JP3198864B2 - Transmission device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmitter which is used in a communication device of a radio communication system using a digital modulation system and which compensates for nonlinear distortion generated in a transmission system amplifier with a simple operation and a small number of reference tables. Things.

[0002]

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

[0003] A conventional transmitting apparatus will be described below.
FIG. 8 shows a block configuration of a conventional transmitting apparatus. In FIG. 8, reference numeral 801 denotes a transmission digital orthogonal 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 denotes a D / A converter for converting digital data into an analog value, and 806 denotes a converted analog quadrature baseband signal. Reference numeral 807 denotes a low-pass filter for limiting the band of the transmission signal, and reference numeral 808 denotes a band-limited orthogonal baseband signal. 809 is a quadrature modulator, and 810 is a modulation signal. 811 is a gain control amplifier for compensating amplitude distortion, 812 is a modulation signal compensated for amplitude distortion, 813 is a phase shifter for compensating phase distortion, 814 is a modulation signal compensated for amplitude and phase shift distortion, and 816 is a transmission system. 817 is a transmission modulation signal.

[0004] The operation of the transmitting apparatus configured as described above will be described below. First, the transmission digital quadrature baseband signal 801 is converted by the D / A converter 805.
Is converted to an analog value, band-limited by a low-pass filter 807, and then quadrature-modulated by a quadrature modulator 809 to become a modulated signal 810. At the same time, the amplitude distortion compensation data 803 and the phase distortion compensation data 804 are obtained by referring to the reference table 802 using the value of the transmission digital orthogonal baseband signal 801 as an address.

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 is performed using the phase distortion compensation data 804 to obtain a modulated signal 814 with amplitude and phase distortion compensation.

[0006] Finally, the modulated signal 814 whose amplitude and phase distortion have been compensated is amplified by the amplifier 816 of the transmission system, and the transmitted modulated signal 817 is output.

[0007]

However, in the above-mentioned conventional configuration, an address having twice the number of bits of the data of the digital orthogonal 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 themselves need to be distortion-free.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems and compensates for non-linear distortion generated in a transmission system amplifier by a simple operation and a small number of lookup tables in a communication device of a radio communication system using a digital modulation system. It is an object of the present invention to provide a transmitting device that performs the following.

[0009]

In order to achieve this object, a transmitting apparatus of the present invention comprises a digitally modulated transmission quadrature frame.
From the baseband signal to calculate the power of the transmitted signal.
Input the power calculation unit and the calculated power value.
To determine the address by referring to the address reference table
Address reference unit, and the address
A data reference table for nonlinear distortion compensation prepared in advance
The table reference section to be referenced and the referenced nonlinear distortion compensation
Orthogonal base using data from data reference table for compensation
A non-linear distortion compensator for performing non-linear distortion compensation of the band signal;
The quadrature modulation is performed on the quadrature baseband signal with the linear distortion compensated.
Quadrature modulator and amplifier for amplifying the output of quadrature modulator
A quadrature detector for quadrature detecting the output of the amplifier;
The cross-detected baseband signal and the transmission quadrature baseband
An error calculation unit that calculates an error by comparing the
Based on the calculated error,
It has a table updating unit for updating the contents.

[0010]

With this configuration, the size of the lookup table can be significantly reduced. Also, since nonlinear distortion compensation is performed by digital complex operation without using the gain control amplifier and phase shifter, which are analog circuits, there is no need to consider the distortion of the gain control amplifier and phase shifter. Thus, nonlinear 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 diagram of a transmitting apparatus according to a first embodiment of the present invention.

In FIG. 1, reference numeral 101 denotes a transmission digital orthogonal baseband signal; 102, a power calculation unit; 103, an amplitude value calculated by the power calculation unit 102; 104, a lookup table for nonlinear distortion compensation; Distortion compensation data, 106 is a nonlinear distortion compensator, 107 is a quadrature baseband signal with nonlinear distortion compensated, 108 is a D / A converter, 109 is an analog quadrature baseband signal, 110
Is a low-pass filter for band limitation, 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 denotes an amplified transmission modulation signal.

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

First, a power calculator 102 calculates an amplitude value 103 of a transmission signal from a transmission digital orthogonal baseband signal 101. Next, the nonlinear distortion compensation data obtained by orthogonalizing the nonlinear distortion compensation data having the inverse characteristic of the nonlinear distortion characteristic of the transmission system calculated in advance by referring to the lookup table 104 for nonlinear distortion compensation using the calculated transmission signal amplitude value 103 as an address is referred to. Obtained as compensation data 105.

The nonlinear distortion compensating section 106 performs a complex product of the transmission digital orthogonal 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 converter 108, band-limited by the low-pass filter 110, and the analog quadrature baseband signal 111
Get.

Then, after performing quadrature modulation by a quadrature modulator 112 to produce a modulated signal 113, the signal is amplified to a required size by a transmission system amplifier 114 and a transmission modulated signal 115 is output.

As described above, according to the present embodiment, the power calculator 10
2. A reference table 104 for nonlinear distortion compensation and a nonlinear distortion compensator 106 are provided, and the reference table 104 for nonlinear distortion compensation is referred to based on the amplitude value 103 of the transmission digital orthogonal baseband signal 101, and the transmission digital orthogonal baseband signal 101 And nonlinear distortion compensation data 105 orthogonalized to
Is performed by the nonlinear distortion compensating unit 106,
It is possible to compensate for non-linear distortion generated in a transmission system amplifier with a simple operation and a small number of reference tables.

(Embodiment 2) Hereinafter, a second embodiment of the present invention will be described with reference to the drawings. FIG. 2 is a block diagram of a transmitting apparatus according to a second embodiment of the present invention.

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

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

First, an amplitude value 203 of a transmission signal is calculated from a transmission digital orthogonal baseband signal 201 by a power calculation unit 202. Next, using the calculated transmission signal amplitude value 203 as an address, a reference table 2 for amplitude distortion compensation is used.
With reference to FIG. 04, 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 digital orthogonal baseband signal 201 is converted into an analog signal by the D / A converter 206 and band-limited by the low-pass filter 208 to obtain an analog orthogonal baseband signal 209.

Then, after performing quadrature modulation by the quadrature modulator 210 to produce 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 performs amplitude distortion compensated modulation. A signal 213 is obtained. Finally, the signal is amplified to a required size by the amplifier 214 and the transmission modulation signal 215 is output.

According to the present embodiment, the power calculator 20
2. A reference table 204 for amplitude distortion compensation and a gain control amplifier 212 for amplitude distortion compensation are provided, and the amplitude signal 203 of the transmission digital orthogonal baseband signal 201 is referred to the reference table 204 for amplitude distortion compensation, and the modulated signal 211 Is performed by the gain control amplifier 212 for amplitude distortion compensation based on the amplitude distortion compensation data 205, so that the amplitude generated in the amplifier of the transmission system can be compensated by a simple operation and a small number of reference tables. .

Embodiment 3 Hereinafter, a third embodiment of the present invention will be described with reference to the drawings. FIG. 3 is a block diagram of a transmitting apparatus according to a third embodiment of the present invention.

In FIG. 3, reference numeral 301 denotes a transmission digital orthogonal baseband signal; 302, a power calculation unit; 303, an amplitude value calculated by the power calculation unit 302; 304, a lookup table for nonlinear distortion compensation; Distortion compensation data, 306 is a nonlinear distortion compensator, 307 is a quadrature baseband signal with nonlinear distortion compensated, 308 is a D / A converter, 309 is an analog quadrature 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 modulated signal, 316 is a distributor, 317 is a distributed transmission modulated signal, 318 is a quadrature detector, 319
Is a quadrature-detected quadrature baseband signal, 320 is a low-pass filter for band limitation, 321 is a band-limited quadrature baseband signal, 322 is an A / D converter, 323 is a digital quadrature baseband signal, 324 is data A delay unit 325 is a delayed transmission digital orthogonal 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 denotes orthogonalized nonlinear 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 an amplitude value 303 of a transmission signal from the transmission digital orthogonal baseband signal 301. Next, the nonlinear distortion compensation data obtained by orthogonalizing the nonlinear distortion compensation data having the inverse characteristic of the nonlinear distortion characteristic of the transmission system calculated in advance by referring to the lookup table 304 for nonlinear distortion compensation using the calculated transmission signal amplitude value 303 as an address is referred to. Obtained as compensation data 305.

The nonlinear distortion compensating unit 306 performs a complex product of the transmission digital orthogonal baseband signal 301 and the orthogonalized nonlinear distortion compensation data 305, and outputs a nonlinear distortion compensated orthogonal baseband signal 307. The D / A converter 308 converts the orthogonal baseband signal 307, for which the nonlinear distortion has been compensated, into an analog signal, performs band limiting by the low-pass filter 310, and performs analog quadrature baseband signal 311.
Get.

Then, after performing quadrature modulation by a quadrature modulator 312 to generate a modulated signal 313, the signal is amplified to a required size by a transmission amplifier 314 and a transmission modulated signal 315 is output.
At this time, the transmission modulation signal 315 is distributed by the distributor 316. The distributed transmission modulation signal 317 is subjected to quadrature detection by a quadrature detection unit 318, passed through a low-pass filter 320 for band limitation, converted to a digital signal by an A / D conversion unit 322, and converted to a digital quadrature baseband signal 323. obtain.

On the other hand, the data delay section 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.
25 and the delayed amplitude value 326 is output. The error calculator 327 calculates the difference between the digital orthogonal baseband signal 323 and the delayed transmission digital orthogonal baseband signal 325, and outputs the result as an orthogonal error signal 328.

The lookup table updating section 329, based on the orthogonal error signal 328, uses the delayed amplitude value 326 as an address to refer to the orthogonalized nonlinear distortion compensation data 33.
Update 0.

According to the present embodiment, the power calculator 30
2, a reference table 304 for nonlinear distortion compensation, a nonlinear distortion compensator 306, a distributor 316, a quadrature detector 318, a data delayer 324, an error calculator 327, and a reference table updater 329 are provided. 3
With reference to the nonlinear distortion compensation reference table 304 based on the amplitude value 303 of 01, the nonlinear distortion compensator 306 performs a complex product of the transmission digital orthogonal baseband signal 301 and the orthogonalized nonlinear distortion compensation data 305, and the distributor 316. A digital quadrature baseband signal 323 obtained by distribution and quadrature detection by a quadrature detector 318;
The transmitted digital quadrature baseband signal 3 delayed by 4
01 is obtained by the error detection unit 327, and the reference table updating unit 329 updates the content of the reference table 304 for nonlinear distortion compensation based on the orthogonal error signal 328. Data errors can be reduced using a feedback loop, and highly accurate nonlinear distortion compensation can be performed.

(Embodiment 4) Hereinafter, a fourth embodiment of the present invention will be described with reference to the drawings. FIG. 4 is a block diagram of a transmitting apparatus according to a fourth embodiment of the present invention.

In FIG. 4, reference numeral 401 denotes a transmission digital quadrature baseband signal; 402, a power calculation unit; 403, an amplitude value calculated by the power calculation unit 402; 404, a lookup table for amplitude distortion compensation; , 4
06 is a D / A converter, 407 is an analog quadrature baseband signal, 408 is a low-pass filter for band limitation, 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 a modulation signal with amplitude distortion compensation, 414 is a transmission system amplifier, 415 is an amplified transmission modulation signal, and 416 is a distribution signal. , 417 is a distributed transmission modulation signal, 418 is a quadrature detector, 419 is a quadrature detected quadrature baseband signal, 420 is a low-pass filter for band limitation, 421 is a band-limited quadrature baseband signal, 422 Is an A / D converter, 423 is a digital orthogonal baseband signal, 424 is a data delay unit, 425 is a delayed transmission digital orthogonal baseband signal, 426 is a delayed amplitude value, 427 is an error calculator, and 428 is an error. The orthogonal error signal 429 calculated by the calculating unit 427 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 orthogonal baseband signal 401. Next, using the calculated transmission signal amplitude value 403 as an address, a reference table 4 for amplitude distortion compensation is used.
With reference to FIG. 04, 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 band-limited by the low-pass filter 408 to obtain an analog quadrature baseband signal 409.

Then, after performing quadrature modulation by the quadrature modulator 410 to obtain a modulation 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 subjected to quadrature detection by a quadrature detection unit 418, passed through a low-pass filter 420 for band limitation, converted into a digital signal by an A / D conversion unit 422, and converted into a digital quadrature baseband signal 423. obtain.

On the other hand, the data delay section 424 delays the transmission digital quadrature baseband signal 401 and the amplitude value 403 of the transmission signal by the time constant of the feedback loop, and delays the transmission digital quadrature baseband signal 4.
25 and the delayed amplitude value 426 is output. An error calculator 427 calculates the difference between the digital orthogonal baseband signal 423 and the delayed transmission digital orthogonal baseband signal 425, and outputs the result as an orthogonal error signal 428.

The reference table updating unit 429 updates the amplitude distortion compensation data 430 referred to by using the delayed amplitude value 426 as an address based on the orthogonal error signal 428.

As described above, according to the present embodiment, the power calculator 40
2. Reference table 404 for amplitude distortion compensation, gain control amplifier 412 for amplitude distortion compensation, distributor 416, quadrature detector 4
18, a data delay unit 424, an error calculation unit 427, and a reference table updating unit 429. The amplitude signal 403 of the transmission digital quadrature baseband signal 401 refers to a reference table 404 for amplitude distortion compensation, and modulates the modulation signal 411 by amplitude distortion. Compensation gain control amplifier 412 uses amplitude distortion compensation data 4
05, a digital quadrature baseband signal 423 obtained by distribution by a distributor 416 and quadrature detection by a quadrature detector 418, and a data delay unit 424.
Digital quadrature baseband signal 40 delayed by
The difference of 1 is obtained by the error detection unit 427, and the reference table updating unit 429 updates the content of the reference table 404 for amplitude distortion compensation based on the quadrature error signal 428. Data errors can be reduced 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 diagram of a transmitting apparatus according to a fifth embodiment of the present invention.

In FIG. 5, reference numeral 501 denotes a transmission digital orthogonal baseband signal; 502, a power calculator; 503, an amplitude value calculated by the power calculator 502; 504, an address reference unit for determining an address using the amplitude value 503; 5
05 is a referenced address, 506 is a lookup table for nonlinear distortion compensation, 507 is orthogonalized nonlinear distortion compensation data, 508 is a nonlinear distortion compensator, 509 is a nonlinear baseband signal with nonlinear distortion compensated, 510 is D / D A conversion unit, 5
11 is an analog quadrature baseband signal, 512 is a low-pass filter for band limitation, 513 is an analog quadrature baseband signal with band limitation, 514 is a quadrature modulator, 51
5 is a modulation signal, 516 is a transmission amplifier, 517 is an amplified transmission modulation signal, 518 is a distributor, 519 is a distributed transmission modulation signal, 520 is a quadrature detector, 521 is a quadrature detected quadrature baseband signal, 522, a band-pass low-pass filter; 523, a band-limited quadrature baseband signal; 524, an A / D converter; 525, a digital quadrature baseband signal; 526, a data delay unit;
Are the delayed transmitted digital quadrature baseband signals, 5
28 is a delayed amplitude value, 529 is an error calculator, 530
Are the quadrature error signals 531 calculated by the error calculator 529
Denotes a reference table update unit, 532 denotes data of an address reference unit, and 533 denotes orthogonalized nonlinear distortion compensation data.

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

First, an amplitude value 503 of a transmission signal is calculated from a transmission digital orthogonal baseband signal 501 by a power calculation section 502. Next, address conversion is performed with reference to the address reference unit 504 using the calculated transmission signal amplitude value 503 as an address. The non-linear distortion compensation data having the inverse characteristic of the non-linear distortion characteristic of the transmission system calculated in advance is referred to the non-linear distortion compensation data 5 which is orthogonalized by referring to the reference table 506 for non-linear distortion compensation using the referred address 505.
07.

The nonlinear distortion compensator 508 performs a complex product of the transmission digital orthogonal baseband signal 501 and the orthogonalized nonlinear distortion compensation data 507, and outputs a nonlinear distortion compensated orthogonal baseband signal 509. The D / A converter 510 converts the orthogonal distortion-compensated quadrature baseband signal 509 into an analog signal, performs band limiting by a low-pass filter 512, and converts the analog quadrature baseband signal 513.
Get.

Then, after performing quadrature modulation by a quadrature modulator 514 to generate a modulated signal 515, the signal is amplified to a required size by a transmission amplifier 516 and a transmission modulated signal 517 is output.

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

On the other hand, data delay section 526 delays transmission digital quadrature baseband signal 501 and transmission signal amplitude value 503 by the time constant of the feedback loop, and delays transmission digital quadrature baseband signal 5.
27 and the delayed amplitude value 528 is output. The error calculator 529 calculates the difference between the digital orthogonal baseband signal 525 and the delayed transmission digital orthogonal baseband signal 527, and outputs the result as an orthogonal error signal 530.

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

As described above, according to the present embodiment, the power calculator 50
2. Address reference section 504, lookup table 506 for nonlinear distortion compensation, nonlinear distortion compensation section 508, distributor 518, quadrature detection section 520, data delay section 526, error calculation section 52
9. A reference table updating unit 531 is provided, the address value of the amplitude value 503 of the transmission digital orthogonal baseband signal 501 is converted by the address reference unit 504, and the referenced address 50 is converted.
5, a nonlinear distortion compensation unit 508 performs a complex product of the transmission digital orthogonal baseband signal 501 and the orthogonalized nonlinear distortion compensation data 507 with reference to the lookup table 506 for nonlinear distortion compensation, and distributes the complex product by the distributor 518. 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 is obtained by the error detection unit 529, and the reference table updating unit At 531, the nonlinear distortion compensation data 53 orthogonalized to the orthogonal error signal 530
3 to update the data 532 of the address reference unit referred to as the address using the delayed amplitude value 528, thereby making it possible to form a feedback loop with a small number of rewritable lookup tables. With a simple circuit configuration, highly accurate nonlinear distortion compensation can be performed.

(Embodiment 6) Hereinafter, a sixth embodiment of the present invention will be described with reference to the drawings. FIG. 6 is a block diagram of a transmitting apparatus according to a sixth embodiment of the present invention.

In FIG. 6, 601 is a transmission digital orthogonal baseband signal, 602 is a power calculator, 603 is an amplitude value calculated by the power calculator 602, 604 is an address calculator that calculates an address using the amplitude value 603, 6
05 is a calculated address, 606 is a lookup table for nonlinear distortion compensation, 607 is orthogonalized nonlinear distortion compensation data, 608 is a nonlinear distortion compensator, 609 is an orthogonal baseband signal with nonlinear distortion compensated, and 610 is D / D A conversion unit, 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 detector, 621 is a quadrature detected quadrature baseband signal, 622 is a low-pass filter for band limitation, 623 is a band-limited orthogonal baseband signal, 624 is an A / D converter, 625 is a digital orthogonal baseband signal, 626 is a data delay unit, and 627.
Is the delayed transmitted digital quadrature baseband signal, 6
28 is a delayed amplitude value, 629 is an error calculator, 630
Is the orthogonal error signal calculated by the error calculator 629, 631
Is a coefficient update unit, and 632 is a coefficient of the address calculation 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 orthogonal baseband signal 601. Next, address conversion is performed by the address calculation unit 604 using the calculated amplitude value 603 of the transmission signal. By using the calculated address 605 and referring to the lookup table 606 for nonlinear distortion compensation, nonlinear distortion compensation data having the inverse characteristic of the nonlinear distortion characteristic of the transmission system calculated in advance is obtained as orthogonalized nonlinear distortion compensation data 607. .

The nonlinear distortion compensator 608 performs a complex product of the transmission digital orthogonal baseband signal 601 and the orthogonalized nonlinear distortion compensation data 607, and outputs a nonlinear distortion compensated orthogonal baseband signal 609. The D / A converter 610 converts the orthogonal baseband signal 609, for which the nonlinear distortion has been compensated, into an analog signal, and performs band limitation by a low-pass filter 612.
Get.

Then, after performing quadrature modulation by a quadrature modulator 614 to generate a modulated signal 615, the signal is amplified by a transmission system amplifier 616 to a required size and a transmission modulated signal 617 is output.

At this time, the transmission modulated signal 5
Distribute 17. The distributed transmission modulation signal 619 is subjected to quadrature detection by a quadrature detection section 620, passed through a low-pass filter 622 for band limitation, converted to a digital signal by an A / D conversion section 624, and converted to a digital quadrature baseband signal 625.
Get.

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

As described above, according to the present 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. A coefficient updating unit 631 is provided, and the address calculation unit 604 performs address calculation using the amplitude value 603 of the transmission digital orthogonal baseband signal 601 to obtain the calculated address 6.
05, the nonlinear distortion compensating unit 608 performs a complex product of the transmission digital orthogonal baseband signal 601 and the orthogonalized nonlinear distortion compensation data 607, and distributes the result by the distributor 618. The difference between the digital quadrature baseband signal 625 obtained by quadrature detection by the quadrature detection unit 620 and the transmission digital quadrature baseband signal 601 delayed by the data delay unit 626 is obtained by the error detection unit 629, and the reference table updating unit 631,
By updating the coefficient 632 of the address calculation unit based on the orthogonal error signal 630, it is possible to form a feedback loop without having a rewritable lookup table. Distortion compensation can be performed.

Embodiment 7 Hereinafter, a seventh embodiment of the present invention will be described with reference to the drawings. FIG. 7 is a block diagram of a transmitting apparatus according to a seventh embodiment of the present invention.

In FIG. 7, reference numeral 701 denotes a transmission digital orthogonal baseband signal; 702, a changeover switch;
3 is a tone signal generator, 704 is the generated tone signal,
705 is a power calculator, 706 is an amplitude value calculated by the power calculator 705, 707 is a lookup table for nonlinear distortion compensation, 708 is orthogonalized nonlinear distortion compensation data, 709 is a nonlinear distortion compensation unit, and 710 is nonlinear distortion compensation. Orthogonal baseband signal, 711 is a D / A converter, 712 is an analog orthogonal baseband signal, 713 is a low-pass filter for band limitation, 714 is an analog orthogonal baseband signal with band limitation, 715 is orthogonal modulation. 716, a modulation signal, 717, a transmission system amplifier, 718, an amplified transmission modulation signal, 719, a changeover switch, 720, 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 detector, 725 is a value of detected power, and 726. Is a data delay unit, 727 is a delayed amplitude value, 728 is a lookup table updating unit, and 729 is orthogonalized nonlinear distortion compensation data.

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

First, the changeover switch 702 is switched to the tone signal generator 703 side and the changeover switch 719 is switched to the attenuator 720 side to enter the training mode. A tone signal generator 703 generates a tone signal 704, and a power calculator 705 calculates an amplitude value 706 of the tone signal 704.

Next, the calculated tone signal amplitude value 70
Reference table 70 for nonlinear distortion compensation using address 6 as an address
7, nonlinear distortion compensation data having an inverse characteristic of the nonlinear distortion characteristic of the transmission system calculated in advance is obtained as orthogonalized nonlinear distortion compensation data 708. Nonlinear distortion compensator 70
In 9, the complex product of the tone signal 704 and the orthogonalized nonlinear distortion compensation data 708 is performed, and the nonlinear baseband signal 710 with the nonlinear distortion compensated is output. The D / A converter 711 converts the non-linear 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, after performing quadrature modulation by a quadrature modulator 715 to generate a modulated signal 716, the signal is amplified to a required size by a transmission amplifier 717 and a transmission modulated signal 718 is output.
Modulated transmission signal 718 via switch 719
Is attenuated by the attenuator 720. The third-order distortion component 723 is extracted from the attenuated transmission modulation signal 721 by the band-limiting filter 722 for detecting the third-order distortion, and 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. Get.

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

Finally, the lookup table 7 for nonlinear distortion compensation
07 when the update of 07 has been completed
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. Reference table 707 for nonlinear distortion compensation, nonlinear distortion compensator 709, changeover switch 719, attenuator 720,
Third-order distortion detection band limiting filter 722, power detection unit 724, data delay unit 726, reference table update unit 72
8 and switches the switches 702 and 719 to set the training mode, and then refers to the lookup table 707 for nonlinear distortion compensation by the amplitude value 706 of the tone signal 704 generated by the tone signal generator 703,
Nonlinear distortion compensation data 70 orthogonalized to tone signal 704
8 is performed by the nonlinear distortion compensator 709, the transmission modulation signal 718 fed back by the changeover switch 719 is attenuated by the attenuator 720,
After extracting only the third-order distortion component at 22, the power detection unit 7
The reference table updating unit 728 causes the data delay unit 7 to reduce the power 725 of the third-order distortion component detected at 24.
The orthogonalized nonlinear distortion compensation data 729 referred to as an address using the amplitude value 727 of the tone signal delayed at 26
Is updated, it is possible to configure a feedback loop with a simple system having no quadrature detection unit, and highly accurate nonlinear distortion compensation can be performed with a small-scale circuit configuration.

[0071]

As described above, the present invention provides 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 compensator that performs nonlinear distortion compensation of the orthogonal baseband signal using the referenced nonlinear distortion compensation data, an orthogonal modulator that orthogonally modulates the orthogonal baseband signal, and a modulation signal An amplifier for amplifying the amplified modulated signal, a distributor for distributing the amplified modulated signal, a quadrature detector for orthogonally detecting the distributed modulated signal, and an A / D converter for digitally converting the orthogonally detected orthogonal baseband signal. An error calculation unit for calculating an error by comparing the transmitted baseband signal with the baseband signal, 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 transmitting apparatus capable of highly accurately compensating for non-linear distortion generated in an amplifier in a transmission system with a small number of reference tables and simple digital operation while suppressing the influence of analog circuit distortion. Can be realized.

[Brief description of the drawings]

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

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

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

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

FIG. 5 is a block diagram of a transmitting apparatus according to a fifth embodiment of the present invention.

FIG. 6 is a block diagram of a transmission device 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 diagram of a conventional transmission device.

[Explanation of symbols]

102, 202, 302, 402, 502, 602, 7
05 Power calculation units 104, 304, 506, 606, 707, 802 Lookup tables 106, 306, 508, 608, 709 Nonlinear distortion compensation units 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 Transmission system amplifiers 204, 404 Lookup tables 212, 412, 811 Gain control amplifiers 316, 416, 518, 618 Dividers 318, 418, 520, 620 Quadrature detectors 322, 422, 524, 624 A / D conversion Units 324, 424, 526, 626, 726 Data delay units 327, 427, 529, 629 Error calculation units 329, 429, 531, 728 Reference table update unit 504 Address reference unit 604 Address calculation unit 631 Coefficient update unit 702, 719 Switching Switch 703 Tone signal generator 720 Attenuator 722 Band limit filter for extracting third-order distortion 724 Power detector

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor, Kimihide Mihozu 4-3-1 Tsunashimahigashi, Kohoku-ku, Yokohama-shi, Kanagawa Prefecture Matsushita Communication Industrial Co., Ltd. (56) References JP-A-63-131326 (JP, A (58) Fields surveyed (Int. Cl. ⁷ , DB name) H04L 27/00-27/38

Claims (5)

(57) [Claims] 1. A power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal, and an adder that receives the calculated power value as an input.
An address reference unit for determining an address by referring to the address reference table; a table reference unit that receives the address as an input and refers to a data reference table for nonlinear distortion compensation prepared in advance ; De
A nonlinear distortion compensator that performs nonlinear distortion compensation of the orthogonal baseband signal using data of the data reference table, an orthogonal modulator that orthogonally modulates the orthogonal baseband signal with the nonlinear distortion compensated, and amplifies an output of the orthogonal modulator. Amplifier, a quadrature detection unit for quadrature detection of the output of the amplifier, an error calculation unit for calculating an error by comparing the quadrature detected baseband signal and the transmission quadrature baseband signal, based on the calculated error transmitting device having a table update unit to update the contents of the address lookup table Te. 2. A power calculator for calculating the power of a transmission signal from a digitally modulated transmission quadrature baseband signal by calculation, an address calculator for calculating an address from the calculated power value, and A table reference unit that refers to a nonlinear distortion compensation table prepared in advance, a nonlinear distortion compensation unit that performs nonlinear distortion compensation of an orthogonal baseband signal using the referenced nonlinear distortion compensation data, and the orthogonal baseband with nonlinear distortion compensation A quadrature modulator for quadrature modulating a signal, an amplifier for amplifying the output of the quadrature modulator, a quadrature detector for quadrature detecting the output of the amplifier, and comparing the quadrature detected baseband signal and the transmission quadrature baseband signal Error calculation unit that calculates the error, and updates the coefficient value inside the address calculation unit based on the calculated error A transmission device comprising a table updating unit for performing the following. 3. A tone signal generator for generating a tone signal, a power calculator for calculating the power of an input signal by calculation, and a table referencing a non-linear distortion compensation table prepared in advance using the calculated power value. A nonlinear distortion compensator that performs nonlinear distortion compensation on an orthogonal baseband signal using the referenced nonlinear distortion compensation data; an orthogonal modulator that orthogonally modulates the nonlinear baseband signal with the nonlinear distortion compensated; An amplifier for amplifying the output of the modulator, an attenuator for attenuating the output of the amplifier, a filter for extracting a third-order distortion component from the attenuated modulation signal, and a power of the extracted third-order distortion component And a table updating unit for updating the contents of the reference table so as to reduce the power of the detected third-order distortion component. Transmitting device. 4. A transmission signal power is calculated from a digitally modulated transmission quadrature baseband signal by calculation, and the calculated power value is input to an address reference table.
To determine the address, and enter the address as an input.
Te, with reference to the data reference te <br/> Buru for nonlinear distortion compensation previously prepared, data for non-linear distortion compensation is the reference
Non-linear distortion compensation of the orthogonal baseband signal is performed using the data of the data reference table, and after orthogonally modulating the orthogonal distortion-compensated orthogonal baseband signal, amplifying and orthogonally detecting the amplified orthogonal baseband signal, orthogonal transmission method by comparing detected baseband signal and the transmission quadrature baseband signal to calculate an error, and updates the contents of the a <br/> address reference table based on the calculated error. 5. A power of a transmission signal is calculated from a digitally modulated transmission quadrature baseband signal by calculation, an address is calculated from the calculated power value, and a nonlinear distortion compensation table prepared in advance is prepared using the address. Refer to, perform nonlinear distortion compensation of the orthogonal baseband signal using the referenced nonlinear distortion compensation data, and after orthogonally modulating the orthogonal baseband signal subjected to nonlinear distortion compensation,
Amplify, perform quadrature detection on the amplified quadrature baseband signal, compare the quadrature detected baseband signal with the transmission quadrature baseband signal, calculate an error, and calculate a coefficient inside the address calculation unit based on the calculated error. Submission method that updates the value of.