JP3607177B2 - CDMA receiver - Google Patents

Description

【００３７】
ここでシンボルの実部は同相成分、虚数部は直交成分を表している。
振幅位相補償部５は、ＣＨ推定部９で算出されたチャネル推定値Ｃと情報チャネルの情報信号を逆拡散した受信情報シンボル１１（下記式の符号「Ｄ」）を用いて、伝搬路のフェージングで生じた振幅・位相ひずみを補償する。補正値Ｈで補償した後の情報シンボルＤａは式（３）のように表現できる。

【００３８】
この補償法を図２を用いて具体的に説明する。例えば、パイロットチャネル３０の受信パイロットシンボル３１を用いてＣＨ推定を行い、そのＣＨ推定値を基に時間的に重ならなく、最も近い位置に存在する情報チャネル４０の情報シンボル５２を上記式（１）〜（３）により補償する。図２の例では、パイロットシンボル３１の１シンボル分で情報チャネル４０の情報シンボル５２の４シンボル分を補償する。ＣＨ推定を行うために使用したシンボル時間長と補償したシンボル時間長は同一である。同様に、パイロットチャネル３０の受信パイロットシンボル３２を用いてＣＨ推定を行い、そのＣＨ推定値を基に時間的に重ならなく、最も近い位置に存在する情報チャネル４０の情報シンボル５３を補償する等、順次ＣＨ推定と補償を繰り返すことにより、情報チャネルのすべての情報シンボルを補償することができる。
【００３９】
このように補償すべき情報シンボルに対して直前のパイロットシンボルのＣＨ推定値Ｃを使用する外挿補間のため、情報シンボルをメモリする必要が無い。実用的には、ＣＨ推定の処理時間による遅延を考慮しても、必要とされる情報シンボルのメモリ量は数シンボル程度で十分である。
【００４０】
図２では、情報シンボル速度はパイロットチャネルのシンボル速度の４倍としたが、８倍の場合には、パイロットシンボル３１を用いたＣＨ推定により、８シンボルから成る情報シンボル５２を補償することになる。
【００４１】
マルチメディア化に伴ない、データ速度（シンボル速度）が高速になるにつれて、情報チャネル４０の１スロットに含まれる情報シンボル５８，５９のシンボル数が増大する。この場合、従来のような内挿補間では、１スロット中の情報シンボルが非常に増大するため、本発明の特長がよりいっそう効果を発揮する。
【００４２】
ＣＨ推定に使用したパイロットチャネルシンボル３１，３２等は１シンボルのみで構成されていたが、複数パイロットシンボルを利用して平均化した結果を基にＣＨ推定を行い、情報シンボルを補償すれば、ＣＨ推定精度の向上が期待できる。また、情報チャネル４０のパイロットシンボル４１，４２，４３は、それぞれ１シンボルで構成されている例を示したが、複数のパイロットシンボルから構成されている場合もあるが、本発明を適用できることは明らかである。
【００４３】
本発明の第２の実施形態を、図３を用いて説明する。尚、本実施形態は、前記実施形態とＣＨ推定方法を異にするものであり、係るＣＨ推定方法を中心に説明し、図２と同一内容については、同一記号で示している。
本実施形態のＣＨ推定方法は、パイロットチャネル３０の複数のパイロットシンボル３１，３２から成るパイロットシンボル６１を利用してＣＨ推定を行い、パイロットシンボル６１と一部重なる情報シンボル５２の補償を行う。すなわち、情報シンボル５２を補償するために、情報シンボル５２と時間的に同一のパイロットシンボル３２とその直前のパイロットシンボル３１から成るパイロットシンボル６１を利用してＣＨ推定を行う。
【００４４】
複数のパイロットシンボル３１，３２を利用するため、上記式（１）、式（２）を複数シンボルそれぞれに対して算出し、その平均化を行うことにより、パイロットシンボル６１のＣＨ推定値Ｃが求まる。
【００４５】
同様に、次の情報シンボル５３を補償するために、情報シンボル５３と時間的に同一のパイロットシンボル３３と直前のパイロットシンボル３２から成るパイロットシンボル６２を利用してＣＨ推定を行う。
【００４６】
このように、第２の実施形態では、連続した情報シンボル５２，５３等を補償するために、ＣＨ推定に用いるパイロットシンボル６１，６２等は各情報シンボル５２，５３等と時間的に同一および直前のパイロットシンボル（３２，３１）、（３３，３２）等を用いる。
したがって、ＣＨ推定を行うパイロットシンボル時間長は、補償すべき情報シンボル時間長の整数倍（図２の例では２倍）長いため、ＣＨ推定の精度が向上する長所がある。また、情報シンボルを補償するために利用したパイロットシンボルは、補償すべき情報シンボルを時間的に包含しているため、内挿補間の特性を持つ。
図３より第２の実施形態で必要となるメモリ数は、補償すべき情報シンボル５２，５３等のため、数シンボル分に過ぎない。
【００４７】
次に、本発明の第３の実施形態を、図４を用いて説明する。尚、本実施形態は、前記実施形態とＣＨ推定方法を異にするものであり、係るＣＨ推定方法を中心に説明し、図４において図２と同一内容については、同一記号で示している。
本実施形態のＣＨ推定方法は、パイロットチャネル３０の複数のパイロットシンボル３１，３２から成るパイロットシンボル６１を利用してＣＨ推定を行い、パイロットシンボル６１と一部重なる情報シンボル５１の補償を行う。すなわち、情報シンボル５１を補償するために、情報シンボル５１と時間的に同一のパイロットシンボル３１とその直後のパイロットシンボル３２から成るパイロットシンボル６１を利用してＣＨ推定を行う。
【００４８】
同様に、次の情報シンボル５２を補償するために、情報シンボル５２と時間的に同一のパイロットシンボル３２と直後のパイロットシンボル３３から成るパイロットシンボル６２を利用してＣＨ推定を行う。
【００４９】
以上説明したように、第３の実施形態では、連続した情報シンボル５１，５２等を補償するために、ＣＨ推定に用いるパイロットシンボル６１，６２等は各情報シンボル５１，５２等と時間的に同一および直後のパイロットシンボル（３１，３２）、（３２，３３）等を用いる。
したがって、第２の実施形態と同様に、ＣＨ推定を行うパイロットシンボル時間長は補償すべき情報シンボル時間長の整数倍（図２の例では２倍）長いため、ＣＨ推定の精度が向上する長所がある。また、情報シンボルを補償するために利用したパイロットシンボルは、補償すべき情報シンボルを時間的に包含しているため、内挿補間の特性を持つ。
【００５０】
前記第１及び第２の実施形態では、パイロットシンボル３１からＣＨ推定を開始した場合、情報シンボル５１の補償はできなく、次の周期（フレーム時間長）まで補償ができない。しかし、本第３の実施形態では、第１及び第２の実施形態と異なり、図４に示すように、補償すべき情報シンボル、例えばシンボル５１の時間的位置はＣＨ推定を行うパイロットシンボル６１に関して、同一位置シンボル３１及び後方位置シンボル３２を利用しているため、補償すべき情報シンボルの抜けがなくなるため、効率的なＣＨ推定、情報復調、Ｒａｋｅ合成が可能となる。この現象は、ＣＤＭＡ受信機が電源ＯＮされ、ＣＨ推定・情報復調を開始する初期時、または低消費電力化のために、スリープモード時にページング信号を受信する場合等に重要となる。
【００５１】
次に、本発明の第４の実施形態を、図５を参照しつつ説明する。尚、本実施形態は、前記実施形態とＣＨ推定方法を異にするものであり、係るＣＨ推定方法を中心に説明し、図５において図２と同一内容については、同一記号で示している。
本実施形態のＣＨ推定方法は、パイロットチャネル３０の複数のパイロットシンボル３１，３２，３３から成るパイロットシンボル７１を利用してＣＨ推定を行い、パイロットシンボル７１に時間的に包含される情報シンボル５２の補償を行う。すなわち、情報シンボル５２と時間的に同一のパイロットシンボル３２とその前後のパイロットシンボル３１，３３から成るパイロットシンボル７１を利用してＣＨ推定を行う。
【００５２】
同様に、次の情報シンボル５３の補償も情報シンボル５３と時間的に同一のパイロットシンボル３３とその前後のパイロットシンボル３２，３４から成るパイロットシンボル７２を利用してＣＨ推定を行う。
【００５３】
以上説明したように、第４の実施形態では、連続した情報シンボル５２，５３等を補償するために、ＣＨ推定に用いるパイロットシンボル７１，７２等は各情報シンボル５２，５３等と時間的に同一および前後のパイロットシンボル（３２，３１，３３）、（３２，３３，３４）等を用いる。
したがって、第２の実施形態と同様に、ＣＨ推定を行うパイロットシンボル時間長は補償すべき情報シンボル時間長の整数倍（図５の例では３倍）長いため、ＣＨ推定の精度が向上する。また、情報シンボルを補償するために利用したパイロットシンボルは、補償すべき情報シンボルを時間的に包含しているため、内挿補間の特性を持つ。
【００５４】
次に、第５の実施形態を、図６を参照しつつ説明する。
パイロットチャネル３０は、基地局のサービス域内に存在する全ての移動局によって共通に利用される。他方、情報チャネル４０は、基地局のサービス域内に存在する個々の移動局に対して、個々の拡散符号により拡散された信号として基地局から送信される。
また、個々の移動局と基地局との間の伝搬路状況に依存して基地局が行う例えば、パワーコントロール、送信ダイバシチ等により、情報チャネル信号４０の振幅、位相が調整される。したがって、移動機で受信したパイロットチャネル３０と情報チャネル４０の受信信号振幅は異なる場合がある。一例として、図６にパワーコントロールされた場合、移動機で受信したパイロットチャネル３０と情報チャネル４０の受信電力９０，９１を模式的に示す。
情報チャネル４０の受信電力９１は、パワーコントロールされていれば、基地局からの距離に依存せず一定の受信電力であり、他方、パイロットチャネル３０の受信電力９０は基地局からの距離に依存して減衰する。また、パイロットチャネル３０は基地局域内に位置する全ての移動機により利用されるため、一般に大電力で送信される。
【００５５】
前記したように、図２において、情報チャネル４０には周期的にパイロットシンボル４１，４２，４３が挿入されている。式（１）〜式（３）より、補償後の情報シンボルＤａの振幅は、補償前の受信情報シンボルの振幅｜Ｄ｜（｜ ｜は絶対値を示す）の他に、ＣＨ推定に使用した受信パイロットシンボル振幅Ａに依存する。したがってパイロットチャネル３０を利用したチャネル推定では図６で示したように、移動局が基地局近傍に位置した場合と、遠方に位置した場合で補償後の情報シンボル振幅が大きく影響される場合がある。
また、パイロットチャネルはパワーコントロールされていないため、移動体通信では伝搬路特性により大きく減衰する現象９２，９３が生じる場合がある。この減衰したパイロットチャネルを利用したＣＨ推定では、補償後の情報シンボルＤａの振幅も減衰するため、パワーコントロール動作とは矛盾した結果となる場合がある。
【００５６】
本第５の実施形態では、上記の状況を考慮したチャネル推定法であり、パイロットチャネル３０と情報チャネル４０のパイロットシンボルの両方を利用してＣＨ推定を行う。情報チャネル４０のパイロットシンボルを用いたＣＨ推定は、情報チャネル逆拡散部４より逆拡散された信号１３をチャネル推定部９のパイロットシンボル利用ＣＨ推定部２１により行われ、チャネル推定値１６を出力する。
【００５７】
補正すべき受信情報シンボルＤに関して、パイロットチャネルを利用したＣＨ推定値１５（「Ｃ１」）、その推定値を用いた補償後の情報シンボルＤａ及び情報チャネルのパイロットシンボルを利用したＣＨ推定値１６（下記符合「Ｃ１０」）、その推定値を用いた補償後の情報シンボルＤｂ、両補償後の振幅比Ｍは上記式（１）、（２）、（３）から次のようになる。

式（６）より、振幅比Ｍは情報チャネルの受信振幅とパイロットチャネルの受信信号振幅の比となる。
【００５８】
以上のように、パイロットチャネル３０を利用したＣＨ推定を行い、補償した情報シンボルＤａに対して式（６）で示した振幅補正値Ｍを演算することにより、上記課題を解決できる。
【００５９】
次に、第６の実施形態では、パイロットチャネル３０を利用したＣＨ推定と情報チャネル４０のパイロットシンボルを利用したＣＨ推定の両ＣＨ推定を実行し、そのＣＨ推定または補償後の情報チャネルパイロットシンボルの信頼性測定手段を設置する。ここで信頼性測定手段とは、両ＣＨ推定のうち、どちらのＣＨ推定を利用した方が精度の高い情報チャネルのシンボル補償ができるかを測定する手段である。その信頼性測定手段で測定した信頼性結果に基いて、いづれかのＣＨ推定値を選択して情報チャネルシンボルを補償する。
【００６０】
前記信頼性測定手段の一例として、補償後の情報チャネルパイロットシンボルの信頼性測定手段の一手法を説明する。
情報チャネル４０には、パイロットシンボル４１，４２，４３があるため、このパイロットシンボルに対するＣＨ推定を、パイロットチャネルを利用したＣＨ推定と情報チャネルのパイロットシンボルを利用したＣＨ推定の両ＣＨ推定により実行する。
そして、パイロットチャネル３０を利用したＣＨ推定に基く補償後のパイロットシンボルＰａと、情報チャネル４０を利用したＣＨ推定に基く補償後のパイロットシンボルＰｂと、を既知のパイロットシンボルＰ１０と比較する。例えば式（７）、（８）に示すように、補償後の情報チャネルのパイロットシンボルと既知のパイロットシンボルとの誤差Ｅ１、Ｅ２を判断基準とし、信頼性が高い方のＣＨ推定値を選択して情報チャネルシンボルを補償する。
Ｅ１＝｜Ｐａ−Ｐ１０｜ （７）
Ｅ２＝｜Ｐｂ−Ｐ１０｜ （８）
【００６１】
前記信頼性測定手段のその他の例として、情報チャネルとパイロットシンボルに対する補償を、パイロットチャネルを利用したＣＨ推定と情報チャネルのパイロットシンボル利用したＣＨ推定の両ＣＨ推定により実行し、両補償後のパイロットシンボルの振幅値を比較することにより実現できる。すなわち、ＣＨ推定の振幅値または補償後の振幅値を比較して、振幅値が大きい方を信頼性が高いと判断し、いづれかのＣＨ推定を選択する。
【００６２】
次に、第７の実施形態として、基地局が送信するパイロットチャネルの信号と情報チャネルの信号に位相差がある場合に対応するＣＨ推定法を説明する。
第６の実施形態と同様に、パイロットチャネルを利用したＣＨ推定と情報チャネルのパイロットシンボル利用したＣＨ推定の両ＣＨ推定を実行する。さらに、情報チャネルの位相情報を保持するため、情報シンボル補償に使用する位相項は情報チャネルを用いたＣＨ推定を使用する。他方、振幅項の補償は第５の実施形態で示したように、パイロットチャネルを利用したＣＨ推定を行い、補償した情報シンボルＤａに対して式（６）で示した振幅補正値Ｍを演算する。
【００６３】
前記した実施形態における情報チャネル４０を利用したチャネル推定は、例えば、図２の情報チャネル４０のパイロットシンボル４１，４２，４３等を利用、またはそれらを平均化することで実行される。
例えば、図２の情報チャネル４０のパイロットシンボル４１，４２，４３が、それぞれ複数のパイロットシンボルから構成されている場合のＣＨ推定は、それら複数の受信パイロットシンボルを平均化した後にＣＨ推定を行う、又は、各シンボルに対してＣＨ推定を行った結果を平均化することにより実行される。
【００６４】
情報チャネルのその他のＣＨ推定として、図２の情報チャネル４０において、複数スロットにまたがるパイロットシンボル４１，４２，４３を利用して、平均化することにより情報チャネルのＣＨ推定を実行する方法を行うことができる。このように情報チャネルの複数のパイロットシンボルの平均化または、複数スロットにまたがる平均化により、限られた情報チャネルのパイロットシンボルを有効にＣＨ推定として利用できる。
【００６５】
また、前記実施形態における情報チャネルを利用したＣＨ推定は、例えば、図２で情報シンボル５９を補償する場合、その補償すべき情報シンボル５９の両端に位置するパイロットシンボル４２，４３、すなわち、補償すべき情報シンボルを含むスロットに存在するパイロットシンボル４３と、その前のスロットに存在するパイロットシンボル４２を少なくとも含むパイロットシンボルを利用してＣＨ推定を行うことができる。
【００６６】
【発明の効果】
以上説明したように、この発明ではパイロットチャネルを利用したＣＨ推定及びシンボル補償を行うために、情報シンボルの１スロット分をメモリする必要はなく、また、パイロットチャネルとパイロットシンボルの少なくとも一方を利用するため、伝搬路で生じたフェージングを高精度で補償できる。
【図面の簡単な説明】
【図１】本発明の実施形態に係るＣＤＭＡ方式の受信部のブロック図である。
【図２】本発明の第１の実施形態に係る受信情報シンボルの補償法の説明図である。
【図３】本発明の第２の実施形態に係る受信情報シンボルの補償法の説明図である。
【図４】本発明の第３の実施形態に係る受信情報シンボルの補償法の説明図である。
【図５】本発明の第４の実施形態に係る受信情報シンボルの補償法の説明図である。
【図６】情報チャネルとパイロットチャネルの基地局からの距離に対する受信電力の説明図である。
【図７】従来の受信情報シンボルの補償法の説明図である。
【符号の説明】
１ アンテナ
２ ＲＦ増幅器
３ 周波数変換器
４ 情報チャネル逆拡散部
５ 振幅・位相補償部
６ Ｒａｋｅ合成部
７ パイロットチャネル逆拡散部
８ パスサーチ部
９ チャネル推定部
１０ 受信ベースバンド信号
１１，１３，１４ 逆拡散信号
１２ 振幅・位相補償後の信号
２０ パイロットチャネルを利用したチャネル推定部
２１ パイロットシンボルを利用したチャネル推定部
３０ パイロットチャネル
４０ 情報チャネル
３１，３２，３３，３４，３５，３６ パイロットチャネルのパイロットシンボル
４１，４２，４３ 情報チャネルのパイロットシンボル
５１，５２，５３，５４，５５，５６，５７ 補償すべきシンボル
６１，６２，６３，６４，７１，７２，７３ チャネル推定に利用するパイロットシンボル[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a CDMA receiver that performs data communication in a fading environment in a CDMA (Code Division Multiplex Access) system.
[0002]
[Prior art]
Conventionally, CDMA systems using spread spectrum communication and spread spectrum communication technology are resistant to multipath fading, can speed up data, have good communication quality, and have good frequency utilization efficiency. This is a promising communication method for wireless communication.
[0003]
A transmission signal in a CDMA system and spread spectrum communication is transmitted by being spread over a band far wider than the bandwidth of an information signal to be transmitted on the transmission side. On the other hand, the receiving side is required to have a function of restoring the spread CDMA signal to the original signal bandwidth and demodulating the information signal. The operation of restoring the original signal bandwidth is called despreading, and a despreading method using a matched filter method and a sliding correlation method are known.
[0004]
Since fading such as multipath between the base station and the mobile station exists in a wireless environment such as mobile communication, when the CDMA signal transmitted from the base station is received by the mobile station, the received signal undergoes amplitude and phase fluctuations. .
For this reason, conventionally, in order to estimate this fading distortion, a known pilot symbol is inserted into a part of information data (symbol) transmitted by the base station at a predetermined time interval, and this pilot is transmitted by the mobile station. By receiving and demodulating the symbols and comparing them with known pilot symbols that should be received, it is possible to estimate the amplitude and phase fluctuations (fading distortion) that the transmission signal has received in the propagation path.
[0005]
For example, in “16QAM fading distortion compensation system for land mobile communication, Sanbo: IEICE Transactions Vol. J72-B-II No. 1 pp7-15 January 1989”, a known frame for measuring transmission path characteristics Symbols (pilot symbols) are periodically inserted into information symbols. Fading distortion is estimated by receiving and demodulating this periodic pilot symbol and comparing it with the known frame symbol (pilot symbol). That is, a method for compensating information symbols between pilot symbols by interpolating based on channel estimation using pilot symbols has been proposed.
[0006]
FIG. 7 shows a fading distortion estimation method according to the above document. In FIG. 7, a signal 790 is periodically inserted between information symbols 700, 720, and 740, each of which has a slot length of 1 pilot 710 and 730. Therefore, for example, fading distortion compensation of the information symbol 720 is performed by estimating the fading distortion using the pilot symbols 710 and 730 at both ends and interpolating.
[0007]
As a technique for estimating fading distortion with high accuracy and performing interpolation, “High-accuracy channel estimation method using multiple pilot blocks in DS-CDMA, Ando, Sawahashi: Shingaku technique RCS-96-72 1996-08” A channel estimation method is proposed by using pilot symbols across slots and weighting and averaging the pilot symbols.
[0008]
In addition to the traffic channel (information channel) that transmits the information signal shown in the conventional example above, a pilot channel that transmits only known pilot symbols orthogonal by orthogonal codes is transmitted simultaneously (in parallel), and the pilot channel is used. A method for estimating and compensating for fading distortion is proposed in “DS / CDMA Synchronous Detection System Using Suppressed Pilot Channel, Abeda: Journal of the Institute of Electronics, Information and Communication Engineers, Vol. Has been. In this method, fading distortion is estimated between the slots using a pilot channel, and information symbols of the information channel are compensated using this estimated value.
[0009]
[Problems to be solved by the invention]
However, in the above-mentioned “16QAM fading distortion compensation system for land mobile communication”, information symbols 700, 720, and 740 for one slot are temporarily stored in a memory in order to compensate information symbols between pilot symbols by interpolation. There is a need. When handling multimedia data, the data rate (symbol rate) increases, so the amount of information stored in one slot in the memory becomes very large, which increases the memory capacity, difficulty in implementing LSIs, and increases costs. It was.
[0010]
Even in the “DS / CDMA synchronous detection method using a suppressed pilot channel”, it is necessary to store information for one slot in the same manner, and there is the same problem.
[0011]
In the above-described “high-accuracy channel estimation method using a plurality of pilot blocks in DS-CDMA”, information for a plurality of slots needs to be stored in a memory, and thus there is a problem that the memory capacity further increases.
[0012]
The present invention has been made in order to solve the above-described problems, and has a high performance and an easy configuration capable of minimizing necessary memory by using channel estimation using a pilot channel. An object of the present invention is to provide a CDMA receiver having
[0013]
[Means for Solving the Problems]
In order to achieve the above object, the present invention has the following configuration.
According to a first aspect of the present invention, there is provided an information signal including a pilot channel in which pilot symbols are spread using a spreading code, an information symbol, and a pilot symbol periodically inserted between the information symbols. In a CDMA receiver that receives and demodulates a CDMA signal having an information channel spread using a spreading code orthogonal to the spreading code, the receiver despreads the received CDMA signal, and despreading A channel estimation unit that estimates fading characteristics using the pilot channel despread in the unit, and outputs the first channel estimation information to the despreading unit using the first channel estimation information A compensation unit that compensates information symbols of the information channel despread and outputs a first compensation information symbol, and the channel estimation unit includes: In CDMA receiver and performing a first channel estimation using pilot symbols positioned immediately before that does not overlap the broadcast signal symbol temporally.
[0014]
According to the first aspect of the present invention, there is a need to store information signal symbols for extrapolation using the first channel estimation information using the immediately preceding pilot symbols for the information signal symbols to be compensated. No. As the data rate (symbol rate) increases with the increase in multimedia, the number of information symbols included in one slot of the information channel increases, so that the effect is further enhanced.
[0015]
According to a second aspect of the present invention, a channel estimation unit uses a pilot symbol located immediately before not overlapping with an information signal symbol and a pilot symbol temporally identical to the information symbol. A CDMA receiver according to the first aspect, wherein channel estimation is performed.
[0016]
According to the second aspect of the present invention, since the pilot symbol time length for performing the first channel estimation is an integral multiple of the information signal symbol time length, the accuracy of CH estimation is improved.
[0017]
According to a third aspect of the present invention, there is provided an information signal including a pilot channel in which pilot symbols are spread using a spreading code, an information symbol, and a pilot symbol periodically inserted between the information symbols. In a CDMA receiver that receives and demodulates a CDMA signal having an information channel spread using a spreading code orthogonal to the spreading code, the receiver despreads the received CDMA signal, and despreading A first channel estimation for estimating fading characteristics using a pilot channel despread in the first channel, and a first channel estimation information for performing a first channel estimation and a first channel estimation information A compensation unit that compensates information symbols of the information channel despread by the spreading unit and outputs a first compensation information symbol, and channel estimation Is the information symbols and temporally same pilot symbol, the CDMA receiver and performing using the pilot symbols positioned immediately thereafter, the.
[0018]
According to the third aspect of the present invention, since the pilot symbol time length for estimation is an integral multiple of the information symbol time length to be compensated, the accuracy of channel estimation is improved. Also, since there is no missing information symbol to be compensated, efficient channel estimation is possible. In this case, this is effective when the paging signal is received in the sleep mode for the initial time when the power of the CDMA receiver is turned on and channel estimation / information demodulation is started or to reduce power consumption.
[0019]
According to a fourth aspect of the present invention, in the first to third aspects, the channel estimator performs the pilot symbol temporally identical to the information symbol and the pilot symbols positioned before and after the information symbol. Located in CDMA receiver.
[0020]
According to the fourth aspect of the present invention, since the pilot symbol time length for performing channel estimation is an integral multiple of the information symbol time length to be compensated, the accuracy of channel estimation is improved. In addition, the pilot symbol used for compensating the information symbol has the characteristic of interpolation because it includes temporally the information symbol to be compensated. Moreover, since there is no missing information symbol to be compensated, efficient channel estimation is possible.
[0021]
According to a fifth aspect of the present invention, the channel estimation unit performs second channel estimation using the information channel despread by the despreading unit to obtain second channel estimation information, and the compensation unit The information symbol of the information channel despread by the despreading unit is compensated using the channel estimation information, the second compensation information symbol is calculated, and the first compensation information symbol and the second compensation information symbol are calculated. The CDMA receiver according to the first or third aspect is characterized in that the amplitude of the first compensation information symbol is corrected by the amplitude correction value obtained by using.
[0022]
According to the fifth aspect of the present invention, in mobile communication, a compensation information symbol is considered in consideration of a pilot channel that is affected by a case where the mobile station is located near the base station and a case where the mobile station is located far away due to propagation path characteristics. The influence on the amplitude can be reduced.
[0023]
According to a sixth aspect of the present invention, the channel estimation unit performs second channel estimation using the information channel despread by the despreading unit to obtain second channel estimation information, and the compensation unit performs despreading. Compensation for the pilot symbols of the information channel despread in the unit is performed by performing channel estimation using the first channel estimation information and the second channel estimation information, respectively. An information symbol having a reliability measurement unit for determining the reliability of the channel estimation information, and selecting either the first channel estimation information or the second channel estimation information based on the reliability result of the reliability measurement unit The CDMA receiver according to the first or third aspect is characterized in that the CDMA receiver is compensated for.
[0024]
According to a seventh aspect of the present invention, the reliability measurement unit performs compensation for the pilot symbol of the information channel by using both channel estimation information of the first channel estimation information and the second channel estimation information, and performs both channel estimation. The CDMA receiver according to the sixth aspect is characterized in that a reliability result is obtained by comparing an error between a compensated pilot symbol based on information and a known pilot symbol.
[0025]
According to an eighth aspect of the present invention, the reliability measurement unit performs compensation for the pilot symbol of the information channel using both channel estimation information of the first channel estimation information and the second channel estimation information, and the both channel estimation is performed. The CDMA receiver according to the sixth aspect is characterized in that a reliability result is obtained by comparing amplitude values of compensated pilot symbols based on information.
[0026]
According to the fifth to eighth aspects of the present invention, in mobile communication, compensation is performed in consideration of pilot channels that are affected by the propagation path characteristics when the mobile station is located near the base station and when the mobile station is located far away. The influence on the information symbol amplitude can be reduced.
[0027]
According to a ninth aspect of the present invention, the compensation unit uses the second channel estimation information for the phase term used for compensation of the information symbol, uses the first channel estimation information for the compensation of the amplitude term, and the amplitude. The CDMA receiver according to the fifth aspect, wherein the amplitude of the first compensation information symbol is corrected by the correction value.
[0028]
According to a tenth aspect of the present invention, the pilot symbol of the information channel is composed of a plurality of pilot symbols, and the channel estimation of the information channel is performed by averaging the plurality of pilot symbols and then performing channel estimation or a plurality of pilot symbols The CDMA receiver according to any one of Items 5 to 9, wherein channel estimation is performed after channel estimation using each of the channels, and channel estimation is performed.
[0029]
An eleventh aspect of the present invention is the CDMA receiver according to any one of the fifth to ninth aspects, wherein the second channel estimation of the information channel is performed by averaging pilot symbols of the information channel over a plurality of slots. It is in.
The twelfth aspect of the present invention is characterized in that the second channel estimation of the information channel performs channel estimation using pilot symbols including at least pilot symbols of the information channel positioned at both ends of the information symbol to be compensated. The CDMA receiver according to the fifth to ninth aspects.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a block diagram of a CDMA receiver according to an embodiment of the present invention. Here, the CDMA signal transmitted from the base station includes information composed of a pilot channel in which pilot symbols are spread using a spreading code, and information symbols and pilot symbols periodically inserted between the information symbols. The signal consists of an information channel spread using a spreading code orthogonal to the spreading code.
[0031]
This CDMA signal is received by the antenna 1, amplified by the RF amplification unit 2, and then converted from a radio frequency to an intermediate frequency or baseband frequency by the frequency conversion unit 3, and the information channel despreading unit 4 and the base station A channel estimator (hereinafter abbreviated as “CH estimator”) 9 for estimating fading characteristics determined from the radio channel environment between mobile stations, and an information channel using CH estimation information 15 obtained by the channel estimator 9 Information symbol amplitude / phase compensator 5, Rake combiner 6 that combines the information symbols of each path subjected to amplitude / phase compensation, pilot channel despreader 7, and multipath components of the propagation path are identified and Rake combined. It comprises a path search unit 8 for defining an effective path.
[0032]
The information channel despreading unit 4, the CH estimation unit 9, the amplitude / phase compensation unit 5, and the pilot channel despreading unit 7 are arranged in parallel by the number of paths necessary for the Rake combining unit.
[0033]
FIG. 2 shows the signal structure of the pilot channel 30 and the information channel 40. The pilot channels are all composed of known pilot symbols 31 to 38, while the information channels are known pilot symbols 41, 42, 43 with respect to the information symbols 58, 59 as in FIG. It is inserted periodically for each slot.
[0034]
Since pilot channel 30 serves as a pilot, its symbol rate is generally lower than the information symbol rate. In FIG. 2, the symbol rate of pilot channel 30 is ¼ of the information symbol rate as an example.
[0035]
Channel estimation using pilot channel 30 of the present embodiment will be described below. The pilot symbol 31 to 38 of the pilot channel 30 transmitted from the base station is received by the receiver, and the signal 14 despread by the pilot channel despreading unit 7 is subjected to channel estimation by the pilot channel using CH estimation unit 20 in the CH estimation unit 9. Is executed. Channel estimation involves despreading signal 14 (symbol “P” in the following equation) and a known pilot symbol (symbol “P in the following equation). ₀ )), And as a result, the channel estimation value 15 (sign “C” in the following equation) can be expressed by the equation (1).
[0036]

[0037]
Here, the real part of the symbol represents the in-phase component, and the imaginary part represents the quadrature component.
The amplitude and phase compensation unit 5 uses the channel estimation value C calculated by the CH estimation unit 9 and the received information symbol 11 (denoted by “D” in the following equation) obtained by despreading the information signal of the information channel, and fading the propagation path. Compensates for amplitude and phase distortion caused by. The information symbol Da after compensation with the correction value H can be expressed as shown in Equation (3).

[0038]
This compensation method will be specifically described with reference to FIG. For example, CH estimation is performed using the received pilot symbol 31 of the pilot channel 30, and the information symbol 52 of the information channel 40 present at the nearest position without overlapping in time based on the CH estimation value is expressed by the above equation (1). ) To (3). In the example of FIG. 2, four symbols of the information symbols 52 of the information channel 40 are compensated by one symbol of the pilot symbols 31. The symbol time length used to perform CH estimation is the same as the compensated symbol time length. Similarly, CH estimation is performed using the received pilot symbol 32 of the pilot channel 30, and the information symbol 53 of the information channel 40 existing in the nearest position is compensated based on the CH estimation value without overlapping in time. By sequentially repeating CH estimation and compensation, all information symbols of the information channel can be compensated.
[0039]
Since extrapolation using the CH estimation value C of the immediately preceding pilot symbol for the information symbol to be compensated in this way, it is not necessary to store the information symbol. Practically, even if the delay due to the CH estimation processing time is taken into consideration, the required amount of information symbol memory is about several symbols.
[0040]
In FIG. 2, the information symbol rate is four times the pilot channel symbol rate. However, in the case of eight times, the information symbol 52 composed of eight symbols is compensated by CH estimation using the pilot symbol 31. .
[0041]
As the data rate (symbol rate) increases with the increase in multimedia, the number of information symbols 58 and 59 contained in one slot of the information channel 40 increases. In this case, in the conventional interpolation, the number of information symbols in one slot is greatly increased, so that the features of the present invention are more effective.
[0042]
The pilot channel symbols 31, 32, etc. used for CH estimation consisted of only one symbol. However, if CH estimation is performed based on the result of averaging using a plurality of pilot symbols and information symbols are compensated, CH An improvement in estimation accuracy can be expected. In addition, the pilot symbols 41, 42, and 43 of the information channel 40 are each configured with one symbol. However, although the information channel 40 may be configured with a plurality of pilot symbols, it is clear that the present invention can be applied. It is.
[0043]
A second embodiment of the present invention will be described with reference to FIG. In this embodiment, the CH estimation method is different from that of the above embodiment. The CH estimation method will be mainly described, and the same contents as those in FIG. 2 are denoted by the same symbols.
In the CH estimation method of the present embodiment, CH estimation is performed using a pilot symbol 61 composed of a plurality of pilot symbols 31 and 32 of the pilot channel 30, and information symbols 52 that partially overlap with the pilot symbol 61 are compensated. That is, in order to compensate for the information symbol 52, CH estimation is performed using a pilot symbol 61 composed of the pilot symbol 32 temporally identical to the information symbol 52 and the pilot symbol 31 immediately before the information symbol 52.
[0044]
Since a plurality of pilot symbols 31 and 32 are used, the above equation (1) and equation (2) are calculated for each of a plurality of symbols and averaged to obtain the CH estimated value C of the pilot symbol 61. .
[0045]
Similarly, in order to compensate for the next information symbol 53, CH estimation is performed using a pilot symbol 62 composed of a pilot symbol 33 that is temporally identical to the information symbol 53 and the immediately preceding pilot symbol 32.
[0046]
Thus, in the second embodiment, in order to compensate for the continuous information symbols 52, 53, etc., the pilot symbols 61, 62, etc. used for CH estimation are temporally the same as and immediately before each information symbol 52, 53, etc. Pilot symbols (32, 31), (33, 32), etc. are used.
Therefore, since the pilot symbol time length for performing CH estimation is an integral multiple (2 times in the example of FIG. 2) of the information symbol time length to be compensated, there is an advantage that the accuracy of CH estimation is improved. In addition, the pilot symbol used to compensate the information symbol includes the information symbol to be compensated in terms of time, and thus has a characteristic of interpolation.
From FIG. 3, the number of memories required in the second embodiment is only a few symbols because of the information symbols 52 and 53 to be compensated.
[0047]
Next, a third embodiment of the present invention will be described with reference to FIG. In this embodiment, the CH estimation method is different from that of the above embodiment, and the CH estimation method will be mainly described. In FIG. 4, the same contents as those in FIG. 2 are indicated by the same symbols.
In the CH estimation method of the present embodiment, CH estimation is performed using a pilot symbol 61 composed of a plurality of pilot symbols 31 and 32 of the pilot channel 30, and information symbols 51 that partially overlap with the pilot symbol 61 are compensated. That is, in order to compensate for the information symbol 51, CH estimation is performed using a pilot symbol 61 including a pilot symbol 31 that is temporally identical to the information symbol 51 and a pilot symbol 32 immediately thereafter.
[0048]
Similarly, in order to compensate for the next information symbol 52, CH estimation is performed using a pilot symbol 62 including a pilot symbol 32 that is temporally identical to the information symbol 52 and a pilot symbol 33 immediately after the information symbol 52.
[0049]
As described above, in the third embodiment, the pilot symbols 61, 62, etc. used for CH estimation are temporally identical to the information symbols 51, 52, etc. in order to compensate for the continuous information symbols 51, 52, etc. And immediately following pilot symbols (31, 32), (32, 33), etc. are used.
Therefore, as in the second embodiment, the pilot symbol time length for performing CH estimation is an integral multiple of the information symbol time length to be compensated (twice in the example of FIG. 2), so that the accuracy of CH estimation is improved. There is. In addition, the pilot symbol used for compensating the information symbol has the characteristic of interpolation because it includes temporally the information symbol to be compensated.
[0050]
In the first and second embodiments, when the CH estimation is started from the pilot symbol 31, the information symbol 51 cannot be compensated and cannot be compensated until the next period (frame time length). However, in the third embodiment, unlike the first and second embodiments, the information symbol to be compensated, for example, the temporal position of the symbol 51 is related to the pilot symbol 61 that performs CH estimation, as shown in FIG. Since the same position symbol 31 and the rear position symbol 32 are used, there is no missing information symbol to be compensated, so that efficient CH estimation, information demodulation, and Rake combining are possible. This phenomenon is important at the initial stage when the CDMA receiver is turned on and starts CH estimation / information demodulation, or when a paging signal is received in the sleep mode in order to reduce power consumption.
[0051]
Next, a fourth embodiment of the present invention will be described with reference to FIG. This embodiment is different from the above embodiment in the CH estimation method, and will be described mainly with reference to the CH estimation method. In FIG. 5, the same contents as those in FIG. 2 are indicated by the same symbols.
In the CH estimation method of this embodiment, CH estimation is performed using a pilot symbol 71 composed of a plurality of pilot symbols 31, 32, 33 of the pilot channel 30, and information symbols 52 temporally included in the pilot symbol 71 are included. Compensate. That is, CH estimation is performed using a pilot symbol 71 including a pilot symbol 32 temporally identical to the information symbol 52 and pilot symbols 31 and 33 before and after the pilot symbol 32.
[0052]
Similarly, in the compensation of the next information symbol 53, CH estimation is performed using a pilot symbol 72 composed of the pilot symbol 33 temporally identical to the information symbol 53 and the pilot symbols 32 and 34 before and after the pilot symbol 33.
[0053]
As described above, in the fourth embodiment, the pilot symbols 71, 72, etc. used for CH estimation are temporally identical to the information symbols 52, 53, etc. in order to compensate for the continuous information symbols 52, 53, etc. And the front and rear pilot symbols (32, 31, 33), (32, 33, 34), etc. are used.
Therefore, as in the second embodiment, the pilot symbol time length for performing CH estimation is an integral multiple (3 times in the example of FIG. 5) of the information symbol time length to be compensated, so that the accuracy of CH estimation is improved. In addition, the pilot symbol used for compensating the information symbol has the characteristic of interpolation because it includes temporally the information symbol to be compensated.
[0054]
Next, a fifth embodiment will be described with reference to FIG.
The pilot channel 30 is commonly used by all mobile stations existing within the service area of the base station. other On the other hand, the information channel 40 is transmitted from the base station as a signal spread by each spreading code to each mobile station existing in the service area of the base station.
Further, the amplitude and phase of the information channel signal 40 are adjusted by, for example, power control, transmission diversity, or the like performed by the base station depending on the propagation path condition between each mobile station and the base station. Therefore, the received signal amplitudes of the pilot channel 30 and the information channel 40 received by the mobile device may be different. As an example, FIG. 6 schematically shows received power 90 and 91 of the pilot channel 30 and the information channel 40 received by the mobile device when power control is performed.
The reception power 91 of the information channel 40 is a constant reception power regardless of the distance from the base station if power control is performed, while the reception power 90 of the pilot channel 30 depends on the distance from the base station. It attenuates. In addition, since pilot channel 30 is used by all mobile devices located within the base station area, it is generally transmitted with high power.
[0055]
As described above, in FIG. 2, pilot symbols 41, 42, and 43 are periodically inserted into the information channel 40. From Equations (1) to (3), the amplitude of the compensated information symbol Da was used for CH estimation in addition to the amplitude | D | (| | represents an absolute value) of the received information symbol before compensation. Depends on the received pilot symbol amplitude A. Therefore, in channel estimation using the pilot channel 30, as shown in FIG. 6, the information symbol amplitude after compensation may be greatly affected when the mobile station is located in the vicinity of the base station or when it is located far away. .
Further, since power control of the pilot channel is not performed, phenomena 92 and 93 that are largely attenuated due to propagation path characteristics may occur in mobile communication. In CH estimation using this attenuated pilot channel, the amplitude of the compensated information symbol Da is also attenuated, which may result in contradiction with the power control operation.
[0056]
The fifth embodiment is a channel estimation method considering the above situation, and CH estimation is performed using both pilot channels 30 and information channel 40 pilot symbols. The CH estimation using the pilot symbols of the information channel 40 is performed by the pilot symbol using CH estimation unit 21 of the channel estimation unit 9 on the signal 13 despread by the information channel despreading unit 4 and outputs the channel estimation value 16. .
[0057]
Regarding the received information symbol D to be corrected, the CH estimation value 15 (“C1”) using the pilot channel, the compensated information symbol Da using the estimation value, and the CH estimation value 16 (using the pilot symbol of the information channel) ( The following symbol “C10”), the compensated information symbol Db using the estimated value, and the amplitude ratio M after both compensation are as follows from the above equations (1), (2), and (3).

From equation (6), the amplitude ratio M is the ratio between the received amplitude of the information channel and the received signal amplitude of the pilot channel.
[0058]
As described above, the above problem can be solved by performing CH estimation using the pilot channel 30 and calculating the amplitude correction value M shown in Expression (6) for the compensated information symbol Da.
[0059]
Next, in the sixth embodiment, both CH estimation using the pilot channel 30 and CH estimation using the pilot symbol of the information channel 40 are performed, and the information channel pilot symbol after the CH estimation or compensation is calculated. Install reliability measurement means. Here, the reliability measurement means is a means for measuring which of the two CH estimations uses which CH estimation can perform symbol compensation of the information channel with higher accuracy. Based on the reliability result measured by the reliability measuring means, any one of the CH estimation values is selected to compensate the information channel symbol.
[0060]
As an example of the reliability measurement unit, a method of the reliability measurement unit for the information channel pilot symbol after compensation will be described.
Since the information channel 40 includes pilot symbols 41, 42, and 43, CH estimation for the pilot symbols is performed by both CH estimation using the pilot channel and CH estimation using the pilot symbol of the information channel. .
Then, the compensated pilot symbol Pa based on CH estimation using the pilot channel 30 and the compensated pilot symbol Pb based on CH estimation using the information channel 40 are compared with a known pilot symbol P10. For example, as shown in Equations (7) and (8), the error estimation E1 and E2 between the compensated information channel pilot symbol and the known pilot symbol are used as judgment criteria, and the more reliable CH estimation value is selected. To compensate for information channel symbols.
E1 = | Pa-P10 | (7)
E2 = | Pb−P10 | (8)
[0061]
As another example of the reliability measurement means, compensation for the information channel and the pilot symbol is performed by both CH estimation using CH estimation using the pilot channel and CH estimation using the pilot symbol of the information channel, and the pilot after both compensation is performed. This can be realized by comparing the amplitude values of the symbols. That is, the CH estimation amplitude value or the compensated amplitude value is compared, and the larger amplitude value is determined to be more reliable, and any one of the CH estimation is selected.
[0062]
Next, as a seventh embodiment, a CH estimation method corresponding to a case where there is a phase difference between a pilot channel signal and an information channel signal transmitted by a base station will be described.
Similar to the sixth embodiment, both CH estimation using CH estimation using a pilot channel and CH estimation using a pilot symbol of an information channel is executed. Furthermore, in order to hold the phase information of the information channel, the phase term used for information symbol compensation uses CH estimation using the information channel. On the other hand, for the compensation of the amplitude term, as shown in the fifth embodiment, CH estimation using the pilot channel is performed, and the amplitude correction value M shown in Expression (6) is calculated for the compensated information symbol Da. .
[0063]
The channel estimation using the information channel 40 in the above-described embodiment is executed by using, for example, pilot symbols 41, 42, 43, etc. of the information channel 40 of FIG. 2 or averaging them.
For example, when the pilot symbols 41, 42, and 43 of the information channel 40 in FIG. 2 are each composed of a plurality of pilot symbols, CH estimation is performed after averaging the plurality of received pilot symbols. Alternatively, it is executed by averaging the results of CH estimation for each symbol.
[0064]
As another CH estimation of the information channel, a method of performing CH estimation of the information channel by performing averaging using pilot symbols 41, 42, and 43 that span a plurality of slots in the information channel 40 of FIG. Can do. Thus, by averaging a plurality of pilot symbols of an information channel or averaging over a plurality of slots, pilot symbols of a limited information channel can be used effectively as CH estimation.
[0065]
Further, in the CH estimation using the information channel in the embodiment, for example, when the information symbol 59 is compensated in FIG. 2, the pilot symbols 42 and 43 positioned at both ends of the information symbol 59 to be compensated, that is, compensation is performed. CH estimation can be performed using a pilot symbol 43 including at least a pilot symbol 43 existing in a slot including a power information symbol and a pilot symbol 42 existing in a previous slot.
[0066]
【The invention's effect】
As described above, in the present invention, in order to perform CH estimation and symbol compensation using the pilot channel, it is not necessary to store one slot of information symbols, and at least one of the pilot channel and the pilot symbol is used. Therefore, fading generated in the propagation path can be compensated with high accuracy.
[Brief description of the drawings]
FIG. 1 is a block diagram of a CDMA receiving unit according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram of a received information symbol compensation method according to the first embodiment of the present invention.
FIG. 3 is an explanatory diagram of a received information symbol compensation method according to a second embodiment of the present invention.
FIG. 4 is an explanatory diagram of a received information symbol compensation method according to a third embodiment of the present invention.
FIG. 5 is an explanatory diagram of a received information symbol compensation method according to a fourth embodiment of the present invention.
FIG. 6 is an explanatory diagram of received power with respect to a distance from a base station of an information channel and a pilot channel.
FIG. 7 is an explanatory diagram of a conventional received information symbol compensation method;
[Explanation of symbols]
1 Antenna
2 RF amplifier
3 Frequency converter
4 Information channel despreading section
5 Amplitude / phase compensator
6 Rake synthesis unit
7 Pilot channel despreading section
8 Path search part
9 Channel estimation unit
10 Receive baseband signal
11, 13, 14 Despread signal
12 Signal after amplitude / phase compensation
20 Channel estimation unit using pilot channel
21 Channel estimation section using pilot symbols
30 Pilot channel
40 information channels
31, 32, 33, 34, 35, 36 Pilot channel pilot symbols
41, 42, 43 Pilot symbols of information channel
51, 52, 53, 54, 55, 56, 57 Symbols to be compensated
61, 62, 63, 64, 71, 72, 73 Pilot symbols used for channel estimation

Claims (12)

An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The pilot channel is commonly used for a plurality of CDMA receivers,
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation to estimate fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
A compensation unit that compensates for information symbols of the information channel despread by the despreading unit using the first channel estimation information, and outputs a first compensation information symbol;
Of the information signal, a continuous information symbol and a pilot symbol at one end of the continuous information symbol are defined as one slot,
The channel estimation unit performs the first channel estimation using a pilot symbol shorter than the one slot,
The CDMA receiver according to claim 1, wherein a pilot symbol shorter than the one slot is only a pilot symbol located immediately before the information signal symbol does not overlap in time. An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The pilot channel is commonly used for a plurality of CDMA receivers,
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation for estimating fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
A compensation unit that compensates for information symbols of the information channel despread by the despreading unit using the first channel estimation information and outputs a first compensation information symbol;
Of the information signal, a continuous information symbol and a pilot symbol at one end of the continuous information symbol are defined as one slot,
The channel estimation unit performs the first channel estimation using a pilot symbol shorter than the one slot,
It said one slot shorter pilot symbols than is, C DMA receivers you being a pilot symbol and said information symbols and temporally same pilot symbols positioned immediately before not overlapping the information symbols and time. An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The pilot channel is commonly used for a plurality of CDMA receivers,
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation to estimate fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
A compensation unit that compensates for information symbols of the information channel despread by the despreading unit using the first channel estimation information, and outputs a first compensation information symbol;
Of the information signal, a continuous information symbol and a pilot symbol at one end of the continuous information symbol are defined as one slot,
The channel estimation unit performs the first channel estimation using a pilot symbol shorter than the one slot ,
Short pilot symbols than the 1 slot, CDMA receiver, which is a pilot symbol located in the information symbols and temporally the same pilot symbol immediately. An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The pilot channel is commonly used for a plurality of CDMA receivers,
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation to estimate fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
A compensation unit that compensates for information symbols of the information channel despread by the despreading unit using the first channel estimation information, and outputs a first compensation information symbol;
Of the information signal, a continuous information symbol and a pilot symbol at one end of the continuous information symbol are defined as one slot,
The channel estimation unit performs the first channel estimation using a pilot symbol shorter than the one slot,
The short pilot symbol than 1 slot, C DMA receivers you being a pilot symbol located before and after the information symbols and temporally same pilot symbol and its. An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation to estimate fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
A compensation unit that compensates for information symbols of the information channel despread by the despreading unit using the first channel estimation information, and outputs a first compensation information symbol;
The channel estimation unit uses the pilot symbol located immediately before the information signal symbol does not overlap in time, or the pilot symbol temporally identical to the information symbol and the pilot symbol located immediately after the first pilot symbol. Perform channel estimation,
The channel estimation unit performs second channel estimation using the information channel despread by the despreading unit to obtain second channel estimation information,
The compensation unit calculates a second compensation information symbol obtained by compensating the information symbol of the information channel despread by the despreading unit, using the second channel estimation information, and the first compensation information symbols and the amplitude correction value obtained by using the compensation information symbols of said 2, C DMA receivers you and corrects the amplitude of said first compensation information symbols. An information signal composed of a pilot channel in which pilot symbols are spread using a spreading code and information symbols and pilot symbols periodically inserted between the information symbols uses a spreading code orthogonal to the spreading code. In a CDMA receiver for receiving and demodulating a CDMA signal having a spread information channel
The receiver
A despreading unit that despreads the received CDMA signal;
A channel estimation unit that performs first channel estimation to estimate fading characteristics using the pilot channel despread by the despreading unit, and outputs first channel estimation information;
Using the first channel estimation information, to compensate for information symbols of the despread traffic channel by said despreading section has a compensation unit for outputting a first compensation information symbols, a,
The channel estimation unit uses the pilot symbol located immediately before the information signal symbol does not overlap in time, or the pilot symbol temporally identical to the information symbol and the pilot symbol located immediately after the first pilot symbol. Perform channel estimation,
The channel estimation unit performs second channel estimation using the information channel despread by the despreading unit to obtain second channel estimation information,
The compensation unit, the compensation for the pilot symbols of the despread information channel by the despreading section, a case of using the first channel estimation information, and when using the second channel estimation information, in A reliability measuring unit that obtains reliability of the first channel estimation information and the second channel estimation information by executing each of the first channel estimation information and the first channel estimation information based on a reliability result of the reliability measurement unit; C DMA receiver you characterized in that the channel estimation information and compensating the second information symbol by selecting either the channel estimation information. The reliability measurement unit performs compensation for the pilot symbols of the information channel based on both channel estimation information of the first channel estimation information and the second channel estimation information, and after compensation based on the both channel estimation information 7. The CDMA receiver according to claim 6, wherein a reliability result is obtained by comparing an error between a pilot symbol and a known pilot symbol. The reliability measurement unit performs compensation for the pilot symbols of the information channel based on both channel estimation information of the first channel estimation information and the second channel estimation information, and after compensation based on the both channel estimation information 7. The CDMA receiver according to claim 6, wherein the reliability result is obtained by comparing the amplitude values of the pilot symbols. The compensation unit uses the second channel estimation information as a phase term used for compensation of an information symbol, uses the first channel estimation information as a compensation for an amplitude term, and uses an amplitude correction value to calculate the first phase term. 6. The CDMA receiver according to claim 5, wherein the amplitude of one compensation information symbol is corrected. The pilot symbol of the information channel is composed of a plurality of pilot symbols,
The channel estimation of the information channel is performed by performing channel estimation after averaging the plurality of pilot symbols, or performing channel estimation after performing channel estimation using each of the plurality of pilot symbols. The CDMA receiver according to 5 to 9. 10. The CDMA receiver according to claim 5, wherein the second channel estimation of the information channel is performed by averaging pilot symbols of the information channel over a plurality of slots. 10. The second channel estimation of the information channel performs channel estimation using pilot symbols including at least pilot symbols of the information channel positioned at both ends of the information symbol to be compensated. A CDMA receiver as described.

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