JPWO2011093514A1 - Wireless communication system, transmitter, and multicarrier communication method - Google Patents

Abstract

As a wireless communication system, a transmitter uses a plurality of quadrature modulations to modulate each analog signal obtained by serial-parallel conversion of an input digital signal sequence and input to a plurality of DA converters into a quadrature modulated RF signal. A mixer and a plurality of RF amplifiers for amplifying a plurality of RF signals orthogonally modulated by a plurality of orthogonal modulation mixers individually corresponding to the subcarrier frequency are provided.

Description

  The present invention relates to a high-speed wireless communication system using a multicarrier with high frequency utilization efficiency such as OFDM (Orthogonal Frequency Domain Modulation), and more particularly to a transmitter using an RF amplifier with high power efficiency.

The OFDM wireless communication system is currently used in a wireless local area network (LAN) and is one of methods for realizing high-speed wireless communication.
A general configuration of a transmitter used in an existing OFDM wireless communication system is described in Non-Patent Document 1, for example. A transmitter used in the OFDM wireless communication system disclosed in Non-Patent Document 1 is shown in FIG.
In the transmitter of FIG. 10, an input digital signal sequence ^t {D} is converted into a parallel complex symbol sequence {S} by a symbol mapper 100 and a serial-parallel converter 101. The parallel complex symbol sequence {S} is subjected to matrix calculation processing by the frequency mapper 102, the inverse discrete Fourier transformer 103, and the parallel-serial converter 104. As a result, a complex OFDM symbol sample value sequence ^t {V} is generated. An appropriate guard interval is added to the complex OFDM symbol sample value sequence ^t {V} by the guard interval circuit 105 and further converted into a complex analog OFDM signal V _BB (t) by the DA converter 106. The complex analog OFDM signal V _BB (t) is converted into a quadrature modulated RF signal V _RF (t) by a quadrature modulator 109 including a quadrature modulation mixer 107 and a local oscillator 108. Thereafter, the RF signal V _RF (t) is amplified to a high output by the RF amplifier 110 and is transmitted from the antenna 111 to the space.
The OFDM wireless communication system having the above configuration generally has excellent characteristics such as high frequency utilization efficiency and resistance to multipath fading by providing an appropriate guard interval.
The configuration of a transmitter used in the OFDM wireless communication system is also described in Patent Document 1. In the configuration described in Patent Document 1, unlike the Non-Patent Document 1, the signal is divided into an in-phase component and a quadrature component, and then combined with an OFDM signal by a quadrature modulator and input to a transmission amplifier (RF amplifier). doing.

Japanese Patent Laid-Open No. 11-289312

Itami Makoto, “Intuitive OFDM Technology”, Ohmsha, November 2005

However, in the OFDM communication system of Patent Document 1 or Non-Patent Document 1, the RF signal V _RF (t) input to the RF amplifier is a multi-carrier modulation signal including a large number of carriers, and the peak power with respect to the average power of the signal. (PAPR: Peak to Average Power Ratio) increases. For this reason, in order to amplify the signal linearly, it is necessary to operate with a sufficiently large back-off to the saturated output power so that the saturated output power of the RF amplifier becomes larger than the peak power of the signal. In other words, it is necessary to use an RF amplifier capable of obtaining a large saturated output and to operate the RF amplifier at a large back-off point. FIG. 11 is an example of output power and power efficiency characteristics of an amplifier in a wireless communication system. As shown in the drawing, the power efficiency of an amplifier is generally maximized when operating at a saturated output power level and significantly decreases when operated with a large backoff from saturation. The increase in power consumption resulting from this result becomes a problem for the wireless communication system. In addition, a high-power amplifier having a large saturation output power is required to construct a wireless communication system. However, in a wireless communication system using extremely short wavelengths such as millimeter waves, it is difficult to realize a high-efficiency and high-power amplifier. There is also. From the above, it is extremely difficult to reduce power consumption while maintaining high frequency utilization efficiency (bit / Hz) like OFDM in a wireless communication system, and there is a problem that power consumption per bit is high.
Even in a multi-carrier communication system that uses a scheme different from the existing OFDM communication system, it is necessary to suppress the spread of spectrum and the influence of mutual distortion components as in the OFDM communication system. It is necessary to take a large. Therefore, the multi-carrier communication system also needs to operate the RF amplifier at a large back-off point. Therefore, there is a problem that the power consumption of the amplifier increases as in the OFDM communication system. As a result, there is a problem that the power consumption per bit in the wireless communication system cannot be reduced.
In a communication system using a multicarrier modulation signal typified by an OFDM communication system, the present invention does not require a large back-off in an RF amplifier used in a transmitter, and as a result, an RF amplifier having a low saturation output power is used. And a radio communication system capable of using the RF amplifier with high power efficiency, and as a result, significantly reducing the power consumption of the transmitter and reducing the power consumption per bit.

  In the wireless communication system according to the present invention, an input digital signal sequence is serial-parallel converted and input to a plurality of DA converters, and each analog signal obtained from the plurality of DA converters is subjected to orthogonal modulation RF. Multi-carrier communication comprising a plurality of quadrature modulation mixers that modulate signals, and a plurality of RF amplifiers that individually amplify a plurality of RF signals that have been quadrature-modulated by the plurality of quadrature modulation mixers in correspondence with subcarrier frequencies Have a transmitter to do.

  According to the present invention, in a communication system using a multicarrier modulation signal, a transmitter, a wireless communication system, and a transmitter that realize high power efficiency while reducing backoff of an RF amplifier used in the transmitter and maintaining high frequency utilization efficiency A multi-carrier communication method can be provided. In order to obtain this effect, a local oscillator having a common frequency or a common local oscillator can be used.

FIG. 1 is a configuration diagram of a transmitter of a wireless communication system according to the first embodiment of the present invention.
FIG. 2 is a configuration diagram of the transmitter of the wireless communication system according to the third embodiment of the present invention.
FIG. 3 is a configuration diagram of the transmitter of the radio communication system according to the fourth embodiment of the present invention.
FIG. 4 is a configuration diagram of a transmitter of a wireless communication system according to the fifth embodiment of the present invention.
FIG. 5 is a configuration diagram of the transmitter of the wireless communication system according to the sixth embodiment of the present invention.
FIG. 6 is an explanatory diagram showing the state of signals when the windowing processing circuit according to the present invention is loaded.
FIG. 7 is a configuration diagram of a transmitter of a wireless communication system according to the seventh embodiment of the present invention.
FIG. 8 is a configuration diagram of the transmitter of the wireless communication system according to the eighth embodiment of the present invention.
FIG. 9 is a configuration diagram of a transmitter of a wireless communication system according to the ninth embodiment of the present invention.
FIG. 10 is a general configuration diagram of a transmitter used in an OFDM wireless communication system.
FIG. 11 is an explanatory diagram illustrating an example of output power and power efficiency characteristics of an amplifier.

ここで、

このとき、（３）および（５）の中で位相項として示されているｆ_ｋ（１＜ｋ＜Ｎ−１）が、この操作で与えられる周波数に対応している。上記Ｎ個の複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）は、それぞれＤＡ変換器５にて複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））に変換される。各複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））は、更に直交変調ミクサ６と局発発振器７とで直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））に変換される。直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））は、ＲＦ増幅器８にてそれぞれ増幅され、アンテナ９から空中に送出される。
以上の動作原理から、各ＲＦ増幅器８で増幅される直交変調された夫々のＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））は、シングルキャリア変調信号となっている。シングルキャリア変調としては、例えばＢＰＳＫ、ＱＰＳＫ、８ＰＳＫ、１６ＱＡＭ、６４ＱＡＭが適用可能である。
これにより、既存のＯＦＤＭなどのマルチキャリアを使用する無線通信システムにおいて問題となったマルチキャリア信号を増幅する必要性がなくなり、増幅器におけるＰＡＰＲが増加する問題が軽減される。
この結果、大きな飽和出力のＲＦ増幅器が不要となり、また、ＰＡＰＲの増加に伴うＲＦ増幅器の効率低下の問題を回避できる。すなわち、小さな出力電力のＲＦ増幅器を使用することが可能となり、かつ、そのＲＦ増幅器を高い電力効率で使用でき、その結果 周波数利用効率を維持しつつ送信機の消費電力を低減でき、高い周波数利用効率（ｂｉｔ／Ｈｚ）を維持しながら、消費電力を下げ、１ｂｉｔあたりの消費電力を下げられる利点がある。
（第２の実施の形態）
第２の実施の形態の無線通信システムは、図１の構成において、各並列複素シンボルのそれぞれに割り当てる個別の周波数を、シンボル周期Ｔの逆数で定義される基本周波数ｆ_０（＝１／Ｔ）の整数倍でなる周波数ｆ_ｋ＝ｋｆ_０（ｋは整数）としている点で第１の実施形態と異なっている。
この場合、行列（Ｆ^−１）は逆離散フーリエ変換行列（ＩＤＦＴ）になり、行列（Ｆ）は離散フーリエ変換行列（ＤＦＴ）になる。その結果、式（１）〜（５）は以下のように変更して表せる。

ここで、

ここで、生成されたＮ個の複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）を標本時間ごとに加算すると既存のＯＦＤＭ変調信号と同一の信号となる。このことから、本発明により生成したＲＦ信号は、周波数利用効率が良く、マルチパスフェージングに強いなどの既存のＯＦＤＭ変調信号の優れた特長を有する。
一方、本発明では、複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）のそれぞれから直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））を生成し、各ＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））をそれぞれ個別に増幅することができ、既存のＯＦＤＭ変調信号で問題となった大きなＰＡＰＲの問題が軽減される。その結果、ＲＦ増幅器に大きなバックオフを持たせる必要がなく、実現が容易な低出力な増幅器を用いることができ、また、高い電力効率で動作させることができ、高い周波数利用効率（ｂｉｔ／Ｈｚ）を維持しながら、消費電力を下げ、１ｂｉｔあたりの消費電力を下げられる利点がある。
以上のように、第２の実施形態に係る無線通信システムでは、既存のＯＦＤＭ変調信号を用いた無線通信システムの優れた特長を有しながら、単一増幅器を用いる欠点である大きなＰＡＰＲによる送信機の効率低下の問題を回避できる。
（第３の実施の形態）
図２は、本発明の第３の実施の形態における無線通信システムの送信機の構成図である。
図１の構成と異なる点は、Ｎ個の直交変調ミクサ６に局発信号を供給する局発発振器を共通の局発信号を生成する単一の共通局発発振器１０で構成していることである。
次に、動作について説明する。本実施の形態の無線通信システムの送信機では並列複素シンボル（Ｓ）に含まれる各複素シンボル（ｓ_０〜ｓ_Ｎ−１）のそれぞれに対して周波数マッパ３によって個別の周波数（ｆ_０，ｆ_１，・・・，ｆ_ｋ，・・・，ｆ_Ｎ−１）が割り当てられ、さらに、デジタル信号処理回路４により各割り当てられた周波数に対応した位相回転を与えた複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）を生成している。
このため、図２の各直交変調ミクサ６に供給する局発信号は、同一の周波数でよい。その結果、一つの共通局発発振器１０を用いることが可能となる。局発発振器が１つでよいので小型化が可能であり、かつ、各直交変調ミクサ６に供給する局発信号間の周波数偏差を考慮する必要がないため構成が簡単になる利点がある。
（第４の実施の形態）
図３は、本発明の第４の実施の形態における無線通信システムの構成図である。図１および図２の構成と比較すると、各ＲＦ増幅器８で個別に増幅されたＲＦ信号を合成するための複数の電力合成器１１、および各電力合成器１１に対応して合成したＲＦ信号を空中に送出する複数のアンテナ１２を備えた点が異なる。
次に、動作について説明する。各ＲＦ増幅器８で個別に増幅された複数のＲＦ信号を電力合成器１１にて合成した後にアンテナ１２から空中に送出することにより、使用するアンテナの削減が可能となる。図３に示した構成は、複数の電力合波器を用いる場合の例を示しているが、各ＲＦ増幅器８で個別に増幅されたＲＦ信号の全てを１つの電力合成器で合成し、１つのアンテナから空中に送出するものであってもよい。換言すれば、電力合成器１１の個数ｎは、ＲＦ増幅器８の個数となる入力系統数＞ｎ≧１である。
以上のように、第４の実施形態に係る無線通信システムでは、既存のＯＦＤＭ変調信号を用いた無線通信システムの優れた特長を有しながら、単一増幅器を用いる欠点である大きなＰＡＰＲによる送信機の効率低下の問題を回避でき、且つ、アンテナの個数を所望の個数まで削減できる。
（第５の実施の形態）
図４は、本発明の第５の実施の形態における無線通信システムの構成図である。図１ないし図３と比較すると、図４における無線通信システムの送信機では、デジタル信号処理回路４及び複数のＤＡ変換器５の間にガードインターバル回路１３を装荷する点が異なる。
次に、動作について説明する。ガードインターバル回路１３を装荷することにより、デジタル信号処理回路４にて生成した複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）のそれぞれに、適切なガードインターバル（ＧＩ）が付加される。付加したＧＩにより、マルチパス干渉波の影響を低減することが可能となる。
（第６の実施の形態）
図５は、本発明の第６の実施の形態における無線通信システムの構成図である。図４と比較すると、ガードインターバル回路１３と複数のＤＡ変換器５との間に、ウインドウイング処理回路１４を装荷する点が異なる。図６はウインドウイング処理回路１４を装荷した場合の信号の様子を示す図である。
図４に示すように、ガードインターバル回路（ＧＩ）１３を付加した場合、図６に示すように、連続する信号間（図ではＡ点）に不連続が生じる。このような不連続が生じるとスプリアス成分が発生することになる。これに対し、図６に示すように、ウインドウイング処理回路１４を設け、ランプ状（傾斜状）のウインドウイング処理を行うと不連続部分の振幅が小さくなり、滑らかになる。これにより、信号のスプリアス成分の抑制やピーク電力の削減等が可能となる。
（第７の実施の形態）
図７は、本発明の第７の実施の形態における無線通信システムの送信機の構成図である。
図示された送信機は、入力デジタル信号列^ｔ｛Ｄ｝を複素シンボル列に変換するシンボルマッパ１と、生成された複素シンボル列を並列複素シンボル（Ｓ）へと変換する直並列変換器２と、並列複素シンボル（Ｓ）に含まれる各複素シンボル（ｓ_０〜ｓ_Ｎ−１）のそれぞれに対して個別の周波数を割り当てる周波数マッパ３と、割り当てられた周波数に対応した位相回転を与えたそれぞれの複素デジタル信号標本列を生成するデジタル信号処理回路４と、各複素デジタル信号標本列の帯域を制限するフィルタ１５と、生成した複素デジタル信号標本列のそれぞれを複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））へと変換するＤＡ変換器５と、各複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））のそれぞれから直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））を生成する複数の直交変調ミクサ６と、各直交変調ミクサに局発信号を供給する複数の局発発振器７と、各直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））をそれぞれ増幅する複数のＲＦ増幅器８と、増幅されたそれぞれのＲＦ信号を空中に送出するアンテナ９とから構成されている。即ち、フィルタ１５を設けた点で、第７の実施の形態に係る送信機は、第１の実施の形態に係る送信機とは異なっている。
次に、動作について説明する。
入力デジタル信号列^ｔ｛Ｄ｝は、シンボルマッパ１および直並列変換器２により、Ｎ個の複素シンボル（ｓ_０〜ｓ_Ｎ−１）に変換される。次に、周波数マッパ３により各複素シンボル（ｓ_０〜ｓ_Ｎ−１）に個別の周波数（ｆ_０，ｆ_１，・・・，ｆ_ｋ，・・・，ｆ_Ｎ−１）が割り当てられ、さらに、デジタル信号処理回路４により、各割り当てられた周波数に対応した位相回転を与えて複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）を生成する。このとき各複素シンボルがそれぞれ別の周波数領域に展開され、かつ個別に復調可能であるシングルキャリア信号が生成できるように位相回転がそれぞれに与えられ、その結果Ｎ個の複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）が生成される。さらに各複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）は、フィルタ１５により帯域が制限される。このときにフィルタ１５として、例えばロールオフフィルタが用いられる。さらに、フィルタリングされた各複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）はそれぞれＤＡ変換器５にて複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））に変換される。複素アナログ信号（Ｖ_ＢＢ．０（ｔ）〜Ｖ_{ＢＢ．Ｎ−１}（ｔ））は、さらに直交変調ミクサ６と局発発振器７とで直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））に変換される。直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））はさらにＲＦ増幅器８にてそれぞれ増幅され、アンテナ９から空中に送出される。
以上の動作原理から、各ＲＦ増幅器８で増幅される直交変調されたＲＦ信号（Ｖ_ＲＦ．０（ｔ）〜Ｖ_{ＲＦ．Ｎ−１}（ｔ））は、シングルキャリア変調信号となっている。シングルキャリア変調としては、例えばＢＰＳＫ、ＱＰＳＫ、８ＰＳＫ、１６ＱＡＭ、６４ＱＡＭが適用可能である。
これにより、既存のＯＦＤＭなどのマルチキャリアを使用する通信システムにおいて問題となったマルチキャリア信号を増幅する必要性がなくなり、増幅器におけるＰＡＰＲが増加する問題が軽減される。この結果、大きな飽和出力のＲＦ増幅器が不要となり、また、ＰＡＰＲの増加に伴うＲＦ増幅器の効率低下の問題を回避できる。すなわち、小さな出力電力のＲＦ増幅器を使用することが可能となり、かつ、そのＲＦ増幅器を高い電力効率で使用でき、その結果送信機の消費電力を低減できる利点がある。
また、フィルタをサブキャリアごとに使うことによって、各サブキャリアのサイドローブが低減されるため、サブキャリア間隔を狭くしても、サブキャリアをそれぞれシングルキャリア信号として扱うことができる。
（第８の実施の形態）
図８は、本発明の第８の実施の形態における無線通信システムの送信機の構成図である。図７の構成と異なる点は、Ｎ個の直交変調ミクサ６に局発信号を供給する局発発振器を単一の共通局発発振器１０で構成していることである。
次に、動作について説明する。本発明の無線通信システムの送信機では各並列複素シンボルｓ_ｋのそれぞれに対して個別の周波数（ｆ_０，ｆ_１，・・・，ｆ_ｋ，・・・，ｆ_Ｎ−１）が割り当てられている。
さらに、デジタル信号処理回路４により、各複素シンボルがそれぞれ固別の周波数領域に展開され、かつ個別に復調可能なシングルキャリア信号が生成可能なように位相回転が与えられ、その結果、Ｎ個の複素デジタル信号標本列（^ｔ｛ｖ_０｝〜^ｔ｛ｖ_Ｎ−１｝）が生成される。このため、図８の各直交変調ミクサ６に供給する局発信号は同一の周波数でよい。その結果、一つの共通局発発振器１０を用いることが可能となる。局発発振器が１つでよいので小型化が可能であり、かつ、各直交変調ミクサ６に供給する局発信号間の周波数偏差を考慮する必要がないため構成が簡単になる利点がある。
（第９の実施の形態）
図９に示された第９の実施の形態に係る送信機は、複数の複素デジタル信号標本列^ｔ｛ｖ_ｋ｝を生成する機能を有する信号処理回路４’に、いずれか一つの複素デジタル信号標本列^ｔ｛ｖ_ｋ｝を選択する制御部を設けている点で、図２に示された送信機と異なっている。
例えば、信号処理回路４’内に、ＯＦＤＭとＯＦＤＭではないマルチキャリア通信システムに対応した複素デジタル信号標本列を出力できる機能を予め回路内に用意する。これにより、制御信号を用いて状況に応じた使い分けが可能になり、１つの無線機が２つの方式をサポートすることが実現できる。
以上説明したように、本発明における無線通信システムの送信機では、Ｎ個の複素シンボルのそれぞれに対して個別の周波数を割り当て、さらに直交変調し、各直交変調したＲＦ信号をそれぞれ個別に増幅する構成としている。
上記構成とすることにより、多数のサブキャリア信号を含むマルチキャリア信号を１つの増幅器で増幅をする必要がなくなり、増幅器におけるＰＡＰＲが増加する問題が軽減される。この結果、大きな飽和出力のＲＦ増幅器が不要となり、また、ＰＡＰＲの増加に伴うＲＦ増幅器の効率低下の問題を回避できる。すなわち、小さな出力電力のＲＦ増幅器を使用することが可能となり、かつ、そのＲＦ増幅器を高い電力効率で使用でき、その結果 周波数利用効率を維持しつつ送信機の消費電力を著しく低減できる。
尚 以上に述べた発明の実施の形態においては、ＯＦＤＭ通信システムにおける信号処理回路４、信号処理回路４’と、実施の形態７や８で示したマルチキャリア通信システムにおけるフィルタ１５は、デジタル回路で構成することができ、回路の有無や順序の変更が可能である。他方、ＲＦ増幅器は、直交変調器よりも後段に設けることが望ましい。
また、本発明の具体的な構成は前述の実施の形態に限られるものではなく、この発明の要旨を逸脱しない範囲の変更があってもこの発明に含まれる。
この出願は、２０１０年１月２９日に出願された日本出願特願２０１０−０１７６３６号を基礎とする優先権を主張し、その開示の全てをここに取り込む。Embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a configuration diagram of a transmitter of a wireless communication system according to the first embodiment of the present invention.
The illustrated transmitter includes a symbol mapper 1 that converts an input digital signal sequence ^t {D} into a complex symbol sequence, and a serial-parallel converter 2 that converts the generated complex symbol sequence into parallel complex symbols (S). The frequency mapper 3 for assigning individual frequencies to each of the complex symbols (s _{0 to} s _N-1 ) included in the parallel complex symbol (S), and the phase rotation corresponding to the assigned frequency, respectively. the complex digital signal sampled sequence _{^{(t {v 0} ~ t}} {v N-1}) digital signal processing circuit 4 for generating the generated complex digital signal samples train _{^{(t {v 0} ~ t}} {v N- ₁ }) to a complex analog signal (V _BB.0 (t) to V _BB.N-1 (t)), and a plurality of DA converters 5 and each complex analog signal (V _BB.0 ( t) to VBB _{. N-1} (t)), a plurality of quadrature modulation mixers 6 for generating RF signals (V _RF.0 (t) to V _RF.N-1 (t)) in which the real part is quadrature modulated, A plurality of local oscillators 7 for supplying a local oscillation signal to the quadrature modulation mixer, and a plurality of _amplifying respective quadrature modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) An RF amplifier 8 and a plurality of antennas 9 for transmitting each amplified RF signal to the air.
Here, the digital signal processing circuit 4 operates as signal processing means. The DA converter 5 operates as DA conversion means. A set of the quadrature modulation mixer 6 and the local oscillator 7 operates as a set of quadrature modulation means or circuit. The RF amplifier 8 operates as RF amplification means or a circuit.
Next, the operation will be described.
The input digital signal sequence ^t {D} is converted into a parallel complex symbol (s) including _N complex symbols (s _{0 to} s _N-1 ) by the symbol mapper 1 and the serial-parallel converter 2. Next, an individual frequency (f ₀ , f ₁ ,..., F _k ,..., F _N−1 ) is assigned to each complex symbol (s _{0 to} s _N−1 ) by the frequency mapper 3, Further, the digital signal processing circuit 4 generates a complex digital signal sample sequence ^t (v) to which a phase rotation corresponding to each assigned frequency is given. The above is expressed by an equation:

here,

At this time, f _k (1 <k <N−1) shown as the phase term in (3) and (5) corresponds to the frequency given by this operation. The N complex digital signal sample sequences ( ^t {v ₀ } to ^t {v _N−1 }) are respectively converted into complex analog signals (V _BB.0 (t) to V _{BB.N− by the} DA converter 5. ₁ (t)). Each of the complex analog signals (V _BB.0 (t) to V _BB.N-1 (t)) is further subjected to quadrature modulation by the quadrature modulation mixer 6 and the local oscillator 7 (V _RF.0 (t ) To V _RF.N-1 (t)). The quadrature-modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) are respectively amplified by the RF amplifier 8 and transmitted from the antenna 9 to the air.
From the above operation principle, each of the quadrature-modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) amplified by each RF amplifier 8 becomes a single carrier modulation signal. Yes. As single carrier modulation, for example, BPSK, QPSK, 8PSK, 16QAM, and 64QAM are applicable.
This eliminates the need to amplify a multicarrier signal that has become a problem in a wireless communication system that uses existing multicarriers such as OFDM, and reduces the problem of increased PAPR in the amplifier.
As a result, an RF amplifier with a large saturation output is not necessary, and the problem of a decrease in efficiency of the RF amplifier due to an increase in PAPR can be avoided. In other words, it is possible to use an RF amplifier with a small output power, and the RF amplifier can be used with high power efficiency. As a result, the power consumption of the transmitter can be reduced while maintaining frequency use efficiency, and high frequency use can be achieved. There is an advantage that the power consumption per bit can be reduced while maintaining the efficiency (bit / Hz).
(Second Embodiment)
In the wireless communication system according to the second embodiment, in the configuration of FIG. 1, the fundamental frequency f ₀ (= 1 / T) defined by the reciprocal number of the symbol period T is assigned to each individual frequency of each parallel complex symbol. This is different from the first embodiment in that the frequency f _k = kf ₀ (k is an integer) that is an integer multiple of.
In this case, the matrix (F ⁻¹ ) is an inverse discrete Fourier transform matrix (IDFT), and the matrix (F) is a discrete Fourier transform matrix (DFT). As a result, the expressions (1) to (5) can be expressed by changing as follows.

here,

Here, the added generated N complex digital signal samples string ^{_{(t {v 0} ~ t}} {v N-1}) for each sample time as an existing OFDM modulated signal identical to the signal. For this reason, the RF signal generated by the present invention has excellent features of existing OFDM modulation signals such as high frequency utilization efficiency and resistance to multipath fading.
On the other hand, in the present invention, RF signals (V _RF.0 (t) to V _RF.N-1 ) that are orthogonally modulated from each of the complex digital signal sample sequences ( ^t {v ₀ } to ^t {v _N−1 }). (T)) can be generated and each RF signal (V _RF.0 (t) to V _RF.N-1 (t)) can be individually amplified, which is a problem with existing OFDM modulated signals. The problem of large PAPR is reduced. As a result, it is not necessary to give the RF amplifier a large back-off, and a low-power amplifier that can be easily realized can be used, and can be operated with high power efficiency, and high frequency utilization efficiency (bit / Hz). ), While reducing power consumption, there is an advantage that power consumption per bit can be reduced.
As described above, in the wireless communication system according to the second embodiment, a transmitter using a large PAPR, which is a drawback of using a single amplifier, while having the excellent features of a wireless communication system using an existing OFDM modulated signal. It is possible to avoid the problem of efficiency reduction.
(Third embodiment)
FIG. 2 is a configuration diagram of the transmitter of the wireless communication system according to the third embodiment of the present invention.
The difference from the configuration of FIG. 1 is that a local oscillator that supplies local oscillation signals to N orthogonal modulation mixers 6 is configured by a single common local oscillator 10 that generates a common local oscillation signal. is there.
Next, the operation will be described. In the transmitter of the wireless communication system according to the present embodiment, each frequency (f ₀ , f) is generated by the frequency mapper 3 for each of the complex symbols (s _{0 to} s _N-1 ) included in the parallel complex symbols (S). ₁ ,..., F _k ,..., F _N−1 ), and further, a complex digital signal sample sequence ( ^t) given a phase rotation corresponding to each assigned frequency by the digital signal processing circuit 4 {V ₀ } to ^t {v _N−1 }).
For this reason, the local signal supplied to each quadrature modulation mixer 6 in FIG. 2 may have the same frequency. As a result, one common local oscillator 10 can be used. Since only one local oscillator is required, the size can be reduced, and there is an advantage that the configuration can be simplified because it is not necessary to consider the frequency deviation between the local signals supplied to each quadrature modulation mixer 6.
(Fourth embodiment)
FIG. 3 is a configuration diagram of a radio communication system according to the fourth embodiment of the present invention. Compared with the configuration of FIG. 1 and FIG. 2, a plurality of power combiners 11 for combining the RF signals individually amplified by each RF amplifier 8, and the RF signals combined corresponding to each power combiner 11 are combined. The difference is that a plurality of antennas 12 to be sent out into the air are provided.
Next, the operation will be described. A plurality of RF signals individually amplified by each RF amplifier 8 are combined by the power combiner 11 and then transmitted from the antenna 12 to the air, so that the number of antennas to be used can be reduced. The configuration shown in FIG. 3 shows an example in which a plurality of power combiners are used, but all the RF signals individually amplified by each RF amplifier 8 are combined by one power combiner. One antenna may be sent into the air. In other words, the number n of the power combiners 11 is the number of input systems that is the number of RF amplifiers 8> n ≧ 1.
As described above, in the radio communication system according to the fourth embodiment, a transmitter using a large PAPR which is a drawback of using a single amplifier while having the excellent features of the radio communication system using the existing OFDM modulated signal. The problem of efficiency reduction can be avoided, and the number of antennas can be reduced to a desired number.
(Fifth embodiment)
FIG. 4 is a configuration diagram of a radio communication system according to the fifth embodiment of the present invention. Compared with FIGS. 1 to 3, the transmitter of the wireless communication system in FIG. 4 is different in that a guard interval circuit 13 is loaded between the digital signal processing circuit 4 and the plurality of DA converters 5.
Next, the operation will be described. By loading the guard interval circuit 13, the respective digital signal processing complex digital signal samples string generated by circuit ^{_{4 (t {v 0} ~}} t {v N-1}), appropriate guard interval (GI) Is added. The added GI can reduce the influence of multipath interference waves.
(Sixth embodiment)
FIG. 5 is a configuration diagram of a radio communication system according to the sixth embodiment of the present invention. Compared to FIG. 4, the windowing processing circuit 14 is loaded between the guard interval circuit 13 and the plurality of DA converters 5. FIG. 6 is a diagram showing the state of signals when the windowing processing circuit 14 is loaded.
As shown in FIG. 4, when the guard interval circuit (GI) 13 is added, as shown in FIG. 6, discontinuity occurs between successive signals (point A in the figure). When such a discontinuity occurs, spurious components are generated. On the other hand, as shown in FIG. 6, when the windowing processing circuit 14 is provided and the ramp-like (inclined) windowing process is performed, the amplitude of the discontinuous portion becomes small and smooth. This makes it possible to suppress spurious components of the signal, reduce peak power, and the like.
(Seventh embodiment)
FIG. 7 is a configuration diagram of a transmitter of a wireless communication system according to the seventh embodiment of the present invention.
The illustrated transmitter includes a symbol mapper 1 that converts an input digital signal sequence ^t {D} into a complex symbol sequence, and a serial-parallel converter 2 that converts the generated complex symbol sequence into parallel complex symbols (S). The frequency mapper 3 for assigning individual frequencies to each of the complex symbols (s _{0 to} s _N-1 ) included in the parallel complex symbol (S), and the phase rotation corresponding to the assigned frequency, respectively. Digital signal processing circuit 4 for generating a complex digital signal sample sequence, a filter 15 for limiting the band of each complex digital signal sample sequence, and a complex analog signal (V _BB.0 ( t) to V _BB.N-1 (t)) and the DA converter 5 and each of the complex analog signals (V _BB.0 (t) to V _BB.N-1 (t)) A plurality of quadrature modulation mixers 6 for generating quadrature modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) from each of them, and a local oscillation signal is supplied to each quadrature modulation mixer A plurality of local oscillators 7, a plurality of RF amplifiers 8 for amplifying each of the quadrature modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)), The antenna 9 is configured to transmit an RF signal into the air. That is, the transmitter according to the seventh embodiment is different from the transmitter according to the first embodiment in that the filter 15 is provided.
Next, the operation will be described.
The input digital signal sequence ^t {D} is converted into N complex symbols (s _{0 to} s _N-1 ) by the symbol mapper 1 and the serial / parallel converter 2. Next, an individual frequency (f ₀ , f ₁ ,..., F _k ,..., F _N−1 ) is assigned to each complex symbol (s _{0 to} s _N−1 ) by the frequency mapper 3, Furthermore, the digital signal processing circuit 4, generates a complex digital signal sampled sequence by giving a phase rotation corresponding to the frequency of each assigned ^{_{(t {v 0} ~ t}} {v N-1}). At this time, each complex symbol is expanded to a different frequency domain, and phase rotation is given to each so that a single carrier signal that can be individually demodulated can be generated. As a result, N complex digital signal sample sequences ( ^t {V ₀ } to ^t {v _N−1 }) are generated. Further, the band of each complex digital signal sample sequence ( ^t {v ₀ } to ^t {v _N−1 }) is limited by the filter 15. At this time, for example, a roll-off filter is used as the filter 15. Further, each complex digital signal samples string filtered ^{_{(t {v 0} ~ t}} {v N-1}) complex analog signal at a DA converter 5, respectively _(V BB.0 _{(t) ~V BB.N -1} (t)). The complex analog signals (V _BB.0 (t) to V _BB.N-1 (t)) are further subjected to quadrature modulation by the quadrature modulation mixer 6 and the local oscillator 7 (V _RF.0 (t)). To V _RF.N-1 (t)). The quadrature-modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) are further amplified by the RF amplifier 8 and transmitted from the antenna 9 to the air.
From the above operation principle, the quadrature-modulated RF signals (V _RF.0 (t) to V _RF.N-1 (t)) amplified by the RF amplifiers 8 are single carrier modulation signals. As single carrier modulation, for example, BPSK, QPSK, 8PSK, 16QAM, and 64QAM are applicable.
As a result, there is no need to amplify a multicarrier signal that has become a problem in a communication system using a multicarrier such as an existing OFDM, and the problem of an increase in PAPR in the amplifier is reduced. As a result, an RF amplifier with a large saturation output is not necessary, and the problem of a decrease in efficiency of the RF amplifier due to an increase in PAPR can be avoided. That is, it is possible to use an RF amplifier having a small output power, and there is an advantage that the RF amplifier can be used with high power efficiency, and as a result, the power consumption of the transmitter can be reduced.
Further, since the side lobe of each subcarrier is reduced by using a filter for each subcarrier, each subcarrier can be treated as a single carrier signal even if the subcarrier interval is narrowed.
(Eighth embodiment)
FIG. 8 is a configuration diagram of the transmitter of the wireless communication system according to the eighth embodiment of the present invention. The difference from the configuration of FIG. 7 is that a local oscillator that supplies local signals to N orthogonal modulation mixers 6 is configured by a single common local oscillator 10.
Next, the operation will be described. In the transmitter of the wireless communication system of the present invention, individual frequencies (f ₀ , f ₁ ,..., F _k ,..., F _N−1 ) are assigned to each parallel complex symbol s _k. ing.
Further, the digital signal processing circuit 4 provides phase rotation so that each complex symbol is developed in a separate frequency domain and can be individually demodulated, and as a result, N pieces of signals are generated. complex digital signal samples train ^{_{(t {v 0} ~ t}} {v N-1}) is generated. For this reason, the local signal supplied to each quadrature modulation mixer 6 in FIG. 8 may have the same frequency. As a result, one common local oscillator 10 can be used. Since only one local oscillator is required, the size can be reduced, and there is an advantage that the configuration can be simplified because it is not necessary to consider the frequency deviation between the local signals supplied to each quadrature modulation mixer 6.
(Ninth embodiment)
The transmitter according to the ninth embodiment shown in FIG. 9 includes any one of the complex digital signals in the signal processing circuit 4 ′ having a function of generating a plurality of complex digital signal sample sequences ^t {v _k }. It differs from the transmitter shown in FIG. 2 in that a control unit for selecting the sample sequence ^t {v _k } is provided.
For example, a function capable of outputting a complex digital signal sample sequence corresponding to a multi-carrier communication system other than OFDM and OFDM is prepared in the circuit in advance in the signal processing circuit 4 ′. As a result, it is possible to selectively use the control signal according to the situation, and it is possible to realize that one wireless device supports two systems.
As described above, in the transmitter of the wireless communication system according to the present invention, a separate frequency is assigned to each of N complex symbols, further orthogonally modulated, and each orthogonally modulated RF signal is individually amplified. It is configured.
With the above configuration, it is not necessary to amplify a multicarrier signal including a large number of subcarrier signals with one amplifier, and the problem of an increase in PAPR in the amplifier is reduced. As a result, an RF amplifier with a large saturation output is not necessary, and the problem of a decrease in efficiency of the RF amplifier due to an increase in PAPR can be avoided. That is, it is possible to use an RF amplifier with a small output power, and the RF amplifier can be used with high power efficiency. As a result, the power consumption of the transmitter can be significantly reduced while maintaining the frequency utilization efficiency.
In the embodiment of the invention described above, the signal processing circuit 4 and the signal processing circuit 4 ′ in the OFDM communication system and the filter 15 in the multicarrier communication system shown in the seventh and eighth embodiments are digital circuits. It can be configured, and the presence / absence of the circuit and the order can be changed. On the other hand, it is desirable that the RF amplifier is provided at a stage subsequent to the quadrature modulator.
In addition, the specific configuration of the present invention is not limited to the above-described embodiment, and changes within a range not departing from the gist of the present invention are included in the present invention.
This application claims the priority on the basis of Japanese application Japanese Patent Application No. 2010-017636 for which it applied on January 29, 2010, and takes in those the indications of all here.

1 Symbol mapper (symbol mapping means)
2 Series-parallel converter (series-parallel conversion means)
3 Frequency mapper (frequency mapping means)
4,4 'signal processing circuit (signal processing means)
5 DA converter (DA conversion means)
6 Quadrature modulation mixer (part of quadrature modulation means)
7 Local oscillator (part of quadrature modulation means)
8 RF amplifier (RF amplification means)
9,12 Antenna 10 Common local oscillator (common local oscillator)
11 Power combiner (Power combiner)
13 Guard interval circuit (guard interval generating means)
14 Window processing circuit (window processing means)
15 Filter (filter means)
DESCRIPTION OF SYMBOLS 100 Symbol mapper 101 Serial / parallel converter 102 Frequency mapper 103 Inverse discrete Fourier transformer 104 Parallel / serial converter 105 Guard interval circuit 106 DA converter 107 Orthogonal modulation mixer 108 Local oscillator 109 RF amplifier 111 Antenna

Claims (22)

A plurality of quadrature modulation mixers that perform serial-parallel conversion on the input digital signal sequence and input the signals to a plurality of DA converters, and modulate the respective analog signals obtained from the plurality of DA converters into RF signals that are orthogonally modulated. When,
A wireless communication comprising: a transmitter for performing multicarrier communication, comprising: a plurality of RF amplifiers that individually amplify a plurality of RF signals orthogonally modulated by the orthogonal modulation mixer in correspondence with subcarrier frequencies. system. The wireless communication system according to claim 1, wherein
A frequency f _k = kf that is an integer multiple of the fundamental frequency f ₀ (= 1 / T) defined by the reciprocal of the symbol period T is assigned to each individual parallel complex symbol obtained by serial-parallel conversion. A radio communication system comprising a signal processing circuit for setting ₀ (k is an integer). The wireless communication system according to claim 2,
Using the plurality of orthogonal modulation mixers, each analog signal obtained from a complex digital signal sample sequence obtained by rotating the phase of parallel complex symbols to be orthogonal to each other is modulated to each RF signal using a common local oscillation signal. A wireless communication system. The wireless communication system according to claim 2 or 3,
A wireless communication system comprising at least one power combiner for combining a part or all of the RF signals amplified by each RF amplifier. The wireless communication system according to any one of claims 2 to 4,
A radio communication system comprising a guard interval circuit for providing a guard interval for each complex digital signal sample sequence between the signal processing circuit and the plurality of DA converters. The wireless communication system according to claim 5, wherein
A wireless communication system, comprising: a windowing processing circuit that performs a windowing process on each of the complex digital signal sample sequences between the guard interval circuit and the plurality of DA converters. The wireless communication system according to any one of claims 1 to 6,
A radio communication system comprising a filter for limiting a band after serially parallel converting an input digital signal sequence and before inputting the digital signal sequence to the plurality of DA converters. The wireless communication system according to any one of claims 2 to 7,
The signal processing circuit includes:
It can generate multiple types of complex digital signal sample sequences corresponding to multiple different methods,
A wireless communication system, wherein a complex digital signal sample sequence selected from the plurality of types of complex digital signal sample sequences is generated based on an input control signal. A symbol mapper that converts an input digital signal sequence into a complex symbol sequence;
A serial-to-parallel converter that converts the generated sequence of complex symbols into N parallel complex symbols (where N is a positive integer);
A frequency mapper for assigning N individual frequencies to each of the N parallel complex symbols;
A digital signal processing circuit that applies phase rotation to each of the N parallel complex symbols to which the frequency is assigned in accordance with the assigned frequency to generate N complex digital signal sample sequences;
N DA converters for converting each of the N complex digital signal sample sequences generated and given a phase rotation into complex analog signals;
M quadrature modulation mixers (where M is a positive integer) that generates M quadrature modulated RF signals from each complex analog signal;
A local oscillator for supplying a local signal to be supplied to the M orthogonal modulation mixers;
M RF amplifiers that individually amplify each of the M RF signals that are orthogonally modulated;
A wireless communication system comprising a transmitter configured to include an antenna for transmitting each amplified RF signal into the air. A plurality of quadrature modulation mixers that modulate the respective analog signals obtained by serial-parallel conversion of the input digital signal sequence and input to a plurality of DA converters into quadrature-modulated RF signals;
A transmitter that performs multi-carrier communication including a plurality of RF amplifiers that individually amplify a plurality of RF signals that are orthogonally modulated by the plurality of orthogonal modulation mixers in correspondence with subcarrier frequencies. The transmitter of claim 10, wherein
A frequency f _k = kf that is an integer multiple of the fundamental frequency f ₀ (= 1 / T) defined by the reciprocal of the symbol period T is assigned to each individual parallel complex symbol obtained by serial-parallel conversion. A transmitter having a signal processing circuit for setting ₀ (k is an integer). The transmitter of claim 11, wherein
A transmitter comprising: a common local oscillator that generates a common local signal used in the plurality of orthogonal modulation mixers. The transmitter according to claim 11 or 12,
A transmitter comprising at least one power combiner that combines a part or all of the RF signals amplified by each RF amplifier. The transmitter according to any one of claims 11 to 13,
A transmitter comprising: a guard interval generation circuit that provides a guard interval for each of the complex digital signal sample sequences between the signal processing circuit and the plurality of DA converters. The transmitter of claim 14, wherein
A transmitter comprising: a windowing processing circuit that performs a windowing process on each of the complex digital signal sample sequences between the guard interval generation circuit and the plurality of DA converters. The transmitter according to any one of claims 10 to 15,
A transmitter comprising: a filter for limiting a band after serially parallel converting an input digital signal sequence and before inputting to the plurality of DA converters. The transmitter according to any one of claims 11 to 16,
The signal processing circuit includes:
It can generate multiple types of complex digital signal sample sequences corresponding to multiple different methods,
A transmitter which generates a complex digital signal sample sequence selected from the plurality of types of complex digital signal sample sequences based on an input control signal. Each analog signal obtained by performing symbol conversion, serial parallel conversion, and analog conversion on an input digital signal sequence is modulated into a plurality of orthogonally modulated RF signals using a plurality of orthogonal modulation mixers,
Amplifying each of the plurality of RF signals individually using a plurality of independent RF amplifiers, corresponding to the frequency of the subcarrier,
A multicarrier communication method, wherein each independently amplified RF signal is transmitted to the air using an antenna. The multi-carrier communication method according to claim 18.
A frequency f _k = kf that is an integer multiple of the fundamental frequency f ₀ (= 1 / T) defined by the reciprocal of the symbol period T is assigned to each individual parallel complex symbol obtained by serial-parallel conversion. A multicarrier communication method characterized in that ₀ (k is an integer). The multicarrier communication method according to claim 18 or 19,
Each analog signal obtained by performing analog conversion on a complex digital signal sample sequence orthogonal to each other by symbol conversion and serial / parallel conversion is modulated to each RF signal using a common local signal. Multi-carrier communication method. The multicarrier communication method according to any one of claims 18 to 20,
Performs filter processing based on the frequency band of the subcarrier before analog conversion after series-parallel conversion,
Before analog conversion, add a guard interval for each complex digital signal sample sequence,
A windowing process is applied to each of the complex digital signal sample sequences to which the guard interval is added,
And power combining some or all of the RF signals amplified by the plurality of RF amplifiers,
A multicarrier communication method characterized by transmitting a synthesized RF signal into the air using an antenna. The multicarrier communication method according to any one of claims 18 to 21,
Supports multiple types of parallel digital signals that are orthogonal to each other by serial-parallel conversion.
A control unit that selects any one of a plurality of methods for generating parallel digital signals orthogonal to each other according to an input control signal,
Based on the control signal input to the control unit, to generate a selected parallel digital signal,
The orthogonal parallel digital signals are respectively modulated into RF signals and individually amplified,
A multi-carrier communication method characterized by transmitting to the air using an antenna.

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