JP2004112834A - Transmitting device and radio communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To maintain the provision on leakage electric power of the adjacent channel with a more sufficient precision by suppressing the intensity of a transmitting signal within a specified value. <P>SOLUTION: This transmitting device comprises a modulation signal generation section 202 constituted so that the signal point amplitude of a symbol for demodulation just before a lamp symbol becomes smaller than the signal point amplitude of a symbol for demodulation except the symbol for demodulation just before the lamp symbol on the I-Q plane, and which outputs the modulating signal of the symbol for demodulation ahead just before the lamp symbol. This allows the intensity of the transmitting signal to be suppressed within the specified value, and the provision of leakage electric power of the adjacent channel to be maintained at a more sufficient precision. <P>COPYRIGHT: (C)2004,JPO

Description

The present invention relates to lamp control in a wireless communication system.

と し て As an example of a configuration of a conventional lamp control device, for example, one described in Non-Patent Document 1 is known.

FIG. 27 shows the configuration of the lamp control device. Modulation signal generating section 2702 receives transmission digital signal 2701 and frame timing signal 2718 as inputs, and outputs in-phase component 2703 and quadrature component 2704 of the transmission quadrature baseband signal.

The transmission filter 2705 receives the in-phase component 2703 of the transmission quadrature baseband signal as input, performs band limitation, and outputs a band-limited transmission quadrature baseband signal in-phase component 2707.

The transmission filter 2706 receives the orthogonal component 2704 of the transmission orthogonal baseband signal as input, performs band limitation, and outputs the orthogonal component 2708 of the band-limited transmission orthogonal baseband signal.

The Hanning window signal processing unit 2709 receives the in-phase component 2707 of the band-limited transmission quadrature baseband signal and the frame timing signal 2718, detects a lamp symbol in the frame from the frame timing signal 2718, The in-phase component 2703 of the restricted transmission quadrature baseband signal is subjected to Hanning window signal processing, and the signal-processed transmission quadrature baseband signal in-phase component 2711 is output.

The Hanning window signal processing unit 2710 receives the orthogonal component 2708 of the band-limited transmission orthogonal baseband signal and the frame timing signal 2718, detects a lamp symbol in the frame from the frame timing signal 2718, A Hanning window signal process is performed on the restricted orthogonal component 2708 of the transmission orthogonal baseband signal, and an orthogonal component 2712 of the signal-processed transmission orthogonal baseband signal is output.

The radio section 2713 receives the in-phase component 27211 and the quadrature component 2712 of the signal-processed transmission quadrature baseband signal, and outputs the transmission signal 2714.

The power amplifier 2715 receives the transmission signal 2714 as input, amplifies the transmission signal 2714, outputs an amplified transmission signal 2716, and the amplified transmission signal is output as a radio wave from the antenna 17.
(Transient response of TDMA burst signal and adjacent slot interference protection time) Ikura, IEICE Autumn National Convention B-291 1990

However, in the conventional example, when it is desired to accurately attenuate the guard time and to regulate the adjacent channel leakage power or reduce the number of lamp symbols, it may be better to perform further control.

In order to solve this problem, the present invention arranges an attenuation control symbol for controlling attenuation before a symbol for demodulation, and sets an attenuation control symbol on the IQ plane from a signal point amplitude of the symbol for demodulation. A signal for signal demodulation before the attenuation control symbol and a signal point arrangement unit for outputting signal point information of the attenuation control symbol so as to reduce the signal point amplitude of the transmission device, thereby, The effect is obtained that the strength of the transmission signal is suppressed to the specified value, and the specification of the adjacent channel leakage power can be more accurately maintained.

As described above, according to the present invention, on the IQ plane, the signal point amplitude of the symbol for demodulation immediately before the ramp symbol is changed to the signal point of the symbol for demodulation excluding the symbol for demodulation immediately before the ramp symbol. This is a transmission device including a modulation signal generation unit that outputs a modulation signal having a smaller amplitude than the amplitude of the modulation signal, whereby the strength of the transmission signal can be suppressed to a specified value, and the specification of adjacent channel leakage power can be more accurately maintained. Effects can be obtained.

The transmitting apparatus according to the present invention is configured such that, on the IQ plane, the signal point amplitude of the symbol for demodulation immediately before the ramp symbol is smaller than the signal point amplitude of the symbol for demodulation except for the symbol for demodulation immediately before the ramp symbol. A transmission device including a modulation signal generation unit that outputs a modulated signal obtained by the above-described method. With these configurations, the intensity of the transmission signal can be suppressed to a specified value, and the specification of adjacent channel leakage power can be more accurately maintained.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 26.

(Embodiment 1)
In Embodiment 1 of the present invention, the signal point amplitude of the symbol for demodulation immediately before the ramp symbol on the IQ plane is smaller than the signal point amplitude of the symbol for demodulation except for the symbol for demodulation immediately before the ramp symbol. Will be described.

FIG. 1 shows an example of a frame configuration on the time axis according to the present embodiment, where 101, 102, 103, 105, 106, and 107 indicate data symbols, for example, symbols modulated by 16QAM. . 104 and 108 are pilot symbols, 109, 110, 111 and 112 are ramp symbols, and 113 and 114 are guard symbols. At this time, if a specified value of the strength of the transmission signal is defined for the guard symbols 113 and 114, it is necessary to keep the strength within the specified value. The lamp symbols 109, 110, 111, and 112 are symbols necessary to suppress the strength of the transmission signals of the guard symbols 113 and 114 to a specified value.

FIG. 2 shows an example of the configuration of the transmitting apparatus according to the present embodiment. Modulated signal generating section 202 receives transmission digital signal and frame configuration signal 218 as inputs, and transmits, for example, according to the frame configuration shown in FIG. An in-phase component 203 and a quadrature component 204 of the quadrature baseband signal are output.

(4) The transmission filter 205 receives the in-phase component 203 of the transmission quadrature baseband signal as an input, limits the band, and outputs the in-phase component 207 of the transmission quadrature baseband signal whose band is limited.

The transmission filter 206 receives the orthogonal component 204 of the transmission orthogonal baseband signal as an input, limits the band, and outputs the orthogonal component 208 of the band-limited transmission orthogonal baseband signal.

The signal processing unit 209 receives as input the in-phase component 207 of the band-limited transmission orthogonal baseband signal and the frame configuration signal 218, for example, applies a window to a lamp symbol and a guard symbol, and performs signal processing on the transmission orthogonal baseband signal. An in-phase component 211 of the signal is output.

The signal processing unit 210 receives as input the orthogonal component 208 of the band-limited transmission orthogonal baseband signal and the frame configuration signal 218, for example, applies a window to a lamp symbol and a guard symbol, and performs signal processing on the transmission orthogonal baseband. The orthogonal component 212 of the signal is output.

The radio section 213 receives the in-phase component 211 and the quadrature component 212 of the signal-transmitted transmission quadrature baseband signal as inputs and outputs a transmission signal 214.

(4) The power amplification unit 215 receives the transmission signal 214 as input, amplifies the transmission signal 214, outputs an amplified transmission signal 216, and outputs the amplified transmission signal 216 from the antenna 217 as radio waves.

FIG. 3 shows an example of the detailed configuration of the modulation signal generation section 202 of FIG. 2. The data symbol modulation signal generation section 302 receives the transmission digital signal 301 and the frame configuration signal 321 as inputs, and the frame configuration signal 321 If it indicates a data symbol, 16QAM modulation is performed, and an in-phase component 307 and a quadrature component 308 of the data symbol transmission quadrature baseband signal are output.

The pilot symbol modulation signal generation section 303 receives the frame configuration signal 321 as an input, and when the frame configuration signal 321 indicates that it is a pilot symbol, converts the in-phase component 309 and the quadrature component 310 of the transmission orthogonal baseband signal of the pilot symbol. Output. However, this excludes the case of the pilot symbol immediately before the ramp symbol.

The pilot symbol modulated signal generation section 304 immediately before the ramp symbol receives the frame configuration signal 321 as an input, and when the frame configuration signal 321 indicates that the pilot symbol is immediately before the ramp symbol, the transmission orthogonal of the pilot symbol immediately before the ramp symbol is transmitted. An in-phase component 311 and a quadrature component 312 of the baseband signal are output.

The ramp symbol modulation signal generation section 305 receives the frame configuration signal 321 as an input, and outputs the in-phase component 313 and the quadrature component 314 of the transmission quadrature baseband signal of the ramp symbol when the frame configuration signal 321 indicates a ramp symbol.

The guard symbol modulation signal generation section 306 receives the frame configuration signal 321 as an input, and when the frame configuration signal 321 indicates a guard symbol, outputs the in-phase component 315 and the quadrature component 316 of the transmission orthogonal baseband signal of the guard symbol.

The in-phase component switching unit 317 includes an in-phase component 307 of the data symbol transmission quadrature baseband signal, an in-phase component 309 of the pilot symbol transmission quadrature baseband signal, an in-phase component 311 of the pilot symbol transmission quadrature baseband signal immediately before the ramp symbol, and a ramp. The in-phase component 313 of the transmission quadrature baseband signal of the symbol, the in-phase component 315 of the transmission quadrature baseband signal of the guard symbol, and the frame configuration signal 321 are input, and the transmission quadrature baseband signal corresponding to the symbol indicated by the frame configuration signal 321 is input. And outputs the selected in-phase component 319 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 318 includes an orthogonal component 308 of the data symbol transmission orthogonal baseband signal, an orthogonal component 310 of the pilot symbol transmission orthogonal baseband signal, an orthogonal component 312 of the pilot symbol transmission orthogonal baseband signal immediately before the ramp symbol, and a ramp. The orthogonal component 314 of the symbol transmission orthogonal baseband signal, the orthogonal component 316 of the guard symbol transmission orthogonal baseband signal, and the frame configuration signal 321 are input, and the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 321 is input. Are selected and output as the orthogonal component 320 of the selected transmission orthogonal baseband signal.

FIG. 4 shows a signal point arrangement of 16QAM, a pilot symbol, a pilot symbol immediately before a ramp symbol, a ramp symbol, and a guard symbol in an in-phase-quadrature plane, where 401 is a signal point of 16QAM, 402 is a signal point of a pilot symbol, 403 indicates a signal point of a pilot symbol immediately before a ramp symbol, and 404 indicates a signal point of a ramp or guard symbol.

FIG. 5 shows a signal point arrangement of 16QAM, a pilot symbol, a pilot symbol immediately before a ramp symbol, a ramp symbol, and a guard symbol in an in-phase-orthogonal plane, where 501 is a signal point of 16QAM, 502 is a signal point of a pilot symbol, Reference numeral 503 denotes a signal point of a pilot symbol immediately before a ramp symbol, and reference numeral 504 denotes a signal point of a ramp or guard symbol.

Next, a detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described with reference to FIGS. 1, 3, and 4.

When the frame configuration signal 321 in FIG. 3 indicates the data symbols 101, 102, 105, 106, and 107 in FIG. 1, the data symbol modulation signal generation unit 302 converts the transmission digital signal into, for example, a 16-QAM transmission orthogonal base. The in-phase component 307 and the quadrature component 308 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is any one of 401 in FIG.

When the frame configuration signal 321 in FIG. 3 indicates the pilot symbol 104 in FIG. 1, the pilot symbol modulation signal generation unit 303 outputs the in-phase component 309 and the quadrature component 310 of the transmission orthogonal baseband signal of the pilot symbol.

信号 At that time, signal points on the in-phase I-quadrature Q plane are indicated by 402 in FIG.

When the frame configuration signal 321 in FIG. 3 indicates the pilot symbol 108 in FIG. 1, that is, the pilot symbol immediately before the ramp symbol, the pilot symbol modulation signal generation unit 304 immediately before the ramp symbol generates the pilot symbol immediately before the ramp symbol. An in-phase component 311 and a quadrature component 312 of the transmission quadrature baseband signal are output. The signal point on the in-phase I-quadrature Q plane at that time is 403 in FIG. 4. Thus, by making the amplitude of the signal point 403 of the pilot symbol immediately before the ramp symbol smaller than the signal point 402 of the pilot symbol, It is possible to suppress the strength of the transmission signals of the guard symbols 113 and 114 to a specified value, and to more accurately comply with the specified adjacent channel leakage power.

When the frame configuration signal 321 in FIG. 3 indicates the ramp symbols 109, 110, 111, and 112 in FIG. 1, the ramp symbol modulation signal generation unit 305 determines the in-phase component 313 and the quadrature component of the transmission orthogonal baseband signal of the ramp symbol. Output the component 314. The signal point on the in-phase I-quadrature Q plane at that time is 404 in FIG.

When the frame configuration signal 321 in FIG. 3 indicates the guard symbols 113 and 114 in FIG. 1, the guard symbol modulation signal generation section 306 outputs the in-phase component 315 and the quadrature component 316 of the transmission orthogonal baseband signal of the guard symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 404 in FIG.

However, in the present embodiment, for example, when pilot symbols are BPSK-modulated, the signal points are arranged as shown in FIG.
The signal point of the pilot symbol 108 immediately before the ramp symbol is 503. Further, the modulation scheme of pilot symbols is not limited to BPSK modulation.

{Although the pilot symbol has been described as an example, the present invention can be similarly implemented as long as it is a symbol for demodulation. At this time, the symbols for demodulation mean, for example, pilot symbols, unique words, synchronization symbols, preambles, and control symbols.

構成 Also, the configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 1, and the modulation scheme of data symbols is not limited to 16QAM.

As described above, according to the present embodiment, the signal point amplitude of the symbol for demodulation immediately before the ramp symbol on the IQ plane is represented by the symbol signal for demodulation excluding the symbol for demodulation immediately before the ramp symbol. By making the amplitude smaller than the point amplitude, the intensity of the transmission signal can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately kept.

(Embodiment 2)
In the second embodiment, a case will be described in which signal points of a ramp symbol are arranged according to signal points of a symbol for demodulation immediately before a ramp symbol on the IQ plane.

の 一 An example of the frame configuration on the time axis according to the present embodiment is as shown in FIG. An example of the configuration of the transmitting apparatus according to the present embodiment is as shown in FIG.

FIG. 6 shows an example of the detailed configuration of the modulation signal generation section 202 of FIG. 2. The data symbol modulation signal generation section 602 receives the transmission digital signal 601 and the frame configuration signal 621 as inputs, and outputs the frame configuration signal 621. If the data symbol is indicated, the signal is subjected to 16QAM modulation and the in-phase component 607 and the quadrature component 608 of the data symbol transmission quadrature baseband signal are output.

The pilot symbol modulation signal generation section 603 receives the frame configuration signal 621 as an input, and if the frame configuration signal 621 indicates that it is a pilot symbol, converts the in-phase component 609 and the quadrature component 610 of the transmission orthogonal baseband signal of the pilot symbol. Output.

If the frame configuration signal 621 is input and the frame configuration signal 621 indicates that it is the ramp symbol immediately after the pilot symbol, the ramp symbol modulation signal generation unit 604 immediately after the pilot symbol transmits the quadrature of the ramp symbol immediately after the pilot symbol. An in-phase component 611 and a quadrature component 612 of the baseband signal are output.

The ramp symbol modulation signal generator 605 receives the frame configuration signal 621 as an input, and outputs the in-phase component 613 and the quadrature component 614 of the transmission quadrature baseband signal of the ramp symbol when the frame configuration signal 621 indicates a ramp symbol.

The guard symbol modulation signal generation section 606 receives the frame configuration signal 621 as an input, and when the frame configuration signal 621 indicates a guard symbol, outputs the in-phase component 615 and the quadrature component 616 of the transmission orthogonal baseband signal of the guard symbol.

The in-phase component switching section 617 includes an in-phase component 607 of the data symbol transmission quadrature baseband signal, an in-phase component 609 of the pilot symbol transmission quadrature baseband signal, an in-phase component 611 of the lamp symbol transmission quadrature baseband signal immediately after the pilot symbol, and a ramp. The in-phase component 613 of the transmission orthogonal baseband signal of the symbol, the in-phase component 615 of the transmission orthogonal baseband signal of the guard symbol, and the frame configuration signal 621 are input, and the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 621 is input. Is selected and output as the in-phase component 619 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 618 includes: an orthogonal component 608 of a data symbol transmission orthogonal baseband signal; an orthogonal component 610 of a transmission orthogonal baseband signal of a pilot symbol; an orthogonal component 612 of a transmission orthogonal baseband signal of a lamp symbol immediately after the pilot symbol; The orthogonal component 614 of the transmission orthogonal baseband signal of the symbol, the orthogonal component 616 of the transmission orthogonal baseband signal of the guard symbol, and the frame configuration signal 621 are input, and the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 621 is input. Are selected and output as the orthogonal component 620 of the selected transmission orthogonal baseband signal.

FIG. 7 shows a signal point arrangement of 16QAM, a pilot symbol, a ramp symbol immediately after the pilot symbol, a ramp symbol, and a guard symbol in an in-phase-orthogonal plane, where 701 is a signal point of 16QAM, 702 is a signal point of a pilot symbol, Reference numeral 703 denotes a signal point of a lamp symbol immediately after a pilot symbol, and reference numeral 704 denotes a signal point of a ramp or guard symbol.

FIG. 8 shows a signal point arrangement of 16QAM, a pilot symbol, a lamp symbol, a lamp symbol, and a guard symbol immediately after the pilot symbol in the in-phase-quadrature plane, where 801 is a signal point of 16QAM, 802 is a signal point of a pilot symbol, Reference numeral 803 denotes a signal point of a lamp symbol immediately after a pilot symbol, and reference numeral 804 denotes a signal point of a ramp or guard symbol.

Next, the detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described with reference to FIGS. 1, 6, and 7.

When the frame configuration signal 621 in FIG. 6 indicates the data symbols 101, 102, 105, 106, and 107 in FIG. 1, the data symbol modulation signal generation unit 602 converts the transmission digital signal into, for example, a 16-QAM transmission orthogonal base. An in-phase component 607 and a quadrature component 608 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is one of 701 in FIG.

When the frame configuration signal 621 in FIG. 6 indicates the pilot symbols 104 and 108 in FIG. 1, the pilot symbol modulation signal generation unit 603 outputs the in-phase component 609 and the quadrature component 610 of the transmission orthogonal baseband signal of the pilot symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 702 in FIG.

When the frame configuration signal 621 in FIG. 6 indicates the ramp symbol 109 in FIG. 1, that is, the ramp symbol immediately after the pilot symbol, the ramp symbol modulation signal generation unit 604 immediately after the pilot symbol generates the ramp symbol immediately after the pilot symbol. An in-phase component 611 and a quadrature component 612 of the transmission quadrature baseband signal are output. The signal point on the in-phase I-quadrature Q plane at that time is 703 in FIG. 7. Thus, by arranging the signal point of the lamp symbol immediately after the pilot symbol according to pilot symbol 108, guard symbol 113 , 114 can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately kept.

When the frame configuration signal 621 in FIG. 6 indicates the ramp symbols 110, 111, and 112 in FIG. 1, the ramp symbol modulation signal generation unit 605 determines the in-phase component 613 and the quadrature component 614 of the transmission orthogonal baseband signal of the ramp symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is 704 in FIG.

When the frame configuration signal 621 in FIG. 6 indicates the guard symbols 113 and 114 in FIG. 1, the guard symbol modulation signal generation unit 606 outputs the in-phase component 615 and the quadrature component 616 of the transmission orthogonal baseband signal of the guard symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 704 in FIG.

However, in the present embodiment, for example, when pilot symbols are BPSK-modulated, the signal points are arranged as shown in FIG. 8, the signal points of pilot symbols 104 and 108 are 802, and the The number of signal points is 803. Further, the modulation scheme of pilot symbols is not limited to BPSK modulation.

{Although the pilot symbol has been described as an example, the present invention can be similarly implemented as long as it is a symbol for demodulation. At this time, the symbol for demodulation means, for example, a pilot symbol, a unique word, a preamble, and a control symbol.

構成 Further, the configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 1, and the modulation scheme of data symbols is not limited to 16QAM.

In the IQ plane, only the signal point of the ramp symbol 109 immediately after the pilot symbol is arranged according to the signal point of the pilot symbol 108. However, the present invention is not limited to this, and the signal points of the lamp symbols 110, 111, and 112 are not limited thereto. May be arranged according to the signal point of pilot symbol 108.

As described above, according to the present embodiment, the intensity of a transmission signal is defined by arranging signal points of a ramp symbol in accordance with signal points of a symbol for demodulation immediately before a ramp symbol on the IQ plane. Value, and the regulation of the adjacent channel leakage power can be more accurately observed.

(Embodiment 3)
Embodiment 3 describes a case where an attenuation control symbol is arranged immediately before a ramp symbol.

FIG. 9 shows an example of a frame configuration on the time axis according to the present embodiment. Reference numerals 901, 902, 903, 905, 906, and 907 denote data symbols, for example, symbols modulated by 16 QAM. . 904 and 908 are pilot symbols, 909 is an attenuation control symbol, 910, 911 and 912 are ramp symbols, and 913 and 914 are guard symbols. At this time, if a specified value of the strength of the transmission signal is defined for the guard symbols 913 and 914, it is necessary to keep the value within the specified value. The lamp symbols 910, 911, and 912 are symbols necessary for suppressing the strength of the transmission signals of the guard symbols 913 and 914 to a specified value.

の 一 An example of the configuration of the transmitting apparatus according to the present embodiment is as shown in FIG.

FIG. 10 shows an example of the detailed configuration of the modulation signal generation section 202 of FIG. 2. The data symbol modulation signal generation section 1002 receives the transmission digital signal 1001 and the frame configuration signal 1021 as inputs, and outputs the frame configuration signal 1021. If it indicates that the symbol is a data symbol, 16QAM modulation is performed, and an in-phase component 1007 and a quadrature component 1008 of the data symbol transmission quadrature baseband signal are output.

Pilot symbol modulation signal generating section 1003 receives frame configuration signal 1021 as input, and when frame configuration signal 1021 indicates that it is a pilot symbol, generates in-phase component 1009 and quadrature component 1010 of the transmission orthogonal baseband signal of the pilot symbol. Output.

When receiving the frame configuration signal 1021 and indicating that the frame configuration signal 1021 is an attenuation control symbol, the attenuation control symbol modulation signal generation unit 1004 receives the in-phase component 1011 and the quadrature component of the transmission orthogonal baseband signal of the attenuation control symbol. Output the component 1012.

The ramp symbol modulation signal generation unit 1005 receives the frame configuration signal 1021 as an input, and outputs the in-phase component 1013 and the quadrature component 1014 of the transmission quadrature baseband signal of the ramp symbol when the frame configuration signal 1021 indicates a ramp symbol.

The guard symbol modulation signal generation section 1006 receives the frame configuration signal 1021 as an input, and when the frame configuration signal 1021 indicates a guard symbol, outputs the in-phase component 1015 and the quadrature component 1016 of the transmission orthogonal baseband signal of the guard symbol.

The in-phase component switching unit 1017 includes an in-phase component 1007 of a data symbol transmission quadrature baseband signal, an in-phase component 1009 of a pilot symbol transmission quadrature baseband signal, an in-phase component 1011 of an attenuation control symbol transmission quadrature baseband signal, and ramp symbol transmission. The in-phase component 1013 of the orthogonal baseband signal, the in-phase component 1015 of the transmission orthogonal baseband signal of the guard symbol, and the frame configuration signal 1021 are input and the in-phase component of the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 1021 is input. And outputs it as the in-phase component 1019 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 1018 includes: an orthogonal component 1008 of the data symbol transmission orthogonal baseband signal; an orthogonal component 1010 of the transmission orthogonal baseband signal of the pilot symbol; an orthogonal component 1012 of the transmission orthogonal baseband signal of the attenuation control symbol; The orthogonal component 1014 of the orthogonal baseband signal, the orthogonal component 1016 of the transmission orthogonal baseband signal of the guard symbol, and the frame configuration signal 1021 are input and the orthogonal component of the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 1021 is input. And outputs it as the orthogonal component 1020 of the selected transmission orthogonal baseband signal.

FIG. 11 shows a signal point arrangement of 16QAM, a pilot symbol, an attenuation control symbol, a ramp symbol, and a guard symbol in the in-phase-quadrature plane, where 1101 is a signal point of 16QAM, 1102 is a signal point of pilot symbol, and 1103 is an attenuation point Control symbol signal points 1104 indicate ramp and guard symbol signal points.

FIG. 12 shows a signal point arrangement of 16QAM, a pilot symbol, an attenuation control symbol, a ramp symbol, and a guard symbol on an in-phase-quadrature plane, where 1201 is a 16QAM signal point, 1202 is a pilot symbol signal point, and 1203 is an attenuation Control symbol signal points 1204 indicate ramp and guard symbol signal points.

Next, a detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described with reference to FIGS. 9, 10, and 11.

When the frame configuration signal 1021 in FIG. 10 indicates the data symbols 901, 902, 905, 906, and 907 in FIG. 9, the data symbol modulation signal generation unit 1002 converts the transmission digital signal into, for example, a 16-QAM transmission orthogonal base. An in-phase component 1007 and a quadrature component 1008 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is one of 1101 in FIG.

When frame configuration signal 1021 in FIG. 10 indicates pilot symbols 904 and 908 in FIG. 9, pilot symbol modulation signal generating section 1003 outputs in-phase component 1009 and quadrature component 1010 of the transmission orthogonal baseband signal of the pilot symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 1102 in FIG.

When the frame configuration signal 1021 of FIG. 10 indicates the attenuation control symbol 909 of FIG. 9, the attenuation control symbol modulation signal generation unit 1004 converts the in-phase component 1011 and the quadrature component 1012 of the transmission orthogonal baseband signal of the attenuation control symbol. Output. The signal point on the in-phase I-quadrature Q plane at that time is 1103 in FIG. 11. Thus, by arranging the signal point of the attenuation control symbol in accordance with the pilot symbol, the guard symbol 913 is obtained. , 914 to a specified value, and the specification of the adjacent channel leakage power can be more accurately maintained.

When the frame configuration signal 1021 in FIG. 10 indicates the ramp symbols 910, 911, and 912 in FIG. 9, the ramp symbol modulation signal generation unit 1005 outputs the in-phase component 1013 and the quadrature component 1014 of the transmission orthogonal baseband signal of the ramp symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is 1104 in FIG.

When the frame configuration signal 1021 in FIG. 10 indicates the guard symbols 913 and 914 in FIG. 9, the guard symbol modulation signal generation unit 1006 outputs the in-phase component 1015 and the quadrature component 1016 of the transmission orthogonal baseband signal of the guard symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 1104 in FIG.

However, in the present embodiment, for example, when pilot symbols are BPSK-modulated, the signal points are arranged as shown in FIG. 12, the signal points of pilot symbols 904 and 908 are 1202, and the signal points of attenuation control symbol 909 are Becomes 1203. Further, the modulation scheme of pilot symbols is not limited to BPSK modulation.

{Although the pilot symbol has been described as an example, the present invention can be similarly implemented as long as it is a symbol for demodulation. At this time, the symbol for demodulation means, for example, a pilot symbol, a unique word, a preamble, and a control symbol.

構成 Also, the configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 1, and the attenuation control symbol is described as one symbol, but a plurality of symbols may be used. Further, the modulation scheme of the data symbol is not limited to 16QAM.

減 衰 The attenuation control symbol may be regarded as a symbol for demodulation such as a pilot symbol, a unique word, a preamble, and a control symbol.

As described above, according to the present embodiment, by arranging the attenuation control symbol immediately before the ramp symbol, the strength of the transmission signal can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately maintained.

(Embodiment 4)
In the fourth embodiment, an attenuation control symbol is arranged immediately before a ramp symbol, and a signal point amplitude of a symbol for demodulation before the attenuation control symbol on the IQ plane is set to a symbol for demodulation before the attenuation control symbol. A case where the amplitude is smaller than the signal point amplitude of a symbol for demodulation excluding will be described.

フ レ ー ム An example of the frame configuration on the time axis according to the present embodiment is as shown in FIG. An example of the configuration of the transmitting apparatus according to the present embodiment is as shown in FIG.

FIG. 13 illustrates an example of a detailed configuration of the modulation signal generation unit 202 of FIG. 2. The data symbol modulation signal generation unit 1302 receives the transmission digital signal 1301 and the frame configuration signal 1321 as inputs, and the frame configuration signal 1321 is If the data symbol is indicated, 16QAM modulation is performed, and an in-phase component 1307 and a quadrature component 1308 of the data symbol transmission quadrature baseband signal are output.

Pilot symbol modulation signal generating section 1303 receives frame configuration signal 1321 as input, and when frame configuration signal 1321 indicates that it is a pilot symbol, generates in-phase component 1309 and quadrature component 1310 of the transmission orthogonal baseband signal of the pilot symbol. Output.

Pilot symbol modulation signal generation section 1304 before the attenuation control symbol receives frame configuration signal 1321 as input, and indicates that frame configuration signal 1321 is a pilot symbol before the attenuation control symbol. Output the in-phase component 1311 and the quadrature component 1312 of the transmission quadrature baseband signal.

When the frame configuration signal 1321 is input and the frame configuration signal 1321 indicates an attenuation control symbol, the attenuation control symbol modulation signal generation unit 1305 converts the in-phase component 1313 and the quadrature component 1314 of the transmission orthogonal baseband signal of the attenuation control symbol into an attenuation control symbol. Output.

The ramp and guard symbol modulation signal generation section 1306 receives the frame configuration signal 1321 as an input, and when the frame configuration signal 1321 indicates a ramp or guard symbol, the in-phase component 1315 and the quadrature component 1315 of the transmission orthogonal baseband signal of the ramp or guard symbol. Output component 1316.

The in-phase component switching unit 1317 includes an in-phase component 1307 of the data symbol transmission quadrature baseband signal, an in-phase component 1309 of the pilot symbol transmission quadrature baseband signal, an in-phase component 1311 of the pilot symbol transmission quadrature baseband signal before the attenuation control symbol, The in-phase component 1313 of the transmission quadrature baseband signal of the attenuation control symbol, the in-phase component 1315 of the transmission quadrature baseband signal of the ramp or guard symbol, and the frame configuration signal 1321 are input, and transmission corresponding to the symbol indicated by the frame configuration signal 1321 is performed. The in-phase component of the quadrature baseband signal is selected and output as the in-phase component 1319 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 1318 includes an orthogonal component 1308 of the data symbol transmission orthogonal baseband signal, an orthogonal component 1310 of the transmission orthogonal baseband signal of the pilot symbol, an orthogonal component 1312 of the transmission orthogonal baseband signal of the pilot symbol before the attenuation control symbol, The orthogonal component 1314 of the transmission orthogonal baseband signal of the attenuation control symbol, the orthogonal component 1316 of the transmission orthogonal baseband signal of the ramp or guard symbol, and the frame configuration signal 1321 are input and the transmission corresponding to the symbol indicated by the frame configuration signal 1321 is performed. The orthogonal component of the orthogonal baseband signal is selected and output as the orthogonal component 1320 of the selected transmission orthogonal baseband signal.

FIG. 14 shows the signal point arrangement of 16QAM, pilot symbols, attenuation control symbols, ramp symbols, and guard symbols in the in-phase-quadrature plane, where 1401 is a 16QAM signal point, 1402 is a pilot symbol signal point, and 1403 is an attenuation signal point. Signal points of pilot symbols before control symbols, 1404 indicates signal points of attenuation control symbols, and 1405 indicates signal points of ramp and guard symbols.

FIG. 15 shows signal point constellations of 16QAM, pilot symbols, attenuation control symbols, ramp symbols, and guard symbols in the in-phase-quadrature plane, where 1501 is a 16QAM signal point, 1502 is a pilot symbol signal point, and 1503 is an attenuation. Signal points of pilot symbols before control symbols, signal points of attenuation control symbols 1504, and signal points of ramp and guard symbols 1505 are shown.

Next, the detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described using FIG. 9, FIG. 13, and FIG.

When the frame configuration signal 1321 in FIG. 13 indicates the data symbols 901, 902, 905, 906, and 907 in FIG. 9, the data symbol modulation signal generation section 1302 converts the transmission digital signal into, for example, a 16 QAM transmission quadrature base. An in-phase component 1307 and a quadrature component 1308 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is one of 1401 in FIG.

When the frame configuration signal 1321 in FIG. 13 indicates the pilot symbol 904 in FIG. 9, the pilot symbol modulation signal generator 133 outputs the in-phase component 1309 and the quadrature component 1310 of the transmission orthogonal baseband signal of the pilot symbol. Signal points on the in-phase I-quadrature Q plane at that time are 1402 in FIG.

When the frame configuration signal 1321 in FIG. 13 indicates the pilot symbol 908 before the attenuation control symbol in FIG. 9, the pilot symbol modulation signal generation section 1304 before the attenuation control symbol transmits the pilot orthogonal symbol before the attenuation control symbol. An in-phase component 1311 and a quadrature component 1312 of the baseband signal are output. The signal point on the in-phase I-quadrature Q plane at that time is 1403 in FIG. 14. Thus, the signal point amplitude of the pilot symbol before the attenuation control symbol is changed by the pilot symbol excluding the pilot symbol before the attenuation control symbol. By making the signal point amplitude smaller than the signal point amplitude, the strength of the transmission signal of the guard symbols 913 and 914 can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately kept.

When the frame configuration signal 1321 in FIG. 13 indicates the attenuation control symbol 909 in FIG. 9, the attenuation control symbol modulation signal generation unit 1305 generates the in-phase component 1313 and the quadrature component 1314 of the transmission orthogonal baseband signal of the attenuation control symbol. Output. The signal point on the in-phase I-quadrature Q plane at that time is 1404 in FIG. By arranging the signal points of the attenuation control symbol in accordance with the pilot symbol before the attenuation control symbol in this manner, the strength of the transmission signals of the guard symbols 913 and 914 is suppressed to a specified value, and the adjacent channel leakage It is possible to more precisely comply with the power regulations.

When the frame configuration signal 1321 in FIG. 13 indicates the ramp symbols 910, 911, 912, and the guard symbols 913, 914 in FIG. 9, the ramp and guard symbol modulation signal generation unit 1306 transmits the ramp or guard symbol transmission orthogonal base. An in-phase component 1315 and a quadrature component 1316 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is 1405 in FIG.

However, in the present embodiment, for example, when the pilot symbol is BPSK modulated, the signal points are arranged as shown in FIG. 15, the signal point of pilot symbol 904 is 1502, and the pilot symbol 908 before the attenuation control symbol is located. The signal point is 1503, and the signal point of the attenuation control symbol 909 is 1504. Further, the modulation scheme of pilot symbols is not limited to BPSK modulation.

{Although the pilot symbol has been described as an example, the present invention can be similarly implemented as long as it is a symbol for demodulation. At this time, the symbol for demodulation means, for example, a pilot symbol, a unique word, a preamble, and a control symbol.

構成 Also, the configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 9, and the attenuation control symbol is described as one symbol, but may be a plurality of symbols. Further, the modulation scheme of the data symbol is not limited to 16QAM.

減 衰 The attenuation control symbol may be regarded as a symbol for demodulation such as a pilot symbol, a unique word, a preamble, and a control symbol.

As described above, according to the present embodiment, the attenuation control symbol is arranged immediately before the ramp symbol, and the signal point amplitude of the symbol for demodulation before the attenuation control symbol on the IQ plane is changed. By making the signal point amplitude smaller than the demodulation symbol excluding the demodulation symbols, the strength of the transmission signal can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately maintained.

(Embodiment 5)
In the fifth embodiment, a case will be described in which signal points of a ramp symbol are arranged according to signal points of a data symbol immediately before a ramp symbol on the IQ plane.

FIG. 16 shows an example of a frame configuration on the time axis according to the present embodiment, and 1601, 1602, 1603, 1607, and 1608 show data symbols, for example, symbols modulated by QPSK. Reference numerals 1604, 1605 and 1606 denote pilot symbols, 1609, 1610, 1611 and 1612 denote ramp symbols, and 1613 and 1614 denote guard symbols. At this time, if a specified value of the strength of the transmission signal is defined for the guard symbols 1613 and 1614, it is necessary to keep it within the specified value. The lamp symbols 1609, 1610, 1611, and 1612 are symbols necessary for suppressing the strength of the transmission signals of the guard symbols 1613 and 1614 to a specified value.

の 一 An example of the configuration of the transmitting apparatus according to the present embodiment is as shown in FIG.

FIG. 17 shows an example of a detailed configuration of the modulation signal generation section 202 in FIG. 2. The data symbol modulation signal generation section 1702 receives the transmission digital signal 1701 and the frame configuration signal 1721 as inputs, and the frame configuration signal 1721 is If it indicates that the symbol is a data symbol, QPSK modulation is performed, and the in-phase component 1707 and the quadrature component 1708 of the data symbol transmission quadrature baseband signal are output.

Pilot symbol modulation signal generating section 1703 receives frame configuration signal 1721 as input, and when frame configuration signal 1721 indicates that it is a pilot symbol, generates in-phase component 1709 and quadrature component 1710 of the transmission orthogonal baseband signal of the pilot symbol. Output.

When the lamp symbol modulation signal generation section 1704 immediately after the data symbol receives the frame configuration signal 1721 and the information 1722 of the data symbol immediately before the ramp symbol as input, and indicates that the frame configuration signal 1721 is a ramp symbol immediately after the pilot symbol The in-phase component 1711 and the quadrature component 1712 of the transmission quadrature baseband signal of the ramp symbol immediately after the data symbol are output based on the information 1722 of the data symbol immediately before the ramp symbol.

If the frame configuration signal 1721 is input and the frame configuration signal 1721 indicates a lamp symbol excluding the lamp symbol immediately after the data symbol, the ramp symbol modulation signal generation unit 1705 receives the in-phase component 1713 of the transmission quadrature baseband signal of the lamp symbol. And an orthogonal component 1714 are output.

The guard symbol modulation signal generation section 1706 receives the frame configuration signal 1721 as an input, and outputs the in-phase component 1715 and the quadrature component 1716 of the transmission orthogonal baseband signal of the guard symbol when the frame configuration signal 1721 indicates a guard symbol.

The in-phase component switching unit 1717 includes an in-phase component 1707 of a data symbol transmission quadrature baseband signal, an in-phase component 1709 of a pilot symbol transmission quadrature baseband signal, an in-phase component 1711 of a lamp symbol transmission quadrature baseband signal immediately after the data symbol, and a ramp. The in-phase component 1713 of the transmission quadrature baseband signal of the symbol, the in-phase component 1715 of the transmission quadrature baseband signal of the guard symbol, and the frame configuration signal 1721 are input, and the transmission quadrature baseband signal corresponding to the symbol indicated by the frame configuration signal 1721 is input. Are selected and output as the in-phase component 1719 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 1718 includes an orthogonal component 1708 of the data symbol transmission orthogonal baseband signal, an orthogonal component 1710 of the transmission orthogonal baseband signal of the pilot symbol, an orthogonal component 1712 of the transmission orthogonal baseband signal of the lamp symbol immediately after the data symbol, and a ramp. The orthogonal component 1714 of the symbol transmission orthogonal baseband signal, the orthogonal component 1716 of the guard symbol transmission orthogonal baseband signal, and the frame configuration signal 1721 are input, and the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 1721 is input. Are selected and output as the orthogonal component 1720 of the selected transmission orthogonal baseband signal.

FIG. 18 shows signal point constellations of a QPSK, a pilot symbol, and a ramp symbol, a ramp symbol, and a guard symbol immediately after a data symbol on an in-phase-orthogonal plane, where 1801, 1802, 1803, and 1804 denote QPSK signal points, Reference numeral 1806 denotes a signal point of a pilot symbol, 1807, 1808, 1809, and 1810 denote signal points of a ramp symbol immediately after a data symbol, and 1811 denotes signal points of a ramp and a guard symbol.

Next, a detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described with reference to FIG. 16, FIG. 17, and FIG.

When the frame configuration signal 1721 in FIG. 17 indicates the data symbols 1601, 1602, 1603, 1607, and 1608 in FIG. 16, the data symbol modulation signal generation section 1702 converts the transmission digital signal into, for example, a QPSK transmission quadrature base. An in-phase component 1707 and a quadrature component 1708 of the band signal are output. The signal point on the in-phase I-quadrature Q plane at that time is one of 1801, 1802, 1803, and 1804 in FIG.

When the frame configuration signal 1721 in FIG. 17 indicates the pilot symbols 1604, 1605, and 1606 in FIG. 16, the pilot symbol modulation signal generation unit 1703 outputs the in-phase component 1709 and the quadrature component 1710 of the transmission orthogonal baseband signal of the pilot symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is one of 1805 and 1806 in FIG.

When the frame configuration signal 1721 in FIG. 17 indicates the ramp symbol 1609 in FIG. 16, that is, the lamp symbol immediately after the data symbol, the lamp symbol modulation signal generation unit 1704 immediately after the data symbol outputs the data symbol of the data symbol immediately before the ramp symbol. Based on information 1722, in-phase component 1711 and quadrature component 1712 of the transmission quadrature baseband signal of the ramp symbol immediately after the data symbol are output. In this case, the signal point of the ramp symbol immediately after the data symbol on the in-phase I-quadrature Q plane indicates that the signal point of the data symbol 1608 is 1801 from the information 1722 of the data symbol immediately before the ramp symbol. , 1807. If the signal point of the data symbol 1608 indicates that the signal point is 1802, the signal point is 1808; if the signal point is 1803, the signal point is 1809; and if the signal point of the data symbol 1608 is 1804, the signal point is 1810. Thus, by arranging the signal point of the ramp symbol immediately after the data symbol according to the data symbol 1608, the strength of the transmission signal of the guard symbols 1613 and 1614 is suppressed to a specified value, and the specification of the adjacent channel leakage power is improved. It is possible to protect with high accuracy.

When the frame configuration signal 1721 in FIG. 17 indicates the ramp symbols 1610, 1611, and 1612 in FIG. 16, the ramp symbol modulation signal generation unit 1705 determines the in-phase component 1713 and the quadrature component 1714 of the transmission orthogonal baseband signal of the ramp symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is 1811 in FIG.

When the frame configuration signal 1721 in FIG. 17 indicates the guard symbols 1613 and 1614 in FIG. 16, the guard symbol modulation signal generation unit 1706 outputs the in-phase component 1715 and the quadrature component 1716 of the transmission orthogonal baseband signal of the guard symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 1811 in FIG.

構成 The configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 16, and the modulation scheme for data symbols is not limited to QPSK.

In the IQ plane, only the signal point of the ramp symbol 1609 immediately after the pilot symbol is arranged according to the signal point of the data symbol 1608. However, the present invention is not limited to this, and the signal points of the lamp symbols 1610, 1611, and 1612 are not limited thereto. May be arranged according to the signal point of the data symbol 1608.

As described above, according to the present embodiment, the signal point of the ramp symbol is arranged in accordance with the signal point of the data symbol immediately before the ramp symbol on the IQ plane, so that the intensity of the transmission signal is suppressed to the specified value. Therefore, the regulation of the adjacent channel leakage power can be more accurately observed.

(Embodiment 6)
Embodiment 6 describes a case where an attenuation control symbol is arranged immediately before a ramp symbol and a signal point of the attenuation control symbol is arranged on the IQ plane according to a data symbol before the attenuation control symbol.

FIG. 19 illustrates an example of a frame configuration on the time axis according to the present embodiment, where 1901, 1902, 1903, 1907, and 1908 indicate data symbols, for example, symbols that are modulated by QPSK. 1904, 1905 and 1906 are pilot symbols, 1909 is an attenuation control symbol, 1910, 1911 and 1912 are ramp symbols, and 1913 and 1914 are guard symbols. At this time, if a specified value of the strength of the transmission signal is defined for the guard symbols 1913 and 1914, it is necessary to keep the value within the specified value. The lamp symbols 1910, 1911, and 1912 are symbols necessary for suppressing the strength of the transmission signals of the guard symbols 1913 and 1914 to a specified value.

の 一 An example of the configuration of the transmitting apparatus according to the present embodiment is as shown in FIG.

FIG. 20 shows an example of a detailed configuration of the modulation signal generation section 202 of FIG. 2. The data symbol modulation signal generation section 2002 receives the transmission digital signal 2001 and the frame configuration signal 2021 as inputs, and outputs the frame configuration signal 2021. If it indicates that the symbol is a data symbol, QPSK modulation is performed, and the in-phase component 2007 and the quadrature component 2008 of the data symbol transmission quadrature baseband signal are output.

Pilot symbol modulation signal generation section 2003 receives frame configuration signal 2021 as input, and when frame configuration signal 2021 indicates that it is a pilot symbol, generates in-phase component 2009 and quadrature component 2010 of the transmission orthogonal baseband signal of the pilot symbol. Output.

The attenuation control symbol modulation signal generation section 2004 receives the frame configuration signal 2021 and information 2022 of the data symbol immediately before the attenuation control symbol, and if the frame configuration signal 2021 indicates that the signal is the attenuation control symbol, Based on the data symbol information 2022, the in-phase component 2011 and the quadrature component 2012 of the transmission quadrature baseband signal of the attenuation control symbol are output.

The ramp symbol modulation signal generation unit 2005 receives the frame configuration signal 2021 and outputs the in-phase component 2013 and the quadrature component 2014 of the transmission quadrature baseband signal of the ramp symbol when the frame configuration signal 2021 indicates a ramp symbol.

The guard symbol modulation signal generation unit 2006 receives the frame configuration signal 2021 and outputs the in-phase component 2015 and the quadrature component 2016 of the transmission quadrature baseband signal of the guard symbol when the frame configuration signal 2021 indicates a guard symbol.

The in-phase component switching unit 2017 includes an in-phase component 2007 of a data symbol transmission quadrature baseband signal, an in-phase component 2009 of a pilot symbol transmission quadrature baseband signal, an in-phase component 2011 of an attenuation control symbol transmission quadrature baseband signal, and ramp symbol transmission. The in-phase component 2013 of the quadrature baseband signal, the in-phase component 2015 of the guard symbol transmission quadrature baseband signal, and the frame configuration signal 2021 are input, and the in-phase component of the transmission quadrature baseband signal corresponding to the symbol indicated by the frame configuration signal 2021 And outputs it as the in-phase component 2019 of the selected transmission quadrature baseband signal.

The orthogonal component switching unit 2018 includes an orthogonal component 2008 of a data symbol transmission orthogonal baseband signal, an orthogonal component 2010 of a pilot symbol transmission orthogonal baseband signal, an orthogonal component 2012 of an attenuation control symbol transmission orthogonal baseband signal, and a ramp symbol transmission. The orthogonal component 2014 of the orthogonal baseband signal, the orthogonal component 2016 of the transmission orthogonal baseband signal of the guard symbol, and the frame configuration signal 2021 are input, and the orthogonal component of the transmission orthogonal baseband signal corresponding to the symbol indicated by the frame configuration signal 2021 is input. And outputs it as the orthogonal component 2020 of the selected transmission orthogonal baseband signal.

FIG. 21 shows signal point constellations of QPSK, pilot symbols, attenuation control symbols, ramp symbols, and guard symbols in the in-phase-quadrature plane, where reference numerals 2101, 2102, 2103, and 2104 denote QPSK signal points, Symbol signal points 2107, 2108, 2109, and 2110 indicate attenuation control symbol signal points, and 2111 indicates ramp and guard symbol signal points.

Next, a detailed operation of the modulation signal generation unit 202 in FIG. 2 will be described with reference to FIGS. 19, 20, and 21.

When the frame configuration signal 2021 in FIG. 20 indicates the data symbols 1901, 1902, 1903, 1907, and 1908 in FIG. 19, the data symbol modulation signal generation unit 2002 converts the transmission digital signal into, for example, a QPSK transmission orthogonal base. An in-phase component 2007 and a quadrature component 2008 of the band signal are output. At this time, the signal point on the in-phase I-quadrature Q plane is one of 2101, 2102, 2103, and 2104 in FIG.

When the frame configuration signal 2021 in FIG. 20 indicates the pilot symbols 1904, 1905, and 1906 in FIG. 19, the pilot symbol modulation signal generation section 2003 transmits the in-phase component 2009 and the quadrature component 2010 of the transmission orthogonal baseband signal of the pilot symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is one of 2105 and 2106 in FIG.

When the frame configuration signal 2021 in FIG. 20 indicates the attenuation control symbol 1909 in FIG. 19, the attenuation control symbol modulation signal generation unit 2004 determines the attenuation control symbol based on the information 2022 of the data symbol immediately before the attenuation control symbol. Output the in-phase component 2011 and the quadrature component 2012 of the transmission quadrature baseband signal. At this time, the signal point of the attenuation control symbol on the in-phase I-quadrature Q plane is, for example, 2107 if the signal point of the data symbol 1908 is 2101 from the information 2022 of the data symbol immediately before the attenuation control symbol. And If the signal point of the data symbol 1908 is 2102, it is 2108, if it is 2103, it is 2109, and if it is 2104, it is 2110. By arranging the signal points of the attenuation control symbols in accordance with the data symbols 1908 in this manner, the strength of the transmission signals of the guard symbols 1913 and 1914 is suppressed to a specified value, and the specification of the adjacent channel leakage power is more accurately maintained. It becomes possible.

When the frame configuration signal 2021 in FIG. 20 indicates the ramp symbols 1910, 1911, and 1912 in FIG. 19, the ramp symbol modulation signal generation unit 2005 outputs the in-phase component 2013 and the quadrature component 2014 of the transmission orthogonal baseband signal of the ramp symbol. Is output. The signal point on the in-phase I-quadrature Q plane at that time is 2111 in FIG.

When the frame configuration signal 2021 in FIG. 20 indicates the guard symbols 1913 and 1914 in FIG. 19, the guard symbol modulation signal generation unit 2006 outputs the in-phase component 2015 and the quadrature component 2016 of the transmission orthogonal baseband signal of the guard symbol. I do. The signal point on the in-phase I-quadrature Q plane at that time is 2111 in FIG.

構成 The configuration of the transmitting apparatus according to the present embodiment is not limited to FIGS. The frame configuration is not limited to that shown in FIG. 19, and the modulation scheme for data symbols is not limited to QPSK. Further, the attenuation control symbol has been described as one symbol, but may be a plurality of symbols.

減 衰 The attenuation control symbol may be regarded as a symbol for demodulation such as a pilot symbol, a unique word, a preamble, and a control symbol.

As described above, according to the present embodiment, an attenuation control symbol is arranged immediately before a ramp symbol, and a signal point of the attenuation control symbol is arranged on the IQ plane according to a data symbol before the attenuation control symbol. Thus, the strength of the transmission signal can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately maintained.

(Embodiment 7)
Embodiment 7 describes a receiving apparatus that estimates transmission line distortion and frequency offset using attenuation control symbols.

フ レ ー ム An example of the frame configuration on the time axis according to the present embodiment is as shown in FIG.

FIG. 22 illustrates an example of a configuration of a reception device in this embodiment. Radio section 2203 receives reception signal 2202 received by antenna 2201, and outputs a reception orthogonal baseband signal 2204.

The channel distortion estimator 2205 receives the received orthogonal baseband signal 2204 as input, estimates channel distortion, and outputs a channel distortion estimated signal 2206. The frequency offset estimator 2207 receives the received orthogonal baseband signal 2204 as input. , And a frequency offset, and outputs a frequency offset estimation signal 2208.

The demodulation unit 2209 receives the received orthogonal baseband signal 2204, the transmission path distortion estimation signal 2206, and the frequency offset estimation signal 2208, removes the frequency offset and the transmission path distortion from the received orthogonal baseband signal 2204, demodulates, and demodulates. The digital signal 2210 is output.

FIG. 23 shows an example of the detailed configuration of the transmission line distortion estimator 2205 shown in FIG. 22. The pilot symbol extraction function 2302 receives the received orthogonal baseband signal 2301, extracts pilot symbols, 2303 is output.

Attenuation control symbol extraction function 2304 receives reception quadrature baseband signal 2301 as input, extracts an attenuation control symbol, and outputs attenuation control symbol signal 2305.

Transmission path distortion estimation function 2306 receives pilot symbol signal 2303 and attenuation control symbol signal 2305 as inputs, estimates transmission path distortion, and outputs transmission path distortion estimation signal 2307.

FIG. 24 shows an example of the detailed configuration of frequency offset estimating section 2207 in FIG. 22. Pilot symbol extracting function 2402 receives received orthogonal baseband signal 2401, extracts pilot symbols, and outputs pilot symbol signal 2403. Is output.

Attenuation control symbol extraction function 2404 receives reception quadrature baseband signal 2401 as input, extracts an attenuation control symbol, and outputs attenuation control symbol signal 2405.

Frequency offset estimation function 2406 receives pilot symbol signal 2403 and attenuation control symbol signal 2405 as inputs, estimates a frequency offset, and outputs frequency offset estimation signal 2407.

FIG. 25 illustrates an example of a configuration of a reception device in this embodiment. Radio section 2503 receives reception signal 2502 received at antenna 2501, and outputs reception quadrature baseband signal 2504.

Frequency offset estimating section 2505 receives received orthogonal baseband signal 2504 as input, estimates a frequency offset, and outputs frequency offset estimation signal 2506.

Frequency offset removing section 2507 receives received orthogonal baseband signal 2504 and frequency offset estimation signal 2506 as input, removes frequency offset, and outputs received orthogonal baseband signal 2508 after frequency offset removal.

The channel distortion estimator 2509 receives the received orthogonal baseband signal 2508 after frequency offset removal as input, estimates channel distortion, and outputs a channel distortion estimation signal 2510. The channel distortion remover and demodulator The received orthogonal baseband signal 2508 and the transmission path distortion estimation signal 2510 after the offset removal are input, the transmission path distortion is removed, demodulation is performed, and the received digital signal 2512 is output.

FIG. 26 illustrates an example of a configuration of a reception device in this embodiment. Radio section 2603 receives reception signal 2602 received by antenna 2601, and outputs reception quadrature baseband signal 2604.

Transmission path distortion estimating section 2605 receives reception orthogonal baseband signal 2604 as input, estimates transmission path distortion, and outputs transmission path distortion estimation signal 2606.

Transmission path distortion removal section 2607 receives reception orthogonal baseband signal 2604 and transmission path distortion estimation signal 2606 as input, removes transmission path distortion, and outputs reception orthogonal baseband signal 2608 after transmission path distortion removal.

Frequency offset estimating section 2610 receives as input received orthogonal baseband signal 2608 from which transmission line distortion has been removed, estimates a frequency offset, and outputs frequency offset estimation signal 2610.

The frequency offset removing unit and the demodulating unit 2611 receive the received orthogonal baseband signal 2608 and the frequency offset estimation signal 2610 from which the transmission line distortion has been removed, remove the frequency offset, perform demodulation, and output the received digital signal 2612.

Next, the detailed operation of the transmission path distortion estimator 2205 in FIG. 22 will be described with reference to FIGS.

The pilot symbol extraction function 2302 in FIG. 23 receives the received orthogonal baseband signal 2301 as input, extracts pilot symbols 904 and 908 in FIG. 9 and outputs a pilot symbol signal 2303.

Attenuation control symbol extraction function 2304 receives received quadrature baseband signal 2301 as input, extracts attenuation control symbol 909 in FIG. 9, and outputs attenuation control symbol signal 2305.

The channel distortion estimation function 2306 receives the pilot symbol signal 2303 and the attenuation control symbol signal 2305 as inputs, estimates channel distortion from the pilot symbol and the attenuation control symbol, and outputs a channel distortion estimation signal 2307.

By using the attenuation control symbol for estimating the transmission line distortion in this way, the estimation accuracy of the transmission line distortion is improved, and the receiving sensitivity of the receiving apparatus is improved.

Next, the detailed operation of the frequency offset estimator 2207 in FIG. 22 will be described with reference to FIGS.

24. The pilot symbol extraction function 2402 in FIG. 24 receives the received orthogonal baseband signal 2401 as input, extracts pilot symbols 904 and 908 in FIG. 9, and outputs a pilot symbol signal 2403. The attenuation control symbol extraction function 2404 receives the reception quadrature baseband signal 2401 as input, extracts the attenuation control symbol 909 in FIG. 9, and outputs the attenuation control symbol signal 2405.

The frequency offset estimation function 2406 receives the pilot symbol signal 2403 and the attenuation control symbol signal 2405 as inputs, estimates a frequency offset from the pilot symbol and the attenuation control symbol, and outputs a frequency offset estimation signal 2407.

(4) By using the attenuation control symbol for estimating the frequency offset in this way, the estimation accuracy of the frequency offset is improved, and the receiving sensitivity of the receiving apparatus is improved.

The configuration of the receiving apparatus according to the present embodiment is not limited to FIG. 22, for example, FIGS. 25 and 26, and a configuration without any one of the transmission path distortion estimating unit and the frequency offset estimating unit. Is also conceivable. 25 and 26, the transmission line distortion estimating units 2509 and 2605 can similarly estimate the transmission line distortion with the configuration of FIG. Further, the frequency offset estimating units 2506 and 2609 can similarly estimate the frequency offset with the configuration of FIG. Then, the transmission line distortion estimating unit can also remove the frequency offset at the same time.

The frame configuration is not limited to that shown in FIG. 9, but can be similarly applied to FIG. Further, the attenuation control symbol has been described as one symbol, but may be a plurality of symbols. Also, the attenuation control symbol may be regarded as a symbol for demodulation, such as a pilot symbol, a unique word, a preamble, and a control symbol.

In the description of the present embodiment, even when the attenuation control symbol is replaced with a ramp symbol, the same can be implemented. At this time, as described in the second or fifth embodiment, signal points need to be arranged in the lamp symbol.

As described above, according to the present embodiment, by estimating the transmission path distortion and the frequency offset using the attenuation control symbol in the receiving apparatus, the estimation accuracy of the transmission path distortion and the estimation of the frequency offset in the receiving apparatus The accuracy is improved, and the receiving sensitivity is improved.

(4) It has an effect that the strength of the transmission signal can be suppressed to a specified value, and the specification of the adjacent channel leakage power can be more accurately maintained, and is useful for lamp control and the like in a wireless communication system.

FIG. 3 is a diagram illustrating a frame configuration on a time axis according to the first embodiment of the present invention. FIG. 3 is a diagram illustrating a configuration of a transmission device according to the first embodiment. FIG. 3 is a diagram illustrating a configuration of a modulation signal generation unit according to the first embodiment. FIG. 4 is a diagram showing a signal point arrangement on an IQ plane according to the first embodiment. FIG. 4 is a diagram showing a signal point arrangement on an IQ plane according to the first embodiment. The figure which shows the structure of the modulation | alteration signal generation part in the 2nd Embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the second embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the second embodiment. FIG. 13 is a diagram showing a frame configuration on a time axis in the third embodiment. The figure which shows the structure of the modulation signal production | generation part in the 3rd Embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the third embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the third embodiment. The figure which shows the structure of the modulation signal generation part in the 4th Embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the fourth embodiment. FIG. 14 is a diagram showing a signal point arrangement on an IQ plane according to the fourth embodiment. FIG. 14 is a diagram showing a frame configuration on a time axis in the fifth embodiment. The figure which shows the structure of the modulation signal production | generation part in the 5th Embodiment. FIG. 17 is a diagram showing a signal point arrangement on an IQ plane according to the fifth embodiment. FIG. 27 is a diagram illustrating an example of a frame configuration on a time axis according to the sixth embodiment. The figure which shows the structure of the modulation signal generation part in the 6th Embodiment. FIG. 28 is a diagram showing a signal point arrangement on an IQ plane according to the sixth embodiment. The figure which shows the structure of the receiver in the 7th Embodiment. The figure which shows the structure of the transmission-path distortion estimation part in the 7th Embodiment. The figure which shows the structure of the frequency offset compensation part in the same 7th Embodiment. The figure which shows the structure of the receiver in the 7th Embodiment. The figure which shows the structure of the receiver in the 7th Embodiment. Diagram showing the configuration of a conventional lamp control device

Explanation of reference numerals

101, 102, 103, 105, 106, 107, 901, 902, 903
, 905, 906, 907, 1601, 1602, 1603, 1607, 160
8 Data symbols 104, 108, 904, 908, 1604, 1605, 1606 Pilot symbols 109, 110, 111, 112, 910, 911, 912, 1609, 16
10, 1611, 1612 Ramp symbol 113, 114, 913, 914, 1613, 1614 Guard symbol 201, 301, 601, 1001, 1301, 2001, 2701 Transmitted digital signal 202, 2702 Modulated signal generator 203, 2703 Transmitted orthogonal baseband In-phase component of signal 204, 2704 Quadrature component of transmission quadrature baseband signal 205, 206, 2705, 2706 Transmission filter 207, 2707 In-phase component of transmission quadrature baseband signal with band limitation 208, 2708 Transmission quadrature baseband with band restriction Signal quadrature components 209, 210 Signal processing units 211, 2711 In-phase components 212, 2712 of signal-processed transmission quadrature baseband signals Quadrature components 213, 27 of signal-processed transmission quadrature baseband signals 3 Radio section 214, 2714 Transmission signal 215, 2715 Power amplification section 216, 2716 Amplified transmission signal 217, 2717 Antenna 218 Frame configuration signal 302, 602, 1002, 1302, 2002 Data symbol modulation signal generation section 303, 603, 1003 , 1303, 2003 Pilot symbol modulation signal generator 304 Pilot symbol modulation signal generator 305, 605, 1005, 2005 Ramp symbol modulation signal generator 306, 606, 1006, 2006 Guard symbol modulation signal generator 307, 607 , 1007, 1307, 2007 In-phase component of data symbol transmission quadrature baseband signal 308, 608, 1008, 1308, 2008 Quadrature of data symbol transmission quadrature baseband signal 309,609,1009,1309,2009 In-phase component of pilot symbol transmission orthogonal baseband signal 310,610,1010,1310,2010 Orthogonal component of pilot symbol transmission orthogonal baseband signal 311 Pilot symbol transmission orthogonal baseband immediately before ramp symbol In-phase component of signal 312 Quadrature component of pilot symbol transmission quadrature baseband signal immediately before ramp symbol 313, 613, 1013, 2013 In-phase component of ramp symbol transmission quadrature baseband signal 314, 614, 1014, 2014 Ramp symbol transmission quadrature baseband signal 315, 615, 1015, 2015 In-phase components of guard symbol transmission orthogonal baseband signals 316, 616, 1016, 2016 Quadrature component of band signal 317,617,1017,1317,2017 In-phase component switching unit 318,618,1018,1318,2018 Quadrature component switching unit 319,619,1019,1319,2019 In-phase of selected transmission quadrature baseband signal Components 320, 620, 1020, 1320, 2020 Quadrature components 321, 621, 1021, 1321, 2021 of selected transmission quadrature baseband signals Frame constituent signals 401, 501, 701, 801, 1101, 1201, 1401, 1501
16QAM signal points 402, 502, 702, 802, 1102, 1202, 1402, 1502
, 2105, 2106 Signal points of pilot symbols 403, 503 Signal points 404, 504, 704, 804, 1104, 1204, 1405, 1505 of pilot symbols immediately before the ramp symbol
, 2111 Signal points of ramp and guard symbols 604 Ramp symbol modulation signal generation section immediately after pilot symbol 611 In-phase component of quadrature baseband signal for transmission of ramp symbol immediately after pilot symbol 612 Quadrature component of quadrature baseband signal for transmission of lamp symbol immediately after pilot symbol 703, 803 Signal point of ramp symbol immediately after pilot symbol 909 Attenuation control symbol 1004, 1305, 2004 Attenuation control symbol modulation signal generation section 1111, 1313, 2011 In-phase component of transmission quadrature baseband signal 1112, 1314, 2012 Attenuation The orthogonal components of the control symbol transmission orthogonal baseband signal 1103, 1203, 1404, 1504, 2107, 2108, 2109,
2110 Signal point of attenuation control symbol 1304 Pilot symbol modulation signal generation section before attenuation control symbol 1306 Ramp and guard symbol modulation signal generation section 1311 In-phase component of pilot symbol transmission quadrature baseband signal before attenuation control symbol 1312 Before attenuation control symbol Quadrature component of pilot symbol transmission orthogonal baseband signal 1315 In-phase component of ramp and guard symbol transmission orthogonal baseband signal 1316 Quadrature component of ramp and guard symbol transmission orthogonal baseband signal 1403, 1503 Signal point of pilot symbol before attenuation control symbol 2101 , 2102, 2103, 2104 Signal points of QPSK 2201, 2501, 2601 Antennas 2202, 2502, 2602 Received signals 2203, 2503, 260 3 Radio section 2204, 2301, 2401, 2504, 2604 Received quadrature baseband signal 2205, 2509, 2605 Transmission path distortion estimation section 2206, 2307, 2510, 2606 Transmission path distortion estimation signal 2207, 2505, 2609 Frequency offset estimation section 2208, 2407, 2506, 2610 Frequency offset estimation signal 2209 Demodulation unit 2210, 2512, 2612 Received digital signal 2302, 2402 Pilot symbol extraction function 2303, 2403 Pilot symbol signal 2304, 2404 Attenuation control symbol extraction function 2305, 2405 Attenuation control symbol signal 2306 Transmission Path distortion estimating function 2405 Frequency offset estimating function 2507 Frequency offset removing section 2508 Received orthogonal vector after removing frequency offset Baseband signal 2511 Transmission line distortion removal unit and demodulation unit 2607 Transmission line distortion removal unit 2608 Received orthogonal baseband signal 2611 after transmission line distortion removal Frequency offset removal unit and demodulation unit 2709, 2710 Hanning window signal processing unit

Claims (2)

An attenuation control symbol for controlling attenuation is arranged before a symbol for demodulation, and the attenuation is controlled so that the signal point amplitude of the attenuation control symbol is smaller than the signal point amplitude of the symbol for demodulation on the IQ plane. A transmitting apparatus comprising: a signal point arrangement unit that outputs a symbol for demodulation before a control symbol and signal point information of the attenuation control symbol. An attenuation control symbol for controlling attenuation is arranged before a symbol for demodulation, and the attenuation is controlled so that the signal point amplitude of the attenuation control symbol is smaller than the signal point amplitude of the symbol for demodulation on the IQ plane. A wireless communication system for outputting a symbol for demodulation before a control symbol and signal point information of the attenuation control symbol.

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