, 310, 320, 408, 420, 5
12, 522, 612, 622, 713, 807 Low-pass filter 112, 210, 312, 410, 514, 614, 7
15, 809 Quadrature modulator 114, 214, 314, 414, 516, 616, 7
17,816 Transmitter amplifier 204,404 Reference table 212,412,811 Gain control amplifier 316,416,518,618 Distributor 318,418,520,620 Quadrature detector 322,422,524,624 A / D conversion Section 324, 424, 526, 626, 726 data delay section 327, 427, 529, 629 error calculation section 329, 429, 531, 728 reference table update section 504 address reference section 604 address calculation section 631 coefficient update section 702, 719 switching Switch 703 Tone signal generator 720 Attenuator 722 Band-limiting filter for extracting third-order distortion 724 Power detector

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Koei Bisuzu, 4-3-1, Tsunashimahigashi, Kohoku-ku, Yokohama-shi, Kanagawa Matsushita Communication Industrial Co., Ltd.

Claims (7)

[Claims] 1. A power calculation unit for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and a power calculation unit prepared in advance using the calculated power value. A transmission apparatus comprising: a table reference section that refers to a nonlinear distortion compensation table; and a nonlinear distortion compensation section that performs nonlinear distortion compensation of an orthogonal baseband signal using the referenced nonlinear distortion compensation data. 2. A power calculation unit for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and a power calculation unit prepared in advance using the calculated power value. A table reference section for referring to the amplitude distortion compensation table,
A transmission apparatus comprising: a quadrature modulation unit that performs quadrature modulation of a quadrature baseband signal; and an amplitude distortion compensation unit that performs amplitude distortion compensation of a modulation signal using the amplitude distortion compensation data referred to by the table reference unit. 3. A power calculation unit for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and a power calculation unit prepared in advance using the calculated power value. A table reference unit that refers to a non-linear distortion compensation table, a non-linear distortion compensation unit that performs non-linear distortion compensation of a quadrature baseband signal using the referenced non-linear distortion compensation data, and a quadrature modulation that quadrature-modulates the quadrature baseband signal. Section, an amplifier for amplifying the modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detecting section for quadrature detecting the distributed modulated signal, and a digital conversion of the quadrature detected quadrature baseband signal. The A / D conversion section compares the A / D converted baseband signal with the transmitted baseband signal to obtain an error. And a table updating unit that updates the contents of the reference table based on the calculated error. 4. A power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and a power calculation unit prepared in advance using the calculated power value. A table reference unit that refers to a distortion compensation table, a quadrature modulation unit that performs quadrature modulation of the quadrature baseband signal, and an amplitude distortion that performs amplitude distortion compensation of a modulation signal using the amplitude distortion compensation data referenced by the table reference unit. A compensating section, an amplifier for amplifying the modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detecting section for quadrature detecting the distributed modulated signal, and a digital conversion of the quadrature detected quadrature baseband signal. A / D converter and its A / D
A transmission apparatus comprising: an error calculation unit that compares a converted baseband signal with a transmitted baseband signal to calculate an error; and a table updating unit that updates the contents of a reference table based on the calculated error. 5. A power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and an address is determined using the calculated power value. Address reference section, a table reference section that references a non-linear distortion compensation table prepared in advance, a non-linear distortion compensation section that performs non-linear distortion compensation of a quadrature baseband signal using the referenced non-linear distortion compensation data, and the quadrature A quadrature modulator for quadrature modulating a baseband signal, an amplifier for amplifying the modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detector for quadrature detecting the distributed modulated signal, and a quadrature detector for the quadrature detector. A / D converter that digitally converts the orthogonal baseband signal that has been converted, and the A / D converted baseband signal A transmission apparatus comprising: an error calculation unit that compares received baseband signals to calculate an error, and a table update unit that updates the contents of the address reference table based on the calculated error. 6. A power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal of a wireless communication system using a digital modulation method, and an address for calculating an address from the value of the calculated power. A calculation unit, a table reference unit that refers to a non-linear distortion compensation table prepared in advance, a non-linear distortion compensation unit that performs non-linear distortion compensation of a quadrature baseband signal using the referenced non-linear distortion compensation data, and the quadrature baseband A quadrature modulator for quadrature modulating a signal, an amplifier for amplifying the modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detector for quadrature detecting the distributed modulated signal, and a quadrature for quadrature detecting the quadrature. An A / D converter that converts the baseband signal into a digital signal, and the A / D converted baseband signal are transmitted. And a table updating unit that updates a coefficient value inside the address calculating unit based on the calculated error, and an error calculating unit that calculates an error by comparing the baseband signals. 7. A tone signal generation unit for generating a tone signal of a wireless communication system using a digital modulation method,
A power calculation unit that calculates the power of the input signal,
A table reference section that refers to a non-linear distortion compensation table prepared in advance using the calculated power value, and a non-linear distortion compensation section that performs non-linear distortion compensation of the orthogonal baseband signal using the referred non-linear distortion compensation data. A quadrature modulator for quadrature modulating the quadrature baseband signal, an amplifier for amplifying the modulated signal, an attenuator for attenuating the amplified modulated signal, and a third-order distortion component extracted from the attenuated modulated signal And the filter part of 3
A transmission device comprising: a power detection unit that detects the power of the next distortion component; and a table updating unit that updates the contents of the reference table so as to reduce the detected power of the third-order distortion component.