JP3658453B2 - Communications system - Google Patents

Description

ただし、ａは基地局２０ａが、「基地局２０ａは現在使用している周波数の信号（キャリア）上であって、現在使用している下り方向のＬＣＣＨが位置する通信チャネルの５ｍ秒ごとの上り方向のＬＣＣＨの受信が可能である」場合、つまり通信データと制御データを多重化せずに伝送する通常処理の場合の通話データの誤り率の基準値ＮＴＨである。
【００２１】
以下、図６を参照して通話データの誤り率の基準値ＮＴＨの変更手順を説明する。図６は、誤り率の基準値ＮＴＨを変更に関する処理を示すフローチャートである。
図６に示す、ステップ０１（Ｓ０１）において、基地局２０ａの制御回路２０８は、図５に示したように通信データと制御データを多重化して伝送するか否かを判断する。
多重化して伝送する場合にはＳ０２の処理に進み、多重化して伝送しない場合にはＳ０５の処理に進む。
【００２２】
ステップ０２（Ｓ０２）において、制御回路２０８は、通話データの誤り率の基準値ＮＴＨを変更する必要があるか否かを判断する。
通話データの誤り率の基準値ＮＴＨを変更する必要がある場合、Ｓ０４の処理に進み、変更する必要がない場合、Ｓ０３の処理に進む。
Ｓ０２の処理は、基準値ＮＴＨを変更しないと常に干渉回避処理が行われてしまう場合に、このような不具合を回避するための処理である。
【００２３】
ステップ０３（Ｓ０３）において、制御回路２０８は、通話データの誤り率の基準値ＮＴＨを変更するか否かを判断する。
通話データの基準値ＮＴＨを変更する場合、Ｓ０４の処理に進み、変更しない場合、Ｓ０５の処理に進む。
Ｓ０３の処理は、実効的な基準値ＮＴＨを一定にしたい場合の処理である。
ステップ０４（Ｓ０４）において、制御回路２０８は通話データの誤り率の基準値ＮＴＨを変更する処理を行う。
ステップ０５（Ｓ０５）において、制御回路２０８は通話データの誤り率の基準値ＮＴＨを変更しないで通話を行う場合の処理（通常処理）を行う。
【００２４】
以下、図７を参照して通話データの誤り率の基準値ＮＴＨの設定に係る基地局２０ａと端末局３０との間の信号シーケンスを説明する。図７は、図１に示した基地局２０ａと端末局３０との間の干渉回避動作における、ＲＣＲ ＳＴＤ−２８に規定された信号シーケンスを示す図である。
図７に示すように、シーケンス０１（ＳＱ１０）において、まず端末局３０（ＰＳ）から基地局２０ａ（ＣＳ）に対してＳＣＣＨ上に、リンクチャネル確立要求が通知される。このリンクチャネル確立要求には、エリア情報通知番号が含まれる。
このリンクチャネル確立要求において、端末局３０は、自己が保有するエリア情報通知状態番号を基地局２０ａに通知する。
この場合、初期状態（端末局３０に一番最初に電源が入った場合）および一斉呼出エリア移動が生じた場合、エリア情報通知状態は無効になるので、端末局３０はエリア情報保持なしとしてリンクチャネル確立（再）要求を送出する。
【００２５】
シーケンス０２（ＳＱ０２）において、基地局２０ａから端末局３０に対してＳＣＣＨ上に、リンクチャネル割当が通知される。リンクチャネル割当には、拡張ＬＣＨプロトコル種別（通知情報受信指示を含む）が含まれる。
このリンクチャネル割当において、基地局２０ａは端末局３０から受信したリンクチャネル確立（再）要求のエリア情報通知状態番号の値がエリア情報保持なしとなっているか、または、受信したエリア情報通知状態番号の値が、自己の保持しているエリア情報通知状態番号の値と異なる場合、拡張ＬＣＨプロトコル種別のビット３を通知情報受信指示有に設定したリンクチャネル割当メッセージを端末局３０に対して送出する。
【００２６】
シーケンス０３（ＳＱ０３）およびシーケンス０４（ＳＱ０４）において、基地局２０ａと端末局３０との間で同期バーストが送受信される。
シーケンス０５（ＳＱ０５）において、端末局３０から基地局２０ａに対してＦＡＣＣＨ／ＳＡＣＣＨ上にＳＡＢＭが送出される。
シーケンス０６（ＳＱ０６）において、基地局２０ａから端末局３０に対してＦＡＣＣＨ／ＳＡＣＣＨ上にＵＡが送出される。
シーケンス０７（ＳＱ０７）において、端末局３０から基地局２０ａに対してＦＡＣＣＨ／ＳＡＣＣＨ上にＣＣ呼設定が送出される。
シーケンス０８（ＳＱ０８）において、基地局２０ａから端末局３０に対してＦＡＣＣＨ／ＳＡＣＣＨ上にＣＣ呼設定受付が送出される。
【００２７】
シーケンス０９（ＳＱ０９）において、端末局３０から基地局２０ａに対してＦＡＣＣＨ／ＳＡＣＣＨ上にＲＴ定義情報要求が送出される。
ＲＴ定義情報要求には、定義情報種別およびエリア情報要求有が含まれる。基地局２０ａから通知情報受信指示有に設定されたリンクチャネル割当を受信した端末局３０は、定義情報種別のビット１をエリア情報要求有に設定した定義情報要求を送出してエリア情報を要求する。
シーケンス１０（ＳＱ１０）において、基地局２０ａから端末局３０に対してＦＡＣＣＨ／ＳＡＣＣＨ上にＲＴ定義情報応答が送出される。
ＲＴ定義情報応答には、エリア情報が含まれる。基地局２０ａからエリア情報要求有に設定した定義情報要求を受信した基地局２０ａは、エリア情報に通信データの誤り率の基準値ＮＴＨおよびエリア情報状態通知番号を含む定義情報応答を送出する。
【００２８】
シーケンス１１（ＳＱ１１）において、基地局２０ａから端末局３０に対してＦＡＣＣＨ／ＳＡＣＣＨ上にＲＴ機能要求が送出される。
シーケンス１２（ＳＱ１２）において、端末局３０から基地局２０ａに対してＦＡＣＣＨ／ＳＡＣＣＨ上にＲＴ機能要求応答が送出される。
以上の基地局２０ａと端末局３０との間の信号シーケンスにより、干渉回避動作が実行される。
【００２９】
以下、以上参照した各図を参照して通信システム１の動作を説明する。
端末局３０の利用者は、端末局３０のテンキー３１６に対して所定の発呼操作を行う。テンキー３１６に入力された情報は制御回路３０８に対して出力され、制御回路３０８は所定の発呼処理を行う。
つまり、制御回路３０８は端末局３０の各部分を制御して、基地局２０ａに対してオフフック情報およびダイヤル情報を制御データとして送出し、基地局２０ａはこれらの情報に基づいて、通信網１０、基地局２０ａおよび端末局３０の間に通話路を設定する。
マイク３１２から入力された端末局３０の利用者の音声は、通話回路３１０でディジタル形式の信号に変換され、信号Ｔとして送信回路３０６に対して出力される。
【００３０】
送信回路３０６は、制御回路３０８から入力される信号ＴＸＣのタイミングに従って、通話回路３１０から入力された通信データ（信号Ｔ）と通話回路３１０から入力された制御データとを図５に示したデータ伝送フォーマットで伝送する信号ＴＸＳを生成し、切り換えスイッチ３０２に対して出力する。
切り換えスイッチ３０２は、信号ＳＷＣを介した制御回路３０８の制御に従って、図５に示した各タイムスロットの第２の上り方向の通信チャネルのタイミングでアンテナ３００を介して無線通信回線上に出力する。
【００３１】
端末局３０からの無線通信回線上の信号は、基地局２０ａのアンテナ２００を介して切り換えスイッチ２０２に入力される。
切り換えスイッチ２０２は、信号ＳＷＣを介した制御回路２０８の制御に従って、受信した信号を図５に示した第２の上り方向の通信チャネルのタイミングで、信号ＳＷＳとして受信回路２０４に対して出力する。
【００３２】
受信回路２０４は、信号ＲＸＣを介した制御回路２０８の制御に従って、信号ＳＷＳから通信データを分離して回線インターフェース２１０に対して出力し、制御データを信号ＲＸＳとして制御回路２０８に入力する。
制御回路２０８は、受信回路２０４から入力される信号ＲＸＳ、および、回線インターフェース２１０から入力される信号ＮＩＳに基づいて、各制御信号ＲＸＣ，ＴＸＣ，ＳＷＣを介して基地局２０ａの各部分を制御し、端末局３０に対する誤り率（ＦＥＲ；Ｆｒｅｍｅ Ｅｒｒｏｒ Ｒａｔｅ）の基準値ＮＴＨ等を生成し、送信回路２０６、切り換えスイッチ２０２およびアンテナ２００を介して端末局３０に対して、図７を参照して上述した、制御信号を送出する周波数の無線通信回線上のＦＡＣＣＨ／ＳＡＣＣＨ上に送出する。制御回路２０８における誤り率の基準値ＮＴＨの算出処理は、図６を参照して上述した通りである。
【００３３】
回線インターフェース２１０は、信号Ｒを通信網１０に対して出力し、通信網１０からの通話信号を信号Ｔとして送信回路２０６に対して出力する。
また、回線インターフェース２１０は、通信網１０からの着信信号等の呼制御情報を検出し、信号ＮＩＳとして制御回路２０８に対して出力し、信号ＣＮＴＳとして制御回路２０８から入力された通信網１０に対する呼制御情報を通信網１０に対して出力する。
【００３４】
送信回路２０６は、制御回路２０８から入力される信号ＴＸＣのタイミングに従って、回線インターフェース２１０から入力された通信データ（信号Ｔ）と制御回路２０８から入力された制御データとを、図５に示したデータ伝送フォーマットで伝送する信号ＴＸＳを生成し、切り換えスイッチ２０２に対して出力する。
切り換えスイッチ２０２は、信号ＳＷＣを介した制御回路２０８の制御に従って、図５に示した各タイムスロットの第２の下り方向の通信チャネルのタイミングでアンテナ２００を介して無線通信回線上に出力する。
【００３５】
基地局２０ａのアンテナ２００から無線通信回線上を伝送された電波信号は、端末局３０のアンテナ３００により受信される。
切り換えスイッチ３０２は、信号ＳＷＣを介した制御回路３０８の制御に従って、アンテナ３００が捉えた信号を、図５に示した下り方向の第２の通信チャネルのタイミングで信号ＳＷＳとして受信回路３０４に対して出力する。
受信回路３０４は、信号ＲＸＣを介した制御回路３０８の制御に従って、信号ＳＷＳから通信データを分離して信号Ｔとして通話回路３１０に対して出力し、制御データを信号ＲＸＳとして制御回路２０８に入力する。通話回路３１０に入力された信号Ｔはアナログ形式の音声信号に変換され、スピーカ３１４を介して端末局３０の利用者に伝えられる。
また、受信回路３０４は、図５に示した下り方向の第２の通信チャネル上の通信データおよび制御データを全て通信データとして取り扱った場合に検出されるデータ誤りが発生するたびに信号ＲＸＳを介して誤りの発生を制御回路３０８に対して通知する。
【００３６】
制御回路３０８は、受信回路３０４から入力されたデータ誤りの数を計数し、８タイムスロットごとの誤り率（ＦＥＲ）を算出する。
８タイムスロットごとの誤り率が、端末局３０から入力された誤り率の基準値ＮＴＨ以下である場合、端末局３０は、そのまま通信網１０、基地局２０ａおよび端末局３０の間の通話路を保持し、誤り率が基準値ＮＴＨ以上である場合には、図７を参照して上述した干渉回避動作を行う。
以上説明した基地局２０ａ（端末局３０が基地局２０ｂの通話領域に入ってハンドオーバーが生じた場合には基地局２０ｂ）および端末局３０の動作は、端末局３０に対する終話操作（オフフック）または通信網１０からの終話処理が行われて通話路が切断するまで続く。
【００３７】
以上述べたように通信システム１を構成することにより、通信データと制御データとを同一の通信チャネルに多重化して伝送することができ、しかも、ＲＣＲＳＴＤ−２８の規格の範囲内の通信制御により、通信データと制御データとを同一の通信チャネルに多重化した場合に発生しうる不具合を回避することができる。
なお、通信システム１においては基地局２０ａ，２０ｂと端末局３０のみで通信システム１を構成したが、これらの数は任意である。
また、１フレームに含まれるタイムスロット数は任意である。
また、通信データと制御データとを多重化して伝送する場合において、制御データを伝送する通信チャネルは１通信チャネルに限らず、システムの構成に応じて、制御データを複数の通信チャネルを用いて伝送してもよい。
また、基地局２０ａ，２０ｂおよび端末局３０の構成は例示であって、これらの各構成要素は、同等の機能を有する他の回路等に置換可能である。
【００３８】
【実施例２】
以下、本発明の第２の実施例を説明する。
図８は、固定的にＬＣＣＨ用および通話用に割り当てる場合の通信チャネル制御方法を示す図である。
例えば、図８に示すように、４つの通信チャネル（通信チャネルコントローラ）ごとに固定的に、１つのＬＣＣＨコントローラおよび３つの通話チャネルコントローラを対応させ、第２の通信チャネルをＬＣＣＨとして固定的に用いて制御データの伝送を行うと、ＬＣＣＨ用に用いる通信チャネルを通話用に用いることができない。しかしながら、通話量が増大した場合、４つの通信チャネル中の１つがＬＣＣＨ専用に用いられたままとなるのは、非常に不便である。以下、第２の実施例として、必要に応じて、全ての通信チャネルを通話用に用いることができる通信チャネル制御方法を説明する。
【００３９】
図９は、任意の通信チャネルをＬＣＣＨ用および通話用に割り当てる場合の通信チャネル制御方法を示す図である。
かかる目的を達成するためには、図９に示すように、４つの通信チャネルそれぞれに１つずつ通話チャネルコントローラを対応させ、４つの通信チャネルに共通に１つのＬＣＣＨコントローラを対応させて、通信チャネルに対する制御を行う。このような通信チャネル制御を行うことにより、４つの通信チャネルを全て通話用に用いることができるようになる。ただし、図９に示したＬＣＣＨコントローラがＬＣＣＨを送出するスロットの位置は可変であり、各通信チャネルコントローラは、各通信チャネルをＬＣＣＨ用と通話用とに、タイムスロットごとに切り換える機能を有することが必要である。
【００４０】
以下、図１０〜図１２を参照して、図９に示した通信チャネル制御方法をさらに説明する。
図１０は、第２の通信チャネルをＬＣＣＨとして用いた場合の、無線通信回線の１タイムスロット分のデータ伝送フォーマットを例示する図である。なお、図１０に示した例においては、多重数は４で、上り通信チャネル〔端末局（ＰＳ）→基地局〕と下り通信チャネル（ＰＳ←基地局）とを合わせて、８つのスロットが１つのタイムスロットに含まれる。
【００４１】
図１０に示すように、第２世代コードレス電話システム（ＰＨＳ）においては、通信チャネルを介して、ＴＤＭＡ／ＴＤＤ(time domain multiple access / time domain duplex)方式を用いたディジタルデータ伝送が行われる。つまり、１つの通信チャネル（周波数）の１スロットをＬＣＣＨとして用い、同期データまたは制御データを、複数のタイムスロットを１単位として間欠的に端末局に対して伝送することにより、周波数資源の有効利用が図られている。
【００４２】
図１１は、無線通信回線の８タイムスロット（１フレーム）分のデータ伝送フォーマットを例示する図である。なお、図１１は、第２の通信チャネルをＬＣＣＨ用として用い、ＬＣＣＨの送出を８タイムスロットおきに行う場合（ｎ＝８）を示している。
例えば、図１１に示すように、ＬＣＣＨが８タイムスロットおきに間欠的に伝送されれる場合、第２の通信チャネル用のスロットは、８タイムスロット中、１タイムスロットだけＬＣＣＨの伝送に用いられ、その他の７タイムスロットにおいては何らのデータ伝送にも用いられていない。従って、その他の第２の通信チャネルのスロットは、通話データの伝送に用いることができることが分かる。
【００４３】
図１２は、図９に示した通信チャネル制御方式で、通話データおよび制御データを伝送する場合における、無線通信回線の８タイムスロット（１フレーム）分のデータ伝送フォーマットを例示する図である。なお、図１２は、第２の通信チャネルをＬＣＣＨ用として用い、ＬＣＣＨの送出を８タイムスロットおきに行う場合（ｎ＝８）を示している。
そこで、図１２に示すように、第２の通信チャネル用のスロットの８タイムスロット中、１タイムスロットだけＬＣＣＨの伝送に用い、その他の７タイムスロットを通話データの伝送に用いる。このように、同一の通信チャネルを、ＬＣＣＨ用と通話用とに共用することにより、全ての通信チャネルを通話ように用い得るようになる。
【００４４】
実際には、図９に示した通信チャネル制御を行う場合には、基地局から端末局に対して、ＢＣＣＨを介し、無線チャネル情報通知にて、「上りＬＣＣＨタイミング」を「ＣＳは、現在使用しているキャリア上であって、現在使用している下りＬＣＣＨの２．５ｍｓ後の上りスロットでのみ上りＬＣＣＨ受信が可能である」と指定する必要がある。
なお、端末局からの制御データを伝送する付随制御チャネル（ＡＣＣＨ）は、下りの場合、基地局は、ＡＣＣＨ送信のタイミングを知り得ない。従って、基地局は、端末局からのＡＣＣＨを１回で受信できない可能性が生じる。しかしながら、ＡＣＣＨには再送手順が用意されており、端末局と基地局との間のＡＣＣＨの伝送はこの再送により可能となる。
【００４５】
【発明の効果】
以上述べたように、本発明の通信システムによれば、パーソナルハンディホンシステムの基地局と端末局との間のデータの伝送において、通信チャネルの１つのみを用いて通話データおよび制御データの伝送を行うことができる。
また、本発明によれば、制御データの伝送に通信チャネルを１つ専用に用いる必要がないので、１つの無線通信回線で４つの通話を行うことができる。したがって、パーソナルハンディホンシステムの基地局と端末局との間のデータの伝送において、周波数資源を有効に活用することができる。
【図面の簡単な説明】
【図１】本発明の通信システムの構成を示す図である。
【図２】図１に示した基地局の構成を示す図である。
【図３】図１に示した端末局の構成を示す図である。
【図４】無線通信回線の１タイムスロット分のデータ伝送フォーマットを示す図である。
【図５】無線通信回線の８タイムスロット分のデータ伝送フォーマットを示す図である。
【図６】誤り率の基準値ＮＴＨを変更に関する処理を示すフローチャートである。
【図７】図１に示した基地局と端末局との間の干渉回避動作における、ＲＣＲ ＳＴＤ−２８に規定された信号シーケンスを示す図である。
【図８】固定的にＬＣＣＨ用および通話用に割り当てる場合の通信チャネル制御方法を示す図である。
【図９】任意の通信チャネルをＬＣＣＨ用および通話用に割り当てる場合の通信チャネル制御方法を示す図である。
【図１０】第２の通信チャネルをＬＣＣＨとして用いた場合の、無線通信回線の１タイムスロット分のデータ伝送フォーマットを例示する図である。
【図１１】無線通信回線の８タイムスロット（１フレーム）分のデータ伝送フォーマットを例示する図である。
【図１２】図９に示した通信チャネル制御方式で、通話データおよび制御データを伝送する場合における、無線通信回線の８タイムスロット（１フレーム）分のデータ伝送フォーマットを例示する図である。
【図１３】パーソナルハンディホンシステムの制御データの伝送フォーマットを示す図である。
【符号の説明】
１…通信システム、１０…通信網、２０ａ，２０ｂ…基地局、２００，３００…アンテナ、２０２，３０２…切り換えスイッチ，２０４，３０４…受信回路，２０６，３０６…送信回路、２０８，３０８…制御回路、３１６…テンキー、２１０…回線インターフェース、３１０…通話回路、３１２…マイク、３１４…スピーカ[0001]
[Industrial application fields]
The present invention relates to a communication system according to, for example, a personal handyphone system (PHS).
[0002]
[Prior art]
Currently, for example, “Personal Handyphone All (Supervision: Ministry of Posts and Telecommunications Bureau, Telecommunications Department, Business Policy Division, edited by: Telecommunications Business Policy Study Group, published by Create Cruise Co., Ltd., issued on December 10, 1993) Using a wireless terminal with a transmission output of 10 mW disclosed in the above, a number of base stations each having a communication area with a radius of several tens of meters are provided, and a call is made in a communication area covering a predetermined range (service area). Personal handyphones (PHS) that can be used are being studied.
[0003]
Hereinafter, data transmission between the base station and the terminal station will be described with reference to FIG. FIG. 13 is a diagram showing a control data transmission format of the personal handyphone system.
Data transmission between the base station and the terminal station of the personal handyphone system is performed according to the standard of “RCR STD-28”.
As shown in FIG. 13, the radio communication line is time-divided into time slots, and each time slot transmits data in the direction from the base station to the terminal station (CS → PS) in order to use the frequency effectively. And 4 communication channels in the downlink direction used for communication, and 4 communication channels in the uplink direction used for transmission of data from the terminal station to the base station (PS → CS) (4 bidirectional communication channels). It is divided.
[0004]
Control data including various control information and synchronization information between the base station and the terminal station is transmitted every 8 time slots. For example, as shown in FIGS. Only one of the eight downlink communication channels included is used as an LCCH for transmitting actual control data, and as shown in FIG. 13 (b), the other seven LCCHs in the downlink are actually Is not used to transmit control data.
Communication data that conveys the voice data of the call is transmitted between the base station and the terminal station using one of the remaining three communication channels (not shown in FIG. 13).
[0005]
[Problems to be solved by the invention]
In the data transmission of the personal handyphone system shown as the prior art, the communication channel used for actual control data transmission is 8 communication channels of 8 time slots, although one communication channel is dedicated to the LCCH. It is only one of them and it is very useless. The use of such a useless communication channel is contrary to the effective use of frequency resources.
However, when the control data and communication data are simply time-division multiplexed and transmitted via the same communication channel, the terminal station confuses the multiplexed control data and communication data, and increases the error rate of the communication data. It will be detected high by mistake.
[0006]
In such a case, the error rate of the communication data may exceed a certain reference value, and the terminal station that has mistakenly detected that the error rate of the communication data has exceeded the reference value may be another base station. Even though there is no need for processing (handover processing or interference avoidance operation) necessary for interference avoidance operation when radio signal interference occurs (handover is performed) I will go away.
When a handover or the like occurs unnecessarily, there is a problem that a call may be difficult.
[0007]
The present invention has been made in view of the above-described problems of the prior art. In the transmission of data between the base station and the terminal station of the personal handyphone system, the call data is transmitted using only one communication channel. An object of the present invention is to provide a communication system capable of transmitting control data.
Another object of the present invention is to provide a communication system that can effectively utilize frequency resources in data transmission between a base station and a terminal station of a personal handyphone system.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, a communication system of the present invention time-divides a wireless communication line into bidirectional communication channels, and transmits control data and predetermined communication data used for communication control via the communication channel to a base station. And the terminal station, wherein the control data and the communication data are time-division multiplexed at a predetermined rate and transmitted via the same communication channel, The station detects at least an error rate of the communication data, performs a predetermined response process to reduce the error rate only when the error rate exceeds a reference value transmitted from the base station, the base station, The terminal station corresponding to the ratio between the control data and the communication data is configured to transmit a reference value of an error rate of the communication data to be subjected to predetermined corresponding processing to the terminal station as the control data. That.
[0009]
[Action]
The base station multiplexes control data and communication data on the same communication channel, and transmits, as control data, a reference value that compensates for an error rate that occurs when all the data is handled as communication data to the terminal station.
The terminal station determines whether to perform processing such as handover and interference avoidance operation using the reference value transmitted from the base station, and prevents occurrence of unnecessary processing such as handover and interference avoidance operation.
[0010]
【Example】
[Example 1]
The first embodiment of the present invention will be described below.
First, the configuration of the communication system 1, the base station 20, and the terminal station 30 used in the personal handyphone system of the present invention will be described with reference to FIGS.
FIG. 1 is a diagram showing a configuration of a communication system 1 according to the present invention.
As shown in FIG. 1, the communication system 1 for the personal handyphone system includes a plurality of base stations 20 a and 20 b and a terminal station 30 connected to a communication network 10.
The communication network 10 is, for example, a general telephone communication network.
Each of the base stations 20a and 20b has a communication area with a radius of about several tens of meters, and these communication areas gather to form a predetermined area (service area).
The terminal station 30 performs a call with the communication network 10 or another terminal station (not shown) via a wireless communication line within the service area formed by the base stations 20a and 20b.
[0011]
FIG. 2 is a diagram illustrating the configuration of the base stations 20a and 20b illustrated in FIG.
Since the base stations 20a and 20b have the same configuration and the same operation, only the base station 20a will be described below.
As shown in FIG. 2, the base station 20a includes an antenna (ANT) 200, a changeover switch (SW) 202, a reception circuit (RX) 204, a transmission circuit (TX) 206, a control circuit (CNT) 208, and a line interface (NI). 210).
The base station 20a multiplexes control data and communication data on the same communication channel with the terminal station 30 and transmits the multiplexed data in both directions, setting a speech path between the communication network 10 and the terminal station 30, and voice. Transmit and receive signals.
The communication data is data such as voices of users of the base station 20a and the communication network 10, and the control data includes data related to communication control such as dial information or off-hook information from the base station 20a.
[0012]
FIG. 3 is a diagram showing the configuration of the terminal station 30 shown in FIG.
As shown in FIG. 3, an antenna (ANT) 300, a changeover switch (SW) 302, a reception circuit (RX) 304, a transmission circuit (TX) 306, a control circuit (CNT) 308, and a numeric keypad 316 connected to the control circuit 308 , A call circuit 310, and a microphone 312 and a speaker 314 connected to the call circuit 310.
[0013]
The terminal station 30 is, for example, a radio terminal dedicated to transmission, and is connected to the communication network 10 or another terminal station 30 (not shown) via a radio communication line within a service area formed by the base stations 20a and 20b. Make a call between. Further, the terminal station 30 detects an error rate of call data in the direction from the base station 20 to the terminal station 30 (downward direction), and this error rate is a radio communication at a frequency at which a control signal is transmitted from the base station 20a. When the reference value (NTH) transmitted on the FACCH / SACCH on the line is equal to or higher, the wireless communication line with the base station 20a is disconnected, for example, the communication line with the base station 20b is connected (handover) and interference Processing related to the avoidance operation is performed to enable a call while moving in the service area.
[0014]
Hereinafter, a data transmission format between the terminal station 30 and the base stations 20a and 20b will be described with reference to FIG. 4 and FIG.
FIG. 4 is a diagram showing a data transmission format for one time slot of a wireless communication line.
As shown in FIG. 4, the wireless communication line is divided into time slots, and each time slot is four communication channels (physical slots) from the base station 20a to the terminal station 30 (downward direction (CS → PS)). The terminal station 30 is time-divided into four communication channels (four bidirectional communication channels) in the direction of the base station 20a (upward direction (PS → CS)).
As shown in FIG. 4A, communication data and control data are transmitted using, for example, the second communication channel among these four bidirectional communication channels.
[0015]
FIG. 5 is a diagram showing a data transmission format for 8 time slots (1 frame) of a wireless communication line.
As shown in FIG. 5, communication data and control data are transmitted in units of communication channels of eight time slots, and only the second bidirectional communication channel of the first time slot of the eight time slots is control data. And the second bi-directional speech channel of the other seven time slots is used for transmission of communication data.
That is, as shown in FIG. 5A, the second downlink communication channel in the first time slot is used for transmission of control data from the base station 20a to the terminal station 30, and is shown in FIG. 5B. As shown in FIGS. 5C and 5D, the second uplink communication channel of the first time slot is used for transmission of control data from the terminal station 30 to the base station 20a. A bi-directional call channel with seven time slots is used for bi-directional transmission of communication data.
[0016]
When a wireless communication line is used as shown in FIG. 5, a signal (carrier) of a frequency currently used by the terminal station 30 in the downlink BCCH radio information notification between the base station 20a and the terminal station 30. The terminal station 30 can receive only the LCCH data of only the second communication channel in the uplink direction 2.5 ms after the LCCH on the second communication channel in the downlink direction that is currently used. Notify that.
Receiving this notification, the terminal station 30 transmits the uplink LCCH in that frequency after 2.5 seconds (to the uplink second communication channel of the time slot).
[0017]
In such a case, when the reference value NTH of the communication data error rate is set in the terminal station 30 as having 240 / n (n = 8) or more communication data errors in 8 time slots, for example. The terminal station 30 regards all the data in the second communication channel in the downlink direction of each time slot as communication data, even though the data in the first time slot shown in FIG. Therefore, an interference avoiding operation is always performed, and a call using the terminal station 30 cannot be normally performed.
Even when the interference avoiding operation or the like is not always performed, the interference avoiding operation is started even when the substantial error rate is sufficiently low and there is no problem with the call.
[0018]
In order to avoid such a problem, the terminal station 30 sets an error rate reference value NTH so that the base station 20a performs an interference avoiding operation only when the error rate becomes substantially the same or higher. There is a need to.
In order to set such a reference value NTH, the base station 20a uses the currently used frequency signal (carrier) on the signal (carrier) currently used by the terminal station 30 in the downlink BCCH radio information notification. 6 that the terminal station 30 can receive only the LCCH data of only the second communication channel in the uplink direction 2.5 ms after the LCCH on the second communication channel in the downlink direction. , The error rate reference value NTH of the terminal station 30 and the value of the area information notification state number are changed in the area information described later.
[0019]
Further, the base station 20a gives a notification information reception instruction to the terminal station 30 that multiplexes and transmits the call data and the control data as shown in FIG. 5 by link channel assignment to be described later with reference to FIG. Validate and receive the reference value NTH of the error rate of the call data for link switching.
Note that the reference value NTH (channel switching FER threshold) of the error rate of the call data is defined for each frame (240 frames) included in 1.2 seconds, so 240 / n frames out of 240 frames. Will always be mistaken as communication data. Accordingly, the reference value NTH for the error rate of the call data when the communication data and control data described above are multiplexed and transmitted is calculated by the following equation.
For example, in the case shown in FIG. 5, one frame is composed of 8 time slots (n = 8; interval value).
[0020]
[Expression 1]

However, a indicates that the base station 20a indicates that “the base station 20a is on a signal (carrier) having a frequency currently used, and that the communication channel on which the currently used downlink LCCH is located is every 5 msec. This is the reference value NTH for the error rate of speech data in the case of normal processing in which communication data and control data are transmitted without being multiplexed.
[0021]
Hereinafter, the procedure for changing the reference value NTH of the error rate of the call data will be described with reference to FIG. FIG. 6 is a flowchart showing a process related to changing the error rate reference value NTH.
In step 01 (S01) shown in FIG. 6, the control circuit 208 of the base station 20a determines whether or not the communication data and the control data are multiplexed and transmitted as shown in FIG.
If multiplexed and transmitted, the process proceeds to S02. If not multiplexed and transmitted, the process proceeds to S05.
[0022]
In step 02 (S02), the control circuit 208 determines whether or not the call data error rate reference value NTH needs to be changed.
If it is necessary to change the reference value NTH of the error rate of the call data, the process proceeds to S04, and if there is no need to change, the process proceeds to S03.
The process of S02 is a process for avoiding such a problem when the interference avoidance process is always performed unless the reference value NTH is changed.
[0023]
In step 03 (S03), the control circuit 208 determines whether or not to change the reference value NTH for the error rate of the call data.
If the reference value NTH of the call data is changed, the process proceeds to S04, and if not changed, the process proceeds to S05.
The process of S03 is a process for making the effective reference value NTH constant.
In step 04 (S04), the control circuit 208 performs processing for changing the reference value NTH of the error rate of the call data.
In step 05 (S05), the control circuit 208 performs a process (normal process) when a call is made without changing the reference value NTH of the error rate of the call data.
[0024]
Hereinafter, a signal sequence between the base station 20a and the terminal station 30 relating to the setting of the reference value NTH for the error rate of the call data will be described with reference to FIG. FIG. 7 is a diagram showing a signal sequence defined in RCR STD-28 in the interference avoiding operation between the base station 20a and the terminal station 30 shown in FIG.
As shown in FIG. 7, in sequence 01 (SQ10), first, the terminal station 30 (PS) notifies the base station 20a (CS) of a link channel establishment request on the SCCH. This link channel establishment request includes an area information notification number.
In this link channel establishment request, the terminal station 30 notifies the base station 20a of the area information notification state number held by itself.
In this case, when the initial state (when the terminal station 30 is powered on for the first time) and when the paging area movement occurs, the area information notification state becomes invalid, and the terminal station 30 is linked without holding the area information. Send a channel establishment (re) request.
[0025]
In sequence 02 (SQ02), the base station 20a notifies the terminal station 30 of the link channel assignment on the SCCH. The link channel assignment includes an extended LCH protocol type (including a notification information reception instruction).
In this link channel allocation, the base station 20a determines that the value of the area information notification state number of the link channel establishment (re-) request received from the terminal station 30 is not holding area information or the received area information notification state number. Is different from the value of the area information notification state number held by itself, a link channel assignment message in which bit 3 of the extended LCH protocol type is set to have notification information reception instruction is sent to the terminal station 30 .
[0026]
In sequence 03 (SQ03) and sequence 04 (SQ04), a synchronization burst is transmitted and received between the base station 20a and the terminal station 30.
In sequence 05 (SQ05), the terminal station 30 transmits the SABM on the FACCH / SACCH to the base station 20a.
In sequence 06 (SQ06), UA is transmitted from the base station 20a to the terminal station 30 on the FACCH / SACCH.
In sequence 07 (SQ07), the CC call setup is transmitted from the terminal station 30 to the base station 20a on the FACCH / SACCH.
In sequence 08 (SQ08), a CC call setup acceptance is transmitted from the base station 20a to the terminal station 30 on the FACCH / SACCH.
[0027]
In sequence 09 (SQ09), an RT definition information request is transmitted from the terminal station 30 to the base station 20a on the FACCH / SACCH.
The RT definition information request includes a definition information type and area information requested. The terminal station 30 that has received the link channel assignment set with the notification information reception instruction from the base station 20a sends a definition information request with the bit 1 of the definition information type set to area information request and requests area information. .
In sequence 10 (SQ10), the base station 20a sends an RT definition information response to the terminal station 30 on the FACCH / SACCH.
The RT definition information response includes area information. The base station 20a that has received the definition information request set to have the area information request from the base station 20a transmits a definition information response including the communication data error rate reference value NTH and the area information state notification number in the area information.
[0028]
In the sequence 11 (SQ11), the RT function request is transmitted from the base station 20a to the terminal station 30 on the FACCH / SACCH.
In sequence 12 (SQ12), the RT function request response is transmitted from the terminal station 30 to the base station 20a on the FACCH / SACCH.
The interference avoiding operation is executed by the signal sequence between the base station 20a and the terminal station 30 described above.
[0029]
Hereinafter, the operation of the communication system 1 will be described with reference to the drawings referred to above.
A user of the terminal station 30 performs a predetermined call operation on the numeric keypad 316 of the terminal station 30. Information input to the numeric keypad 316 is output to the control circuit 308, and the control circuit 308 performs predetermined call processing.
That is, the control circuit 308 controls each part of the terminal station 30, and sends off-hook information and dial information as control data to the base station 20a. The base station 20a, based on the information, A speech path is set between the base station 20a and the terminal station 30.
The voice of the user of the terminal station 30 input from the microphone 312 is converted into a digital signal by the call circuit 310 and output to the transmission circuit 306 as a signal T.
[0030]
The transmission circuit 306 transmits the communication data (signal T) input from the call circuit 310 and the control data input from the call circuit 310 according to the timing of the signal TXC input from the control circuit 308 in the data transmission shown in FIG. A signal TXS to be transmitted in the format is generated and output to the changeover switch 302.
The changeover switch 302 outputs to the wireless communication line via the antenna 300 at the timing of the second upstream communication channel of each time slot shown in FIG. 5 according to the control of the control circuit 308 via the signal SWC.
[0031]
A signal on the wireless communication line from the terminal station 30 is input to the changeover switch 202 via the antenna 200 of the base station 20a.
The changeover switch 202 outputs the received signal to the receiving circuit 204 as the signal SWS at the timing of the second uplink communication channel shown in FIG. 5 according to the control of the control circuit 208 via the signal SWC.
[0032]
The receiving circuit 204 separates the communication data from the signal SWS and outputs it to the line interface 210 according to the control of the control circuit 208 via the signal RXC, and inputs the control data to the control circuit 208 as the signal RXS.
The control circuit 208 controls each part of the base station 20a via the control signals RXC, TXC, SWC based on the signal RXS input from the reception circuit 204 and the signal NIS input from the line interface 210. A reference value NTH or the like of an error rate (FER) for the terminal station 30 is generated, and the terminal station 30 is transmitted to the terminal station 30 via the transmission circuit 206, the changeover switch 202, and the antenna 200 with reference to FIG. The control signal is transmitted on the FACCH / SACCH on the radio communication line having the frequency for transmitting the control signal. The calculation process of the error rate reference value NTH in the control circuit 208 is as described above with reference to FIG.
[0033]
The line interface 210 outputs a signal R to the communication network 10, and outputs a call signal from the communication network 10 as a signal T to the transmission circuit 206.
The line interface 210 detects call control information such as an incoming signal from the communication network 10, outputs the call control information to the control circuit 208 as the signal NIS, and calls the communication network 10 input from the control circuit 208 as the signal CNTS. Control information is output to the communication network 10.
[0034]
The transmission circuit 206 converts the communication data (signal T) input from the line interface 210 and the control data input from the control circuit 208 into the data shown in FIG. 5 according to the timing of the signal TXC input from the control circuit 208. A signal TXS to be transmitted in the transmission format is generated and output to the changeover switch 202.
The changeover switch 202 outputs to the wireless communication line via the antenna 200 at the timing of the second downlink communication channel of each time slot shown in FIG. 5 according to the control of the control circuit 208 via the signal SWC.
[0035]
A radio wave signal transmitted from the antenna 200 of the base station 20 a on the wireless communication line is received by the antenna 300 of the terminal station 30.
The changeover switch 302 transmits the signal captured by the antenna 300 to the reception circuit 304 as the signal SWS at the timing of the second communication channel in the downlink direction shown in FIG. 5 according to the control of the control circuit 308 via the signal SWC. Output.
The receiving circuit 304 separates the communication data from the signal SWS and outputs it as the signal T to the call circuit 310 according to the control of the control circuit 308 via the signal RXC, and inputs the control data to the control circuit 208 as the signal RXS. . The signal T input to the call circuit 310 is converted into an analog audio signal and transmitted to the user of the terminal station 30 via the speaker 314.
In addition, the reception circuit 304 receives a signal RXS every time a data error is detected when the communication data and control data on the second communication channel in the downlink direction shown in FIG. 5 are all handled as communication data. The occurrence of an error is notified to the control circuit 308.
[0036]
The control circuit 308 counts the number of data errors input from the receiving circuit 304, and calculates an error rate (FER) every 8 time slots.
When the error rate for every 8 time slots is equal to or less than the reference value NTH of the error rate input from the terminal station 30, the terminal station 30 uses the communication path between the communication network 10, the base station 20a, and the terminal station 30 as it is. If the error rate is equal to or higher than the reference value NTH, the interference avoidance operation described above with reference to FIG. 7 is performed.
The operations of the base station 20a (the base station 20b when the terminal station 30 enters the call area of the base station 20b and a handover occurs) and the operation of the terminal station 30 are as described above. Or it continues until the call termination process from the communication network 10 is performed and the communication path is disconnected.
[0037]
By configuring the communication system 1 as described above, communication data and control data can be multiplexed and transmitted on the same communication channel, and further, by communication control within the range of the RCRSTD-28 standard, Problems that may occur when communication data and control data are multiplexed on the same communication channel can be avoided.
In the communication system 1, the communication system 1 is configured by only the base stations 20a and 20b and the terminal station 30, but these numbers are arbitrary.
Further, the number of time slots included in one frame is arbitrary.
In addition, when communication data and control data are multiplexed and transmitted, the communication channel for transmitting control data is not limited to one communication channel, and control data is transmitted using a plurality of communication channels according to the system configuration. May be.
The configurations of the base stations 20a and 20b and the terminal station 30 are merely examples, and each of these components can be replaced with other circuits having equivalent functions.
[0038]
[Example 2]
The second embodiment of the present invention will be described below.
FIG. 8 is a diagram illustrating a communication channel control method in a case where fixed allocation is performed for LCCHs and calls.
For example, as shown in FIG. 8, one LCCH controller and three speech channel controllers are fixedly associated with each of four communication channels (communication channel controllers), and the second communication channel is fixedly used as the LCCH. If the control data is transmitted, the communication channel used for the LCCH cannot be used for a call. However, when the call volume increases, it is very inconvenient for one of the four communication channels to remain dedicated to the LCCH. Hereinafter, as a second embodiment, a communication channel control method in which all communication channels can be used for calls as necessary is described.
[0039]
FIG. 9 is a diagram showing a communication channel control method in the case where an arbitrary communication channel is allocated for LCCH and call.
In order to achieve such an object, as shown in FIG. 9, one communication channel controller is associated with each of the four communication channels, and one LCCH controller is associated with each of the four communication channels. Control over. By performing such communication channel control, all four communication channels can be used for a call. However, the position of the slot in which the LCCH controller shown in FIG. 9 transmits the LCCH is variable, and each communication channel controller may have a function of switching each communication channel for each LCCH and for each call. is necessary.
[0040]
Hereinafter, the communication channel control method shown in FIG. 9 will be further described with reference to FIGS.
FIG. 10 is a diagram illustrating a data transmission format for one time slot of a wireless communication line when the second communication channel is used as an LCCH. In the example shown in FIG. 10, the number of multiplexing is 4, and 8 slots are 1 in total including the uplink communication channel (terminal station (PS) → base station) and the downlink communication channel (PS ← base station). Included in one time slot.
[0041]
As shown in FIG. 10, in the second generation cordless telephone system (PHS), digital data transmission using a TDMA / TDD (time domain multiple access / time domain duplex) system is performed via a communication channel. In other words, one slot of one communication channel (frequency) is used as an LCCH, and synchronization data or control data is intermittently transmitted to a terminal station as a unit of a plurality of time slots, thereby effectively using frequency resources. Is planned.
[0042]
FIG. 11 is a diagram illustrating a data transmission format for 8 time slots (1 frame) of a wireless communication line. FIG. 11 shows a case where the second communication channel is used for LCCH and LCCH is transmitted every 8 time slots (n = 8).
For example, as shown in FIG. 11, when the LCCH is transmitted intermittently every 8 time slots, the slot for the second communication channel is used for transmission of the LCCH only for 1 time slot in the 8 time slots. The other 7 time slots are not used for any data transmission. Therefore, it can be seen that the slot of the other second communication channel can be used for transmission of call data.
[0043]
FIG. 12 is a diagram illustrating a data transmission format for 8 time slots (1 frame) of a wireless communication line in the case of transmitting call data and control data using the communication channel control method shown in FIG. FIG. 12 shows a case where the second communication channel is used for LCCH and LCCH is transmitted every 8 time slots (n = 8).
Therefore, as shown in FIG. 12, among the 8 time slots of the slot for the second communication channel, only 1 time slot is used for LCCH transmission, and the other 7 time slots are used for transmission of call data. Thus, by sharing the same communication channel for LCCH and for calling, all the communication channels can be used for calling.
[0044]
Actually, when the communication channel control shown in FIG. 9 is performed, the “uplink LCCH timing” is set to “CS is currently used by the radio channel information notification from the base station to the terminal station via the BCCH. It is necessary to specify that the uplink LCCH can be received only in the uplink slot 2.5 ms after the currently used downlink LCCH.
When the associated control channel (ACCH) for transmitting control data from the terminal station is down, the base station cannot know the timing of ACCH transmission. Therefore, there is a possibility that the base station cannot receive the ACCH from the terminal station at one time. However, a retransmission procedure is prepared for the ACCH, and transmission of the ACCH between the terminal station and the base station becomes possible by this retransmission.
[0045]
【The invention's effect】
As described above, according to the communication system of the present invention, in the transmission of data between the base station and the terminal station of the personal handyphone system, the transmission of the call data and the control data using only one communication channel. It can be performed.
Further, according to the present invention, it is not necessary to use one communication channel exclusively for transmission of control data, so that four calls can be performed on one wireless communication line. Therefore, frequency resources can be effectively used in data transmission between the base station and the terminal station of the personal handyphone system.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a communication system according to the present invention.
2 is a diagram showing a configuration of a base station shown in FIG.
3 is a diagram showing a configuration of a terminal station shown in FIG.
FIG. 4 is a diagram illustrating a data transmission format for one time slot of a wireless communication line.
FIG. 5 is a diagram showing a data transmission format for 8 time slots of a wireless communication line.
FIG. 6 is a flowchart showing processing related to changing an error rate reference value NTH;
7 is a diagram showing a signal sequence defined in RCR STD-28 in the interference avoidance operation between the base station and the terminal station shown in FIG. 1;
FIG. 8 is a diagram illustrating a communication channel control method in a case where fixed allocation is performed for LCCHs and calls.
FIG. 9 is a diagram showing a communication channel control method when an arbitrary communication channel is assigned for LCCH and for a call.
FIG. 10 is a diagram illustrating a data transmission format for one time slot of a wireless communication line when a second communication channel is used as an LCCH.
FIG. 11 is a diagram illustrating a data transmission format for 8 time slots (1 frame) of a wireless communication line;
12 is a diagram exemplifying a data transmission format for 8 time slots (1 frame) of a wireless communication line in a case where call data and control data are transmitted by the communication channel control method shown in FIG. 9;
FIG. 13 is a diagram showing a control data transmission format of the personal handyphone system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Communication system, 10 ... Communication network, 20a, 20b ... Base station, 200, 300 ... Antenna, 202, 302 ... Changeover switch, 204, 304 ... Reception circuit, 206, 306 ... Transmission circuit, 208, 308 ... Control circuit 316: Numeric keypad, 210: Line interface, 310 ... Call circuit, 312 ... Microphone, 314 ... Speaker

Claims (2)

A communication system in which a wireless communication line is time-divided into bidirectional communication channels, and control data used for communication control and predetermined communication data are transmitted bidirectionally between a base station and a terminal station via the communication channel. There,
The control data and the communication data are time-division multiplexed at a predetermined rate and transmitted through the same communication channel,
The terminal station detects at least an error rate of the communication data, performs a predetermined response process to reduce the error rate only when the error rate exceeds a reference value transmitted from the base station,
The base station transmits to the terminal station, as the control data, the reference value of the error rate of the communication data that the terminal station corresponding to the ratio of the control data and the communication data should perform a predetermined corresponding process. A communication system configured as described above. The communication system according to claim 1, wherein the control data is transmitted in a time-division multiplexed manner with the communication data intermittently for each of a plurality of time slots of an arbitrary communication channel.

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