JP3970614B2 - Wireless system and wireless slave unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable radio slave machines to save electric power of one's own station. <P>SOLUTION: This radio system is composed of a radio master machine, and a plurality of radio slave machines. The radio master machine has a slave machine storage part for storing order of the radio slave machines at simultaneous communication mode time for communicating in predetermined order with the radio slave machines, and a calling-out signal transmitting part for transmitting a calling-out signal including a command for indicating a simultaneous communication mode in the simultaneous communication mode. The radio slave machines have an order storage part 221 for storing order of one's own station at simultaneous communication mode time, an intermittent carrier sense part 212 for intermittently detecting a calling-out signal, and a carrier sense control part 241 for prohibiting detection by the intermittent carrier sense part 212 for a prescribed time determined on the basis of the order of one's own station stored in the order storage part 221 when including the command for indicating the simultaneous communication mode in the detected calling-out signal. <P>COPYRIGHT: (C)2003,JPO

Description

【００６５】
端末識別符号５３３は、１２桁の無線子機の呼出ＩＤの下４桁をＲＣＲ２進数に変換した１６ビット（＝４ビット×４桁）の符号である。呼出信号５００を受信した無線子機２００は、自局が記憶している自局の呼出ＩＤの下４桁と、受信した呼出信号５００に含まれる端末識別符号５３３とを比較することにより、受信した呼出信号５００が自局に対して送信された呼出信号であるかを概略的に判断する。
【００６６】
情報部５５０は、呼出信号５００を送信している無線親機１００を特定する自局呼出ＩＤ５５１と、呼出信号５００を受信する無線子機２００を特定する相手局呼出ＩＤ５５２と、無線親機１００から無線子機２００に渡されるデータ５５３とを含む。
【００６７】
自局呼出ＩＤ５５１は、呼出信号５００を送信した自局である無線親機１００を特定する１２桁の番号をＲＣＲ２進数に変換した４８ビットの符号である。
【００６８】
相手局呼出ＩＤ５５２は、呼出信号５００の相手局である無線子機２００を特定する１２桁の番号をＲＣＲ２進数に変換した４８ビットの符号である。
【００６９】
図７は、第１の実施の形態における一斉検針モード時に無線親機１００から送信される呼出信号５００に含まれ繰返し送信される接続要求信号５２０のパケット５３０の第１の構成を示す図である。図７を参照して、パケット５３０Ａは、同期信号５３１と、グループ識別符号５３２と、端末識別符号５３３と、一斉検針コマンド５４１と、一斉検針の台数を示す符号５４２とを含む。
【００７０】
一斉検針コマンド５４１は、無線子機２００と予め決められた順番で通信する一斉通信モードを示す４ビットのコマンドである。呼出信号５００を受信した無線子機２００は、グループ識別符号５３２および端末識別符号５３３により、受信した呼出信号５００が自局が属する無線親機１００から自局に対して送信された呼出信号５００であると概略的に判断し、さらに、一斉検針コマンド５４１を検出した場合は、一斉検針に対応した動作を行なう。具体的には、無線子機２００は、順番記憶部２２１に記憶された自局の順番に基づき、一斉検針コマンド５４１を受信してから自局の検針が開始されるまでの時間、間欠キャリアセンスを停止し、自局の検針の呼出信号が送信される時に間欠キャリアセンスを再開する。一斉検針コマンド５４１は、ＲＣＲ２進数で使用されない４ビットの符号、たとえば、「００００」、「０００１」、「００１０」、「１１０１」、「１１１０」および「１１１１」のうちの１つである「０００１」で示される。
【００７１】
一斉検針の台数を示す符号５４２は、一斉検針を行なう無線子機２００の台数をＲＣＲ２進数に変換した１２ビット（＝４ビット×３桁）の符号である。呼出信号５００を受信した無線子機２００は、グループ識別符号５３２および端末識別符号５３３により、受信した呼出信号５００が自局が属する無線親機１００から自局に対して送信された呼出信号５００であると概略的に判断し、さらに、一斉検針コマンド５４１を検出した場合は、順番記憶部２２１に記憶された自局の順番と一斉検針の台数とに基づき、自局の検針が終了してから最後の無線子機の検針が終了するまでの時間、間欠キャリアセンスを停止し、最後の無線子機の検針が終了する時に間欠キャリアセンスを再開する。
【００７２】
図７で説明した一斉検針コマンド５４１と一斉検針を行なう無線子機２００の台数を示す符号５４２は、後述する図８および図９で示す構成で、呼出信号５００のパケット５３０に含まれてもよい。
【００７３】
図８は、第１の実施の形態における一斉検針モード時に無線親機１００から送信される呼出信号５００に含まれ繰返し送信される接続要求信号５２０のパケット５３０の第２の構成を示す図である。図８を参照して、パケット５３０Ｂは、同期信号５３１と、グループ識別符号５３２と、一斉検針コマンド５４１と、一斉検針の台数を示す符号５４２とを含む。
【００７４】
同期信号５３１は、無線子機２００との同期をとるための１７ビットの信号である。
【００７５】
グループ識別符号５３２は、１２桁の無線親機１００の呼出ＩＤの下４桁をＲＣＲ２進数に変換した１６ビット（＝４ビット×４桁）の符号である。
【００７６】
一斉検針コマンド５４１は、無線子機２００と予め決められた順番で通信する一斉通信モードを示す４ビットのコマンドである。
【００７７】
一斉検針の台数を示す符号５４２は、一斉検針を行なう無線子機２００の台数をＲＣＲ２進数に変換した１２ビット（＝４ビット×３桁）の符号である。
【００７８】
同期信号５３１と、グループ識別符号５３４と、一斉検針コマンド５４１と、一斉検針の台数を示す符号５４２との作用については、図７で説明した通りである。
【００７９】
図９は、第１の実施の形態における一斉検針モード時に無線親機１００から送信される呼出信号５００に含まれ繰返し送信される接続要求信号５２０のパケット５３０の第３の構成を示す図である。図９を参照して、パケット５３０Ｃは、同期信号５３１と、グループ識別符号５３４と、一斉検針コマンド５４１と一斉検針の台数を示す符号５４３とを含む。
【００８０】
同期信号５３１は、無線子機２００との同期をとるための１７ビットの信号である。
【００８１】
グループ識別符号５３４は、１２桁の無線親機１００の呼出ＩＤの下３桁をＲＣＲ２進数に変換した１２ビット（＝４ビット×３桁）の符号である。
【００８２】
一斉検針コマンド５４１は、無線子機２００と予め決められた順番で通信する一斉通信モードを示す４ビットのコマンドである。
【００８３】
一斉検針の台数を示す符号５４３は、一斉検針を行なう無線子機２００の台数をＲＣＲ２進数に変換した１６ビット（＝４ビット×４桁）の符号である。
【００８４】
同期信号５３１と、グループ識別符号５３４と、一斉検針コマンド５４１と、一斉検針の台数を示す符号５４３との作用については、図７で説明した通りである。
【００８５】
図１０は、第１の実施の形態における無線親機１００の送受信の時間的な流れおよび無線子機２００の送受信とキャリアセンスとの時間的な流れの一例を示すタイムチャートである。ここでは、無線親機１００と、一斉検針の順番が１番目の無線子機２００ａと、一斉検針の順番がｍ番目の無線子機２００ｍと、一斉検針の順番が最後であるｎ番目の無線子機２００ｎとの送受信の時間的な流れを説明する。また、無線親機１００が送信する呼出信号の間隔は９０秒とし、無線親機が呼出信号を送信してから、無線子機が検針データを応答して、無線親機が終了信号を送信するまでの時間は６０秒とする。図１０を参照して、
（１）無線子機２００ａ，２００ｍ，２００ｎは、間欠キャリアセンスを行なっている。
【００８６】
（２）無線親機１００は、呼出信号（一斉通信）５００を送信する。
（３）無線子機２００ａ，２００ｍ，２００ｎは呼出信号（一斉通信）５００を間欠キャリアセンスで検知する。
【００８７】
（４）無線子機２００ａは、自局の順番が１番目であるので、呼出信号（一斉検針）５００を検知してから自局の検針が開始されるまでの９０×１秒間、間欠キャリアセンスを停止する。
【００８８】
（５）無線子機２００ｍは、自局の順番がｍ番目であるので、呼出信号（一斉検針）５００を検知してから自局の検針が開始されるまでの９０×ｍ秒間、間欠キャリアセンスを停止する。
【００８９】
（６）無線子機２００ｎは、自局の順番がｎ番目であるので、呼出信号（一斉検針）５００を検知してから自局の検針が開始されるまでの９０×ｎ秒間、間欠キャリアセンスを停止する。
【００９０】
（７）無線親機１００は、呼出信号（１台目）５０１を送信する。
（８）無線子機２００ａは、間欠キャリアセンスを再開し、呼出信号（１台目）５０１を検知する。
【００９１】
（９）中略
（１０）無線親機１００は、終了信号（ｍ−１台目）７０１を送信する。
【００９２】
（１１）無線親機１００は、呼出信号（ｍ台目）５０２を送信する。
（１２）無線子機２００ｍは、間欠キャリアセンスを再開し、呼出信号（ｍ台目）５０２を検知する。
【００９３】
（１３）無線子機２００ｍは、検針データを含む応答信号６０２を送信する。
（１４）無線親機１００は、応答信号６０２を受信する。
【００９４】
（１５）無線親機１００は、終了信号７０２を送信する。
（１６）無線子機２００ｍは、終了信号７０２を受信する。
【００９５】
（１７）無線子機２００ｍは、最後の無線子機２００ｎの検針が終了するまでの９０×（ｎ−ｍ）秒間、間欠キャリアセンスを停止する。
【００９６】
（１８）無線親機１００は、呼出信号（ｍ＋１台目）５０３を送信する。
（１９）中略
（２０）無線親機１００は、呼出信号（ｎ台目）５０４を送信する。
【００９７】
（２１）無線子機２００ｎは、間欠キャリアセンスを再開し、呼出信号（ｎ台目）５０４を検知する。
【００９８】
（２２）無線子機２００ｎは、検針データを含む応答信号６０４を送信する。
（２３）無線親機１００は、応答信号６０４を受信する。
【００９９】
（２４）無線親機１００は、終了信号７０４を送信する。
（２５）無線子機２００ｎは、終了信号７０４を受信する。
【０１００】
（２６）無線子機２００ａ，２００ｍ，２００ｎは、間欠キャリアセンスを再開する。
【０１０１】
以上、説明したように、第１の実施の形態における無線テレメータシステムでは、無線親機１００は、無線子機２００と予め決められた順番で通信する一斉検針モード時の無線子機の順番を記憶し、一斉検針モードの場合、一斉検針モードを示すコマンドを含む呼出信号５００を送信する。また、無線子機２００は、一斉検針モード時の自局の順番を記憶し、間欠的に呼出信号５００を検知し、検知された呼出信号５００に一斉検針モードを示すコマンドが含まれる場合、記憶された自局の順番に基づき求められる所定の時間、間欠キャリアセンスを停止する。
【０１０２】
このため、無線テレメータシステムの無線子機は、自局の順番以外は、間欠キャリアセンスを停止することができる。その結果、無線テレメータシステムにおいて、無線子機が自局の省電力を図ることができる。
【０１０３】
また、無線親機１００は、一斉通信モード時の無線子機２００の順番を無線子機２００に送信する。そして、無線子機２００は、一斉通信モード時の自局の順番を無線親機１００から受信する。
【０１０４】
このため、無線親機は、無線親機１００で設定された無線子機２００の順番を無線子機２００に通知することができる。その結果、無線子機の順番の整合性を良くすることができる。
【０１０５】
なお、第１の実施の形態においては、無線テレメータシステムにおける無線システムについて説明したが、図７〜図９で説明したパケット５３０Ａ〜５３０Ｃのいずれかを含む呼出信号５００を送信する無線親機１００、および、図７〜図９で説明したパケット５３０Ａ〜５３０Ｃを含む呼出信号５００を受信して、自局の順番以外は間欠キャリアセンスを停止する無線子機２００として発明を捕らえることができる。
【０１０６】
［第２の実施の形態］
続いて、本実施の形態における第２の実施の形態について説明する。
【０１０７】
本発明の第２の実施の形態の１つにおける無線テレメータシステムの構成の概略は、図１に示した、第１の実施の形態の１つにおける無線テレメータシステムの構成の概略と同様である。
【０１０８】
第２の実施の形態における無線親機１００の構成は、図２で示した第１の実施の形態における無線親機１００の構成と同様である。
【０１０９】
第２の実施の形態における無線子機２００の構成は、図３で示した第１の実施の形態における無線子機２００の構成と同様である。
【０１１０】
第２の実施の形態における無線親機１００の制御部１４０と記憶部１２０との機能の概略は、図４で示した第１の実施の形態における無線親機１００の制御部１４０と記憶部１２０との機能の概略と同様である。
【０１１１】
第２の実施の形態における無線子機２００の制御部２４０と無線ユニット２１０と記憶部２２０との機能の概略は、図５で示した第１の実施の形態における無線子機２００の制御部２４０と無線ユニット２１０と記憶部２２０との機能の概略と同様である。
【０１１２】
第２の実施の形態において無線親機１００から無線子機２００に送信される呼出信号５００の構成は、図６で示した第１の実施の形態において無線親機１００から無線子機２００に送信される呼出信号５００の構成と同様である。
【０１１３】
第２の実施の形態が第１の実施の形態と異なる点は、一斉検針モード時に無線親機１００から送信される呼出信号５００に含まれ繰返し送信される接続要求信号５２０のパケット５３０の構成である。したがって、その点について説明する。
【０１１４】
なお、第２の実施の形態においては、ホストコンピュータ１５０から指定されたメータを検針する指定検針モードを指定された無線親機１００と無線子機２００とが、指定通信モードで検針データなどのデータを送受信する場合について説明する。
【０１１５】
図１１は、第２の実施の形態における指定検針モード時に無線親機１００から送信される呼出信号５００に含まれ繰返し送信される接続要求信号５２０のパケット５３０の構成を示す図である。図１１を参照して、パケット５３０Ｄは、同期信号５３１と、グループ識別符号５３４と、指定検針コマンド５４４と、ビット列５４５とを含む。
【０１１６】
同期信号５３１は、呼出信号５００を受信した無線子機２００が呼出信号５００を送信している無線親機１００と同期をとるための１７ビットの信号である。
【０１１７】
グループ識別符号５３４は、１２桁の無線親機１００の呼出ＩＤの下３桁をＲＣＲ２進数に変換した１２ビット（＝４ビット×３桁）の符号である。呼出信号５００を受信した無線子機２００は、自局が記憶している無線親機１００の呼出ＩＤの下３桁と、受信した呼出信号に含まれるグループ識別符号５３４とを比較することにより、受信した呼出信号５００が自局が属する無線親機１００から送信された呼出信号であるかを概略的に判断する。
【０１１８】
指定検針コマンド５４４は、指定した無線子機２００を順番に検針する指定検針モードを示す４ビットのコマンドである。
【０１１９】
ビット列５４５は、各ビットが各無線子機に対応し、通信の対象であるか否かを示す１６ビットの符号である。この場合は、各ビットが無線親機１００に属する１６台の無線子機にそれぞれ対応するが、ビット列５４５を長くすることによって、１６台以上の無線子機に対応することもできる。
【０１２０】
呼出信号５００を受信した無線子機２００は、グループ識別符号５３４により、受信した呼出信号５００が自局が属する無線親機１００から送信された呼出信号５００であると概略的に判断し、さらに、指定検針コマンド５４１を検出した場合は、ビット列５４５に基づき、間欠キャリアセンスを停止する。
【０１２１】
自局の順番に対応するビットが通信の対象であることを示す場合、呼出信号５００を検知してから自局の検針が開始されるまでの時間、および、自局の検針が終了してから最後の無線子機の検針が終了するまでの時間、間欠キャリアセンスを停止する。
【０１２２】
自局の順番に対応するビットが通信の対象でないことを示す場合、呼出信号５００を検知してから最後の無線子機の検針が終了するまでの時間、間欠キャリアセンスを停止する。
【０１２３】
図１２は、第２の実施の形態における指定検針モード時の呼出信号５００に含まれるビット列５４５の一例を示す図である。ここでは、値が１であるビットに対応する無線子機が検針の対象であることを示すものとする。図１２（Ａ）を参照して、ビット列５４５Ａのうち５番目と１０番目と１５番目とのビットの値が１であるので、ビット列５４５Ａは、順番記憶部２２１に記憶された順番が５番と１０番と１５番とである無線子機が検針の対象であることを示している。また、ビット列５４５Ａは、指定検針が、５番の無線子機、１０番の無線子機、１５番の無線子機の通信順序で行われることを示している。
【０１２４】
図１２（Ｂ）を参照して、ビット列５４５Ｂのうちすべてのビットの値が１であるので、ビット列５４５Ｂは、無線親機１００に属するすべての無線子機が検針の対象であることを示している。また、ビット列５４５Ｂは、指定検針が各無線子機の順番記憶部２２１に記憶された順番通りの通信順序で行われることを示している。この場合は、第１の実施の形態における一斉検針に相当する。
【０１２５】
図１３は、第２の実施の形態における無線親機１００の送受信の時間的な流れおよび無線子機２００の送受信とキャリアセンスとの時間的な流れの一例を示すタイムチャートである。ここでは、無線親機１００が図１２（Ａ）で示されるビット列５４５Ａを含む呼出信号５００を送信した場合における、送受信とキャリアセンスとの時間的な流れを説明する。図１２（Ａ）で示されるビット列５４５Ａで検針を指定された無線子機は、順番記憶部２２１に記憶された順番が５番と１０番と１５番とである無線子機２００Ｃ，２００Ｄ，２００Ｅである。参考のために、図１２（Ａ）で示されるビット列５４５Ａで検針を指定されていない無線子機の送受信とキャリアセンスとの時間的な流れについても説明する。
【０１２６】
また、無線親機１００が送信する呼出信号の間隔は９０秒とし、無線親機１００が呼出信号５００を送信してから、無線子機２００Ｃ，２００Ｄ，２００Ｅが検針データを応答して、無線親機１００が終了信号を送信するまでの時間は６０秒とする。図１３を参照して、
（１）無線子機２００Ｃ，２００Ｄ，２００Ｅおよびその他の無線子機は、間欠キャリアセンスを行なっている。
【０１２７】
（２）無線親機１００は、呼出信号（指定検針）５００を送信する。
（３）無線子機２００Ｃ，２００Ｄ，２００Ｅおよびその他の無線子機は呼出信号（指定検針）５００を間欠キャリアセンスで検知する。
【０１２８】
（４）無線子機２００Ｃは、検針順序が１番目であるので、呼出信号（指定検針）５００を検知してから自局の検針が開始されるまでの９０×１秒間、間欠キャリアセンスを停止する。
【０１２９】
（５）無線子機２００Ｄは、検針順序が２番目であるので、呼出信号（指定検針）５００を検知してから自局の検針が開始されるまでの９０×２秒間、間欠キャリアセンスを停止する。
【０１３０】
（６）無線子機２００Ｅは、検針順序が３番目であるので、呼出信号（指定検針）５００を検知してから自局の検針が開始されるまでの９０×３秒間、間欠キャリアセンスを停止する。
【０１３１】
（７）その他の無線子機は、検針の指定をされていないので、呼出信号（指定検針）５００を検知してから、検針順序が３番目である最後の無線子機２００Ｅの検針が終了するまでの９０×４−３０秒間、間欠キャリアセンスを停止する。
【０１３２】
（８）無線親機１００は、呼出信号（５番）５０５を送信する。
（９）無線子機２００Ｃは、間欠キャリアセンスを再開し、呼出信号（５番）５０５を検知する。
【０１３３】
（１０）無線子機２００Ｃは、検針データを応答信号６０５として、送信する。
【０１３４】
（１１）無線親機１００は、応答信号６０５を受信する。
（１２）無線親機１００は、終了信号７０５を送信する。
【０１３５】
（１３）無線子機２００Ｃは、終了信号７０５を受信する。
（１４）無線子機２００Ｃは、最後の無線子機２００Ｅの検針が終了するまでの９０×２秒間、間欠キャリアセンスを停止する。
【０１３６】
（１５）以下、無線子機２００Ｄ，２００Ｅについて、無線子機２００Ｃに対する（８）〜（１４）までの処理と同様の処理が行なわれる。
【０１３７】
（１６）無線子機２００Ｃ，２００Ｄ，２００Ｅおよびその他の無線子機は、間欠キャリアセンスを再開する。
【０１３８】
以上、説明したように、第２の実施の形態における無線テレメータシステムでは、無線親機は、予め決められた無線子機の順番を記憶し、各ビットが無線子機の順番に対応し、通信の対象であるか否かを示すビット列を含む呼出信号を送信する。また、無線子機は、自局の順番を記憶し、間欠的に呼出信号を検知し、検知された呼出信号に含まれるビット列の自局の順番に対応するビットが通信の対象であることを示す値の場合、ビット列に基づき求められる所定の時間、間欠キャリアセンスを停止する。
【０１３９】
このため、無線テレメータシステムの無線子機は、自局の順番以外は、間欠キャリアセンスを停止することができる。その結果、無線テレメータシステムにおいて、無線子機が自局の省電力を図ることができる。
【０１４０】
今回開示された実施の形態はすべての点で例示であって、制限的なものではないと考えられるべきである。本発明の範囲は上記した説明ではなくて特許請求の範囲によって示され、特許請求の範囲と均等の意味および、範囲内でのすべての変更が含まれることが意図される。
【図面の簡単な説明】
【図１】 本発明の第１の実施の形態の１つにおける無線テレメータシステムの構成の概略を示すブロック図である。
【図２】 第１の実施の形態における無線親機の構成を示すブロック図である。
【図３】 第１の実施の形態における無線子機の構成を示すブロック図である。
【図４】 第１の実施の形態における無線親機の制御部と記憶部との機能の概略を示す機能ブロック図である。
【図５】 第１の実施の形態における無線子機の制御部と無線ユニットと記憶部との機能の概略を示す機能ブロック図である。
【図６】 第１の実施の形態において無線親機から無線子機に送信される呼出信号の構成を示す図である。
【図７】 第１の実施の形態における一斉検針モード時に無線親機から送信される呼出信号に含まれ繰返し送信される接続要求信号のパケットの第１の構成を示す図である。
【図８】 第１の実施の形態における一斉検針モード時に無線親機から送信される呼出信号に含まれ繰返し送信される接続要求信号のパケットの第２の構成を示す図である。
【図９】 第１の実施の形態における一斉検針モード時に無線親機から送信される呼出信号に含まれ繰返し送信される接続要求信号のパケットの第３の構成を示す図である。
【図１０】 第１の実施の形態における無線親機の送受信の時間的な流れおよび無線子機の送受信とキャリアセンスとの時間的な流れの一例を示すタイムチャートである。
【図１１】 第２の実施の形態における指定検針モード時に無線親機から送信される呼出信号に含まれ繰返し送信される接続要求信号のパケットの構成を示す図である。
【図１２】 第２の実施の形態における指定検針モード時の呼出信号に含まれるビット列の一例を示す図である。
【図１３】 第２の実施の形態における無線親機の送受信の時間的な流れおよび無線子機の送受信とキャリアセンスとの時間的な流れの一例を示すタイムチャートである。
【符号の説明】
１００ 無線親機、１１０ 無線ユニット、１１１ アンテナ、１２０ 記憶部、１２１ 子機記憶部、１３０ 通信部、１４０ 制御部、１４１ 呼出信号送信部、１４２ 順番送信部、１５０ ホストコンピュータ、２００ 無線子機、２１０ 無線ユニット、２１１ アンテナ、２１２ 間欠キャリアセンス部、２２０ 記憶部、２２１ 順番記憶部、２３０ 通信部、２４０ 制御部、２４１ キャリアセンス制御部、２４２ 演算部。[0001]
BACKGROUND OF THE INVENTION
  The present invention provides a wireless system.MuIn particular, a wireless system suitable for power saving of the wireless slave unitMuAnd wireless handset.
[0002]
[Prior art]
Conventionally, in a wireless telemeter system, meter reading data of electricity, gas, water, etc. measured by a meter and abnormality information of the meter are transmitted from a wireless slave unit to a wireless master unit via a wireless line, and wirelessly via a wired line. The data is transmitted from the master unit to the host computer via the terminal side network control unit (T-NCU) and the center side network control unit, and processed by the host computer.
[0003]
An example of such a radio telemeter system is disclosed in, for example, Japanese Patent Laid-Open No. 11-296776. According to the wireless automatic meter reading system disclosed in the publication, the wireless slave unit accurately and quickly identifies only the wireless call to its own wireless device without being affected by other communications or noise, Consumption can be reduced.
[0004]
[Problems to be solved by the invention]
In the conventional wireless telemeter system, the wireless slave device stops intermittent carrier sense while a wireless slave device other than its own station is communicating. However, the wireless slave device restarts the intermittent carrier sense every time the wireless slave device other than its own station finishes communication. For this reason, for example, when meter reading is performed in a fixed order, there is a problem that intermittent carrier sensing is resumed even when the station is not in order, and the power of the wireless slave unit is wasted.
[0005]
  The present invention has been made to solve the above-described problems, and one object of the present invention is to provide a wireless system in which a wireless slave unit can save power of its own station.MuAnd providing a wireless slave unit.
[0006]
[Means for Solving the Problems]
  In order to achieve the above object, according to one aspect of the present invention, a wireless system includes a wireless master device and a plurality of wireless slave devices, and the wireless master device and the wireless slave device are in a predetermined order. Slave unit storage means for storing the order of wireless slave units in the simultaneous communication mode for communication, and a command indicating the simultaneous communication mode in the case of the simultaneous communication modeAnd the number of wireless slaves that are subject to simultaneous communicationThe wireless slave unit includes: order storage means for storing the order of the own station in the simultaneous communication mode; and intermittent carrier sense means for intermittently detecting the call signal. If the detected call signal includes a command indicating the simultaneous communication mode, the order of the own station stored in the order storage meansAnd the number of the wireless slave units included in the call signalBased onThe calculation means for calculating the time from the end of the communication of the own station until the end of the communication of the last wireless slave unit, and the calculation meansCarrier sense control means for prohibiting detection by time and intermittent carrier sense means.
[0007]
  According to the present invention, the wireless master device stores the order of the wireless slave devices in the simultaneous communication mode for communicating with the wireless slave devices in a predetermined order. In the simultaneous communication mode, the command indicating the simultaneous communication mode is stored.And the number of wireless slaves that are subject to simultaneous communicationA paging signal including is transmitted. In addition, the wireless slave unit stores the order of its own station in the simultaneous communication mode, intermittently detects a call signal, and if the detected call signal includes a command indicating the simultaneous communication mode, Station orderAnd the number of wireless slave units included in the call signalBased on, Calculate the time from the end of the communication of the local station to the end of the communication of the last wireless slave unit,Stop intermittent carrier sense for hours.
[0008]
For this reason, intermittent carrier sense can be stopped except in the order of the own station. As a result, it is possible to provide a wireless system in which the wireless slave unit can save power of its own station.
[0009]
  Preferably,CalculationThe means determines the time from when a call signal including a command indicating simultaneous communication is detected until the communication of the local station is started.furtherCalculateThe
[0010]
  According to the present invention, the wireless slave unit determines the time from when a call signal including a command indicating simultaneous communication is detected until the communication of the local station is started.furtherCalculate andCalculated time,Intermittent carrier sensefurtherCan be stopped. As a result, the wireless slave unit saves its power.furtherCan be planned.
[0013]
Preferably, the wireless master device further includes order transmitting means for transmitting the order of the wireless slave devices in the simultaneous communication mode to the wireless slave device, and the wireless slave device determines the order of the own station in the simultaneous communication mode to the wireless master device. Order receiving means is further provided.
[0014]
According to this invention, the wireless master device transmits the order of the wireless slave devices in the simultaneous communication mode to the wireless slave device. Further, the wireless slave device receives the order of the own station in the simultaneous communication mode from the wireless master device. For this reason, it is possible to notify the wireless slave device of the order of the wireless slave devices set in the wireless master device. As a result, the order consistency of the wireless slave units can be improved.
[0015]
  According to another aspect of the present invention, the wireless system includes a wireless master device and a plurality of wireless slave devices, and the wireless master device includes slave device storage means for storing a predetermined order of the wireless slave devices, Each bit corresponds to the order of the wireless slave units, and includes call signal transmission means for transmitting a paging signal including a bit string indicating whether or not communication is to be performed, and the wireless slave unit stores the order of its own station In the case of a value indicating that the order storage means, the intermittent carrier sense means for intermittently detecting the call signal, and the bit corresponding to the order of the own station of the bit string included in the detected call signal is a communication target,Included in the call signalBased on bit stringThe calculation means for calculating the time from the end of the communication of the own station until the end of the communication of the last wireless slave unit, and the calculation meansCarrier sense control means for prohibiting detection by time and intermittent carrier sense means.
[0016]
  According to this invention, the wireless master unit stores a predetermined order of the wireless slave units, and each bit corresponds to the order of the wireless slave units and includes a call string including a bit string indicating whether or not communication is to be performed. Send a signal. In addition, the wireless slave device stores the order of its own station, intermittently detects the call signal, and confirms that the bit corresponding to the order of its own station in the bit string included in the detected call signal is the object of communication. For the value shown,Included in the call signalBased on bit string, Calculate the time from the end of the communication of the local station to the end of the communication of the last wireless slave unit,Stop intermittent carrier sense for hours.
[0017]
For this reason, intermittent carrier sense can be stopped except in the order of the own station. As a result, it is possible to provide a wireless system in which the wireless slave unit can save power of its own station.
[0018]
  Preferably,CalculationThe means determines the time from when the call signal is detected until the communication of the local station is started.furtherCalculateThe
[0020]
  Preferably,CalculationIf the bit corresponding to the turn of the bit string included in the detected paging signal is a value indicating that it is not a communication target, the communication of the last wireless slave unit is terminated after detecting the paging signal. Calculate the time untilThe
[0021]
  For this reason, intermittent carrier sense can be stopped except in the order of the own station. As a result, the wireless slave unit saves its power.furtherCan be planned.
[0022]
Preferably, the intermittent carrier sense means resumes the carrier sense even when the intermittent carrier sense is stopped when an emergency call factor occurs. For this reason, communication can be performed even in an emergency.
[0026]
  According to still another aspect of the present invention, the wireless slave device has a simultaneous communication mode for communicating with the wireless parent device in a predetermined order, and stores the order of own stations in the simultaneous communication mode. When,Includes the command indicating the simultaneous communication mode and the number of wireless slave units subject to simultaneous communicationRinging signalIntermittentlyIf the intermittent carrier sense means to be detected and a command indicating the simultaneous communication mode are included in the detected call signal, the order of the own station in the simultaneous communication mode stored in the order storage meansAnd the number of the wireless slave units included in the call signalBased onThe calculation means for calculating the time from the end of the communication of the own station until the end of the communication of the last wireless slave unit, and the calculation meansCarrier sense control means for prohibiting detection by time and intermittent carrier sense means.
[0027]
  According to the present invention, the wireless slave device has a simultaneous communication mode for communicating with the wireless parent device in a predetermined order, stores the order of the own station in the simultaneous communication mode,Includes the command indicating the simultaneous communication mode and the number of wireless slave units subject to simultaneous communicationRinging signalIntermittentlyIf the detected paging signal includes a command indicating the broadcast mode, the order of the station in the stored broadcast modeAnd the number of wireless slave units included in the call signalBased on, Calculate the time from the end of the communication of the local station to the end of the communication of the last wireless slave unit,Stop intermittent carrier sense for hours.
[0028]
For this reason, intermittent carrier sense can be stopped except in the order of the own station. As a result, it is possible to provide a wireless slave device capable of saving power of the local station.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. In addition, the same code | symbol in the figure shows the same or equivalent member, and the overlapping description is not repeated.
[0030]
[First Embodiment]
The first embodiment in the present embodiment will be described below.
[0031]
FIG. 1 is a block diagram showing an outline of the configuration of a radio telemeter system according to one of the first embodiments of the present invention. Referring to FIG. 1, a wireless telemeter system includes a plurality of wireless master devices 100, 100A, 100B, a host computer 150 connected to wireless master devices 100, 100A, 100B via communication line 160, and a wireless master device. The wireless slave devices 200, 200A, and 200B are connected to the meters 250, 250A, and 250B, respectively.
[0032]
In the first embodiment, the wireless master device 100 and the wireless slave device 200 to which the simultaneous meter reading mode in which the meter is read from the host computer 150 in a predetermined order are assigned to the meter reading data in the simultaneous communication mode. A case of transmitting / receiving data such as will be described.
[0033]
The wireless master device 100 converts a signal including a command indicating the simultaneous meter reading mode received from the host computer 150 into a calling signal including a command indicating the simultaneous meter reading mode, and converts the converted calling signal to the wireless slave devices 200, 200A, and 200B. Send over a wireless line. In addition, the wireless master device 100 transmits a signal including meter reading data indicating the usage amount of electricity, gas, water, etc. measured by the meters 250, 250A, 250B connected to the wireless slave devices 200, 200A, 200B. 200, 200A, and 200B, converted into a signal for transmission via a communication line, and transmitted to the host computer 150 via the communication line 160.
[0034]
The host computer 150 is a computer such as a general-purpose machine or a workstation, transmits a signal including a command indicating the simultaneous meter reading mode, and receives and counts meter reading data indicating the usage amount of electricity, gas, water and the like. Also, the abnormality information is received, and an operation corresponding to the abnormality of the wireless slave devices 200, 200A, 200B and the meters 250, 250A, 250B is performed.
[0035]
The communication line 160 is used for communication between the wireless master devices 100, 100 </ b> A, 100 </ b> B and the host computer 150. The communication line 160 may be a public line such as a telephone line or a dedicated line.
[0036]
The wireless slave devices 200, 200A, 200B receive a calling signal including a command indicating the simultaneous meter reading mode from the wireless master device 100, and generate a signal including meter reading data indicating the amount of use received from the meters 250, 250A, 250B. The generated signal is transmitted to the wireless master device 100 via a wireless line.
[0037]
Meters 250, 250A, and 250B measure usage amounts of electricity, gas, water, and the like, convert them into electrical signals, and transmit them to wireless slave devices 200, 200A, and 200B as meter reading data.
[0038]
In the case of the simultaneous meter reading mode in which the wireless master device 100 performs meter reading with a plurality of wireless slave devices 200, 200A, 200B in a predetermined order, a signal including a command indicating the simultaneous meter reading mode is transmitted from the host computer 150 via the communication line 160. And transmitted to the wireless master device 100. Then, it is converted into a calling signal including a command indicating the simultaneous meter reading mode by the wireless master device 100, and the converted calling signal is transmitted from the wireless master device 100 to the wireless slave devices 200, 200A, and 200B via the wireless channel. . The wireless slave devices 200, 200A, 200B that have received the calling signal including the command indicating the simultaneous meter reading mode perform an operation corresponding to the simultaneous meter reading.
[0039]
In addition, meter reading data indicating the usage amount of electricity, gas, water, etc. measured by the meters 250, 250A, 250B, abnormality information of the meters 250, 250A, 250B, and the like are wireless devices connected to the meters 250, 250A, 250B. The data is transmitted from the devices 200, 200A, 200B to the wireless master device 100 via a wireless line. Then, it is transmitted from the wireless master device 100 to the host computer 150 via the communication line 160 and processed by the host computer 150.
[0040]
FIG. 2 is a block diagram showing a configuration of wireless master device 100 according to the first embodiment. Note that the wireless master devices 100A and 100B in FIG. Referring to FIG. 2, radio base unit 100 includes radio unit 110 that performs radio communication, antenna 111 that transmits and receives radio signals, storage unit 120 that stores predetermined information, and a communication unit that communicates with host computer 150. 130 and a control unit 140 that controls the entirety of the wireless master device 100.
[0041]
The wireless unit 110 transmits a paging signal including a command indicating the simultaneous meter reading mode received from the control unit 140 to the antenna 111. Further, a signal including meter reading data received from the antenna 111 is transmitted to the control unit 140.
[0042]
The antenna 111 transmits a calling signal including a command indicating the simultaneous meter reading mode received from the wireless unit 110 to the wireless slave devices 200, 200A, and 200B, and includes the meter reading data transmitted from the wireless slave devices 200, 200A, and 200B. A signal is received and transmitted to the wireless unit 110.
[0043]
The storage unit 120 stores the calling ID of the local station, the calling ID of the wireless slave unit belonging to the local station, and the order of meter reading of the wireless slave unit in the simultaneous meter reading mode.
[0044]
The communication unit 130 is connected to the communication line 160, receives a signal including a command indicating the simultaneous meter reading mode from the host computer 150, and transmits a signal including meter reading data to the host computer 150.
[0045]
The control unit 140 receives a signal including a command indicating the simultaneous meter reading mode from the communication unit 130, converts the signal into a calling signal including a command indicating the simultaneous meter reading mode for wireless transmission, and transmits the call signal to the wireless unit 110. Further, a wireless signal for requesting that each wireless slave device 200, 200 </ b> A, 200 </ b> B individually transmit a signal including meter reading data is created and transmitted to the wireless unit 110. Furthermore, a signal including meter reading data received from the wireless unit 110 is transmitted to the communication unit 130.
[0046]
FIG. 3 is a block diagram illustrating a configuration of the wireless slave device 200 according to the first embodiment. Note that the wireless slave devices 200 </ b> A and 200 </ b> B in FIG. 1 have the same configuration as the wireless slave device 200. Referring to FIG. 3, the wireless slave device 200 includes a wireless unit 210 that performs wireless communication, an antenna 211 that transmits and receives wireless signals, a storage unit 220 that stores predetermined information, and a communication unit 220 that communicates with a meter 250. And a control unit 240 that controls the entire wireless slave device 200.
[0047]
The wireless unit 210 transmits a wireless signal received from the control unit 240 for wireless transmission to the antenna 211. In addition, the wireless signal received from the antenna 211 is transmitted to the control unit 240. Furthermore, carrier sense for detecting whether or not a carrier wave is transmitted via the antenna 211 is performed.
[0048]
The antenna 211 transmits the radio signal received from the radio unit 210 to the radio base unit 100, receives the radio signal transmitted from the radio base unit 100, and transmits the radio signal to the radio unit 210.
[0049]
The storage unit 220 stores the call ID of the own station, the call ID of the wireless master device to which the own station belongs, and the order of the meter reading of the own station in the simultaneous meter reading mode.
[0050]
The communication unit 230 is connected to the meter 250 and receives a signal including meter reading data from the meter 250.
[0051]
The control unit 240 receives a calling signal including a command indicating the simultaneous meter reading mode from the wireless unit 210 and transmits a signal requesting the communication unit 230 to transmit a signal including meter reading data. Further, it receives a signal including meter reading data from the communication unit 230, converts the signal including meter reading data into a wireless signal for wireless transmission, and transmits the wireless signal to the wireless unit 210.
[0052]
FIG. 4 is a functional block diagram illustrating an outline of functions of the control unit 140 and the storage unit 120 of the wireless master device 100 according to the first embodiment. Referring to FIG. 4, control unit 140 includes a call signal transmission unit 141 and an order transmission unit 142. The storage unit 120 includes a slave unit storage unit 121 that stores the order of each wireless slave unit in the simultaneous meter reading mode.
[0053]
The call signal transmission unit 141 receives a signal including a command indicating the simultaneous meter reading mode from the communication unit 130, and converts the signal into a calling signal including a command indicating the simultaneous meter reading for wireless transmission. Then, the converted call signal is transmitted to the wireless unit 110.
[0054]
The order transmission unit 142 reads the order of each wireless slave unit from the slave unit storage unit 121, generates a call signal including the order of each wireless slave unit, and transmits the generated call signal to each wireless slave unit.
[0055]
FIG. 5 is a functional block diagram illustrating an outline of functions of the control unit 240, the wireless unit 210, and the storage unit 220 of the wireless slave device 200 according to the first embodiment. Referring to FIG. 5, radio unit 210 includes an intermittent carrier sensing unit 212 that intermittently detects a call signal. The storage unit 220 includes an order storage unit 221 that stores the order of the own station in the simultaneous meter reading mode. In addition, the control unit 240 includes a carrier sense control unit 241, and the carrier sense control unit 241 includes a calculation unit 242.
[0056]
The carrier sense control unit 241 prohibits the detection by the intermittent carrier sense unit 212 for a predetermined time obtained based on the order of the own station stored in the order storage unit 221.
[0057]
The calculation unit 242 calculates a time during which intermittent carrier sense other than the order of the own station is prohibited, based on the order of the own station and the number of wireless slave devices that are targets of simultaneous meter reading.
[0058]
FIG. 6 is a diagram illustrating a configuration of a paging signal 500 transmitted from the wireless master device 100 to the wireless slave device 200 in the first embodiment. Referring to FIG. 6, paging signal 500 includes a portion 510 defined by ARIB STD-T67, a connection request signal 520, and an information unit 550. ARIB (Association of Radio Industries and Businesses) is an abbreviation for “Radio Industry Association”. ARIB STD is a standard that directly adopts a standard determined by the International Communication Union (ITU) to which ARIB is a member as a domestic standard.
[0059]
A portion 510 defined by ARIB STD-T67 is a 63-bit self-call code including a 105-bit bit synchronization signal 511, a 31-bit frame synchronization signal 512, a self-call ID and an error correction redundant bit. 513. When the standard is changed, the portion 510 defined by ARIB STD-T67 may be configured according to the change. Moreover, the structure according to previous standards, for example, RCR STD, may be used. RCR STD is a standard adopted by the Radio System Development Center (RCR), the predecessor of ARIB, as a domestic standard.
[0060]
The connection request signal 520 includes a plurality of packets 530 that are repeatedly transmitted. The packet 530 includes a synchronization signal 531, a group identification code 532, and a terminal identification code 533.
[0061]
The synchronization signal 531 is a 17-bit signal for the wireless slave device 200 that has received the call signal 500 to synchronize with the wireless master device 100 that is transmitting the call signal 500.
[0062]
The group identification code 532 is a 16-bit code (= 4 bits × 4 digits) obtained by converting the last 4 digits of the call ID of the 12-digit wireless master device 100 into an RCR binary number. The wireless slave device 200 that has received the call signal 500 compares the last four digits of the call ID of the wireless master device 100 stored in its own station with the group identification code 532 included in the received call signal. It is roughly determined whether the received call signal 500 is a call signal transmitted from the wireless master device 100 to which the own station belongs.
[0063]
The RCR binary number is a 4-bit binary number converted from a decimal number as shown in Table 1 below.
[0064]
[Table 1]

[0065]
The terminal identification code 533 is a 16-bit code (= 4 bits × 4 digits) obtained by converting the last 4 digits of the call ID of the 12-digit wireless slave device into an RCR binary number. The wireless slave device 200 that has received the call signal 500 compares the last four digits of the call ID stored in the own station with the terminal identification code 533 included in the received call signal 500 to receive the call. It is roughly determined whether the received call signal 500 is a call signal transmitted to the own station.
[0066]
The information unit 550 includes a local station call ID 551 that identifies the wireless master device 100 that is transmitting the call signal 500, a partner station call ID 552 that identifies the wireless slave device 200 that receives the call signal 500, and the wireless master device 100. Data 553 passed to the wireless slave device 200.
[0067]
The local station call ID 551 is a 48-bit code obtained by converting a 12-digit number identifying the wireless master device 100 that is the local station that transmitted the call signal 500 into an RCR binary number.
[0068]
The partner station call ID 552 is a 48-bit code obtained by converting a 12-digit number identifying the wireless slave device 200 that is the partner station of the call signal 500 into an RCR binary number.
[0069]
FIG. 7 is a diagram illustrating a first configuration of the packet 530 of the connection request signal 520 included in the calling signal 500 transmitted from the wireless master device 100 and repeatedly transmitted in the simultaneous meter reading mode in the first embodiment. . Referring to FIG. 7, packet 530A includes a synchronization signal 531, a group identification code 532, a terminal identification code 533, a simultaneous meter reading command 541, and a code 542 indicating the number of simultaneous meter readings.
[0070]
The simultaneous meter reading command 541 is a 4-bit command indicating a simultaneous communication mode for communicating with the wireless slave device 200 in a predetermined order. The wireless slave device 200 that has received the call signal 500 uses the group identification code 532 and the terminal identification code 533 to send the received call signal 500 to the own station from the wireless master device 100 to which the own station belongs. If it is determined that there is a general meter reading and the simultaneous meter reading command 541 is detected, an operation corresponding to the simultaneous meter reading is performed. Specifically, the wireless slave device 200, based on the order of the own station stored in the order storage unit 221, the time from when the simultaneous meter reading command 541 is received until the meter reading of the own station is started, intermittent carrier sense Is stopped, and intermittent carrier sensing is resumed when a calling signal for meter reading of the own station is transmitted. The simultaneous meter reading command 541 is a 4-bit code not used in the RCR binary number, for example, “0001” which is one of “0000”, “0001”, “0010”, “1101”, “1110” and “1111”. ".
[0071]
Reference numeral 542 indicating the number of simultaneous meter readings is a 12-bit (= 4 bits × 3 digits) code obtained by converting the number of wireless slave devices 200 that perform simultaneous meter reading into RCR binary numbers. The wireless slave device 200 that has received the call signal 500 uses the group identification code 532 and the terminal identification code 533 to send the received call signal 500 to the own station from the wireless master device 100 to which the own station belongs. When the general meter reading command 541 is detected, it is determined based on the order of the own station stored in the order storage unit 221 and the number of simultaneous meter readings. The intermittent carrier sense is stopped for the time until the meter reading of the last wireless slave device is finished, and the intermittent carrier sense is restarted when the meter reading of the last wireless slave device is finished.
[0072]
The simultaneous meter reading command 541 described in FIG. 7 and the reference numeral 542 indicating the number of wireless slave devices 200 performing the simultaneous meter reading may be included in the packet 530 of the call signal 500 in the configuration illustrated in FIGS. 8 and 9 described later. .
[0073]
FIG. 8 is a diagram showing a second configuration of the packet 530 of the connection request signal 520 that is repeatedly transmitted by being included in the calling signal 500 transmitted from the wireless master device 100 in the simultaneous meter reading mode in the first embodiment. . Referring to FIG. 8, packet 530B includes a synchronization signal 531, a group identification code 532, a simultaneous meter reading command 541, and a code 542 indicating the number of simultaneous meter readings.
[0074]
The synchronization signal 531 is a 17-bit signal for synchronizing with the wireless slave device 200.
[0075]
The group identification code 532 is a 16-bit code (= 4 bits × 4 digits) obtained by converting the last 4 digits of the call ID of the 12-digit wireless master device 100 into an RCR binary number.
[0076]
The simultaneous meter reading command 541 is a 4-bit command indicating a simultaneous communication mode for communicating with the wireless slave device 200 in a predetermined order.
[0077]
Reference numeral 542 indicating the number of simultaneous meter readings is a 12-bit (= 4 bits × 3 digits) code obtained by converting the number of wireless slave devices 200 that perform simultaneous meter reading into RCR binary numbers.
[0078]
The operations of the synchronization signal 531, the group identification code 534, the simultaneous meter reading command 541, and the reference numeral 542 indicating the number of simultaneous meter readings are as described in FIG.
[0079]
FIG. 9 is a diagram showing a third configuration of the packet 530 of the connection request signal 520 that is repeatedly transmitted by being included in the calling signal 500 transmitted from the wireless master device 100 in the simultaneous meter reading mode in the first embodiment. . Referring to FIG. 9, packet 530 </ b> C includes a synchronization signal 531, a group identification code 534, a simultaneous meter reading command 541, and a code 543 indicating the number of simultaneous meter readings.
[0080]
The synchronization signal 531 is a 17-bit signal for synchronizing with the wireless slave device 200.
[0081]
The group identification code 534 is a 12-bit code (= 4 bits × 3 digits) obtained by converting the last 3 digits of the call ID of the 12-digit wireless master device 100 into an RCR binary number.
[0082]
The simultaneous meter reading command 541 is a 4-bit command indicating a simultaneous communication mode for communicating with the wireless slave device 200 in a predetermined order.
[0083]
Reference numeral 543 indicating the number of simultaneous meter readings is a 16-bit (= 4 bits × 4 digits) code obtained by converting the number of wireless slave devices 200 that perform simultaneous meter reading into RCR binary numbers.
[0084]
The operations of the synchronization signal 531, the group identification code 534, the simultaneous meter reading command 541, and the reference numeral 543 indicating the number of simultaneous meter readings are as described in FIG.
[0085]
FIG. 10 is a time chart illustrating an example of a temporal flow of transmission / reception of the wireless master device 100 and an exemplary temporal flow of transmission / reception of the wireless slave device 200 and carrier sense in the first embodiment. Here, the wireless master device 100, the wireless slave device 200a in which the order of simultaneous meter reading is first, the wireless slave device 200m in which the order of simultaneous meter reading is mth, and the nth wireless device in which the order of simultaneous meter reading is the last. The time flow of transmission / reception with the apparatus 200n will be described. The interval of the calling signal transmitted by the wireless master device 100 is 90 seconds. After the wireless master device transmits the calling signal, the wireless slave device responds with the meter reading data, and the wireless master device transmits the end signal. The time until is 60 seconds. Referring to FIG.
(1) The wireless slave devices 200a, 200m, and 200n perform intermittent carrier sense.
[0086]
(2) The wireless master device 100 transmits a call signal (simultaneous communication) 500.
(3) The wireless slave devices 200a, 200m, and 200n detect the call signal (simultaneous communication) 500 by intermittent carrier sense.
[0087]
(4) Since the wireless slave device 200a has the first station order, the wireless slave device 200a intermittently senses the carrier for 90 × 1 seconds from when the call signal (simultaneous meter reading) 500 is detected until the meter reading of the own station is started. To stop.
[0088]
(5) The wireless slave device 200m is in the m-th order of its own station, so intermittent carrier sensing is performed for 90 × m seconds from when the call signal (simultaneous meter reading) 500 is detected until the meter reading of its own station is started. To stop.
[0089]
(6) Since the wireless slave device 200n has its own station in the n-th order, intermittent carrier sense is performed for 90 × n seconds from the detection of the calling signal (simultaneous meter reading) 500 to the start of the meter reading of the own station. To stop.
[0090]
(7) The wireless master device 100 transmits a call signal (first device) 501.
(8) The wireless slave device 200a restarts the intermittent carrier sense and detects the calling signal (first device) 501.
[0091]
(9) Omission
(10) The wireless master device 100 transmits an end signal (m−1th unit) 701.
[0092]
(11) The wireless master device 100 transmits a calling signal (m-th unit) 502.
(12) The wireless slave device 200m resumes the intermittent carrier sense and detects the calling signal (m-th unit) 502.
[0093]
(13) The wireless slave device 200m transmits a response signal 602 including meter reading data.
(14) The wireless master device 100 receives the response signal 602.
[0094]
(15) The wireless master device 100 transmits an end signal 702.
(16) The wireless slave device 200m receives the end signal 702.
[0095]
(17) The wireless slave device 200m stops the intermittent carrier sense for 90 × (nm) seconds until the meter reading of the last wireless slave device 200n is completed.
[0096]
(18) The wireless master device 100 transmits a call signal (m + 1th unit) 503.
(19) Omission
(20) The wireless master device 100 transmits a call signal (n-th unit) 504.
[0097]
(21) The wireless slave device 200n restarts the intermittent carrier sense and detects the calling signal (n-th unit) 504.
[0098]
(22) The wireless slave device 200n transmits a response signal 604 including meter reading data.
(23) The wireless master device 100 receives the response signal 604.
[0099]
(24) The wireless master device 100 transmits an end signal 704.
(25) The wireless slave device 200n receives the end signal 704.
[0100]
(26) The wireless slave devices 200a, 200m, and 200n resume intermittent carrier sense.
[0101]
As described above, in the wireless telemeter system according to the first embodiment, the wireless master device 100 stores the order of the wireless slave devices in the simultaneous meter reading mode in which the wireless slave device 200 communicates with the wireless slave device 200 in a predetermined order. In the case of the simultaneous meter reading mode, a call signal 500 including a command indicating the simultaneous meter reading mode is transmitted. Further, the wireless slave device 200 stores the order of the own station in the simultaneous meter reading mode, intermittently detects the calling signal 500, and stores when the detected calling signal 500 includes a command indicating the simultaneous meter reading mode. The intermittent carrier sense is stopped for a predetermined time determined based on the order of the received stations.
[0102]
For this reason, the radio | wireless subunit | mobile_unit of a radio | wireless telemeter system can stop intermittent carrier sense except the order of an own station. As a result, in the wireless telemeter system, the wireless slave unit can save power of its own station.
[0103]
Further, the wireless master device 100 transmits the order of the wireless slave devices 200 in the simultaneous communication mode to the wireless slave device 200. Then, the wireless slave device 200 receives the order of the local station in the simultaneous communication mode from the wireless master device 100.
[0104]
Therefore, the wireless master device can notify the wireless slave device 200 of the order of the wireless slave devices 200 set in the wireless master device 100. As a result, the order consistency of the wireless slave units can be improved.
[0105]
Although the wireless system in the wireless telemeter system has been described in the first embodiment, the wireless master device 100 that transmits the calling signal 500 including any of the packets 530A to 530C described in FIGS. And the invention can be captured as the wireless slave device 200 that receives the calling signal 500 including the packets 530A to 530C described in FIGS. 7 to 9 and stops the intermittent carrier sense except the order of the own station.
[0106]
[Second Embodiment]
Next, a second embodiment in the present embodiment will be described.
[0107]
The outline of the configuration of the radio telemeter system in one of the second embodiments of the present invention is the same as the outline of the configuration of the radio telemeter system in one of the first embodiments shown in FIG.
[0108]
The configuration of wireless master device 100 in the second embodiment is the same as that of wireless master device 100 in the first embodiment shown in FIG.
[0109]
The configuration of the wireless slave device 200 in the second embodiment is the same as the configuration of the wireless slave device 200 in the first embodiment shown in FIG.
[0110]
An outline of the functions of the control unit 140 and the storage unit 120 of the wireless master device 100 in the second embodiment is as follows. The control unit 140 and the storage unit 120 of the wireless master device 100 in the first embodiment shown in FIG. It is the same as the outline of the function.
[0111]
The outline of the functions of the control unit 240, the wireless unit 210, and the storage unit 220 of the wireless slave device 200 in the second embodiment is as follows. The control unit 240 of the wireless slave device 200 in the first embodiment shown in FIG. This is the same as the outline of the functions of the wireless unit 210 and the storage unit 220.
[0112]
The configuration of the calling signal 500 transmitted from the wireless master device 100 to the wireless slave device 200 in the second embodiment is transmitted from the wireless master device 100 to the wireless slave device 200 in the first embodiment shown in FIG. This is the same as the configuration of the calling signal 500 to be executed.
[0113]
The second embodiment is different from the first embodiment in the configuration of the packet 530 of the connection request signal 520 that is repeatedly transmitted by being included in the calling signal 500 transmitted from the wireless master device 100 in the simultaneous meter reading mode. is there. Therefore, this point will be described.
[0114]
In the second embodiment, the wireless master device 100 and the wireless slave device 200 that are designated in the designated meter-reading mode for meter-reading the meter designated from the host computer 150 receive data such as meter-reading data in the designated communication mode. A case of transmitting and receiving will be described.
[0115]
FIG. 11 is a diagram illustrating a configuration of a packet 530 of a connection request signal 520 that is repeatedly transmitted by being included in the calling signal 500 transmitted from the wireless master device 100 in the designated meter-reading mode according to the second embodiment. Referring to FIG. 11, packet 530 </ b> D includes a synchronization signal 531, a group identification code 534, a designated meter reading command 544, and a bit string 545.
[0116]
The synchronization signal 531 is a 17-bit signal for the wireless slave device 200 that has received the call signal 500 to synchronize with the wireless master device 100 that is transmitting the call signal 500.
[0117]
The group identification code 534 is a 12-bit code (= 4 bits × 3 digits) obtained by converting the last 3 digits of the call ID of the 12-digit wireless master device 100 into an RCR binary number. The wireless slave device 200 that has received the call signal 500 compares the last three digits of the call ID of the wireless master device 100 stored in its own station with the group identification code 534 included in the received call signal. It is roughly determined whether the received call signal 500 is a call signal transmitted from the wireless master device 100 to which the own station belongs.
[0118]
The designated meter reading command 544 is a 4-bit command indicating a designated meter reading mode for metering the designated wireless slave device 200 in order.
[0119]
The bit string 545 is a 16-bit code indicating whether each bit corresponds to each wireless slave and is a communication target. In this case, each bit corresponds to 16 wireless slave devices belonging to the wireless master device 100. However, by making the bit string 545 longer, it is possible to correspond to 16 or more wireless slave devices.
[0120]
The wireless slave device 200 that has received the call signal 500 roughly determines by the group identification code 534 that the received call signal 500 is the call signal 500 transmitted from the wireless master device 100 to which the own station belongs. When the designated meter reading command 541 is detected, the intermittent carrier sense is stopped based on the bit string 545.
[0121]
When the bit corresponding to the order of the own station indicates that it is a communication target, the time from when the call signal 500 is detected until the meter reading of the own station is started, and after the meter reading of the own station is completed Intermittent carrier sense is stopped for the time until the last wireless slave unit's meter reading is completed.
[0122]
When the bit corresponding to the order of the own station indicates that it is not a communication target, the intermittent carrier sense is stopped for the time from when the call signal 500 is detected until the last wireless slave device completes the meter reading.
[0123]
FIG. 12 is a diagram illustrating an example of the bit string 545 included in the calling signal 500 in the designated meter reading mode according to the second embodiment. Here, it is assumed that the wireless slave device corresponding to the bit whose value is 1 is the target of meter reading. Referring to FIG. 12A, since the values of the fifth, tenth, and fifteenth bits in bit sequence 545A are 1, bit sequence 545A has the order stored in order storage unit 221 as the fifth. This indicates that the wireless slave devices No. 10 and No. 15 are objects of meter reading. The bit string 545A indicates that the designated meter reading is performed in the communication order of the fifth wireless slave device, the tenth wireless slave device, and the 15th wireless slave device.
[0124]
Referring to FIG. 12B, since the values of all bits in bit string 545B are 1, bit string 545B indicates that all wireless slave devices belonging to wireless master device 100 are subject to meter reading. Yes. The bit string 545B indicates that the designated meter reading is performed in the communication order in the order stored in the order storage unit 221 of each wireless slave unit. This case corresponds to the simultaneous meter reading in the first embodiment.
[0125]
FIG. 13 is a time chart illustrating an example of a temporal flow of transmission / reception of the wireless master device 100 and an exemplary temporal flow of transmission / reception of the wireless slave device 200 and carrier sense in the second embodiment. Here, the temporal flow of transmission / reception and carrier sense when wireless base station 100 transmits call signal 500 including bit string 545A shown in FIG. 12 (A) will be described. In the wireless slave device whose meter reading is designated by the bit string 545A shown in FIG. 12A, the wireless slave devices 200C, 200D, and 200E in which the orders stored in the order storage unit 221 are Nos. 5, 10, and 15E. It is. For reference, the temporal flow of transmission / reception and carrier sense of a wireless slave unit for which meter reading is not designated in the bit string 545A shown in FIG. 12A will also be described.
[0126]
The interval of the calling signal transmitted by the wireless master device 100 is 90 seconds. After the wireless master device 100 transmits the calling signal 500, the wireless slave devices 200C, 200D, and 200E respond to the meter reading data, and the wireless parent device 100 The time until the machine 100 transmits the end signal is 60 seconds. Referring to FIG.
(1) The wireless slave devices 200C, 200D, and 200E and other wireless slave devices perform intermittent carrier sense.
[0127]
(2) The wireless master device 100 transmits a calling signal (designated meter reading) 500.
(3) The wireless slave devices 200C, 200D, 200E and other wireless slave devices detect the calling signal (designated meter reading) 500 by intermittent carrier sense.
[0128]
(4) Since the wireless slave device 200C has the first meter reading order, the intermittent carrier sense is stopped for 90 × 1 seconds from when the calling signal (designated meter reading) 500 is detected until the meter reading of the local station is started. To do.
[0129]
(5) Since the wireless slave device 200D has the second meter reading order, the intermittent carrier sense is stopped for 90 × 2 seconds from when the calling signal (designated meter reading) 500 is detected until the meter reading of the local station is started. To do.
[0130]
(6) Since the wireless slave device 200E has the third meter reading order, the intermittent carrier sense is stopped for 90 × 3 seconds from when the calling signal (designated meter reading) 500 is detected until the meter reading of the local station is started. To do.
[0131]
(7) Since the other wireless slave units are not designated for meter reading, the meter reading of the last wireless slave device 200E having the third meter reading sequence is completed after detecting the calling signal (designated meter reading) 500. The intermittent carrier sense is stopped for 90 × 4 to 30 seconds.
[0132]
(8) The wireless master device 100 transmits a call signal (No. 5) 505.
(9) The wireless slave device 200C restarts the intermittent carrier sense and detects the calling signal (No. 5) 505.
[0133]
(10) The wireless slave device 200C transmits the meter reading data as a response signal 605.
[0134]
(11) The wireless master device 100 receives the response signal 605.
(12) The wireless master device 100 transmits an end signal 705.
[0135]
(13) The wireless slave device 200C receives the end signal 705.
(14) The wireless slave device 200C stops the intermittent carrier sense for 90 × 2 seconds until the meter reading of the last wireless slave device 200E is completed.
[0136]
(15) Hereinafter, the same processing as (8) to (14) for the wireless slave device 200C is performed for the wireless slave devices 200D and 200E.
[0137]
(16) The wireless slave devices 200C, 200D, 200E and other wireless slave devices resume intermittent carrier sense.
[0138]
As described above, in the wireless telemeter system according to the second embodiment, the wireless master unit stores a predetermined order of the wireless slave units, and each bit corresponds to the order of the wireless slave units. A paging signal including a bit string indicating whether or not it is a target of transmission is transmitted. In addition, the wireless slave device stores the order of its own station, intermittently detects the call signal, and confirms that the bit corresponding to the order of its own station in the bit string included in the detected call signal is the object of communication. In the case of the indicated value, the intermittent carrier sense is stopped for a predetermined time obtained based on the bit string.
[0139]
For this reason, the radio | wireless subunit | mobile_unit of a radio | wireless telemeter system can stop intermittent carrier sense except the order of an own station. As a result, in the wireless telemeter system, the wireless slave unit can save power of its own station.
[0140]
The embodiment disclosed this time is to be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an outline of a configuration of a radio telemeter system according to one of first embodiments of the present invention.
FIG. 2 is a block diagram showing a configuration of a wireless master device in the first embodiment.
FIG. 3 is a block diagram showing a configuration of a wireless slave unit in the first embodiment.
FIG. 4 is a functional block diagram showing an outline of functions of a control unit and a storage unit of the wireless master device in the first embodiment.
FIG. 5 is a functional block diagram illustrating an outline of functions of a control unit, a wireless unit, and a storage unit of the wireless slave device in the first embodiment.
FIG. 6 is a diagram showing a configuration of a paging signal transmitted from a wireless master device to a wireless slave device in the first embodiment.
FIG. 7 is a diagram showing a first configuration of a packet of a connection request signal included in a paging signal transmitted from a wireless master device and repeatedly transmitted in the simultaneous meter reading mode in the first embodiment.
FIG. 8 is a diagram showing a second configuration of a packet of a connection request signal included in a paging signal transmitted from a wireless master device and repeatedly transmitted in the simultaneous meter reading mode in the first embodiment.
FIG. 9 is a diagram showing a third configuration of a packet of a connection request signal included in a paging signal transmitted from a wireless master device and repeatedly transmitted in the simultaneous meter reading mode in the first embodiment.
FIG. 10 is a time chart showing an example of a temporal flow of transmission / reception of the wireless master device and a temporal flow of transmission / reception of the wireless slave device and carrier sense in the first embodiment.
FIG. 11 is a diagram showing a configuration of a packet of a connection request signal that is repeatedly transmitted by being included in a paging signal transmitted from a wireless master in the designated meter reading mode in the second embodiment.
FIG. 12 is a diagram illustrating an example of a bit string included in a calling signal in a designated meter reading mode according to the second embodiment.
FIG. 13 is a time chart illustrating an example of a temporal flow of transmission / reception of the wireless master device and a temporal flow of transmission / reception of the wireless slave device and carrier sense in the second embodiment.
[Explanation of symbols]
100 wireless master unit, 110 wireless unit, 111 antenna, 120 storage unit, 121 slave unit storage unit, 130 communication unit, 140 control unit, 141 call signal transmission unit, 142 sequential transmission unit, 150 host computer, 200 wireless slave unit, 210 wireless unit, 211 antenna, 212 intermittent carrier sense unit, 220 storage unit, 221 order storage unit, 230 communication unit, 240 control unit, 241 carrier sense control unit, 242 calculation unit.

Claims (8)

A wireless system comprising a wireless master device and a plurality of wireless slave devices,
The wireless master unit is
Slave unit storage means for storing the order of the wireless slave units in the simultaneous communication mode for communicating with the wireless slave units in a predetermined order;
In the case of the simultaneous communication mode, comprising: a call signal transmission means for transmitting a call signal including a command indicating the simultaneous communication mode and the number of wireless slave devices to be subjected to the simultaneous communication ;
The wireless slave is
Order storage means for storing the order of the own station in the simultaneous communication mode;
Intermittent carrier sense means for intermittently detecting the call signal;
When the detected call signal includes the command indicating the simultaneous communication mode, the local station is based on the order of the local station stored in the order storage unit and the number of the wireless slave units included in the call signal. Calculating means for calculating the time from the end of the communication until the end of the communication of the last wireless slave unit,
A wireless system comprising: a time calculated by the calculation means; and carrier sense control means for prohibiting detection by the intermittent carrier sense means. Said computing means, said you further calculates the time from detection of the call signal including a command indicating a broadcast communication to said local station for communication is started, the radio system according to claim 1. The wireless master device further comprises an order transmission means for transmitting the order of the wireless slave devices during the simultaneous communication mode to the wireless slave device,
The wireless system according to claim 1, wherein the wireless slave device further comprises order receiving means for receiving the order of the own station in the simultaneous communication mode from the wireless master device. A wireless system comprising a wireless master device and a plurality of wireless slave devices,
The wireless master unit is
A handset storage means for storing a predetermined order of the wireless handset;
Call signal transmitting means for transmitting a call signal including a bit string indicating whether each bit corresponds to the order of the wireless slave units and is a communication target;
The wireless slave is
Order storage means for storing the order of the station;
Intermittent carrier sense means for intermittently detecting the call signal;
If the bit corresponding to the order of the station in the bit string included in the detected call signal is a value indicating communication, the communication of the station is terminated based on the bit string included in the call signal. And calculating means for calculating the time from the end of the communication of the last wireless slave unit,
A wireless system comprising: a time calculated by the calculation means; and carrier sense control means for prohibiting detection by the intermittent carrier sense means. Said computing means, said call signal you further calculates the time from detection until the communication of the own station starts the radio system according to 請 Motomeko 4. When the bit corresponding to the order of the own station of the bit string included in the detected call signal is a value indicating that communication is not an object of communication, the calculation means detects the call signal and detects the last wireless slave unit you calculating the time until the communication is finished, the radio system according to claim 4.   2. The wireless system according to claim 1, wherein the intermittent carrier sense means restarts the carrier sense even when the intermittent carrier sense is stopped when an emergency call factor occurs. A wireless slave device having a simultaneous communication mode for communicating with a wireless master device in a predetermined order,
Order storage means for storing the order of the own station in the simultaneous communication mode;
An intermittent carrier sensing means for detecting the radio personal station of the number to be the simultaneous communication with command indicating the previous SL simultaneous communication modes including call signal intermittently,
When the detected call signal includes a command indicating the simultaneous communication mode, the order of the local station in the simultaneous communication mode stored in the order storage means and the number of the wireless slave units included in the call signal And calculating means for calculating the time from the end of the communication of the own station until the end of the communication of the last wireless slave unit,
A wireless slave device comprising: a carrier sense control means for prohibiting detection by the intermittent carrier sense means for a time computed by the computing means .

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