JP2004173902A - Game machine tester - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine tester capable of using in other case than programmed testing. <P>SOLUTION: A test board 90 tests each control data ROM55B, 56B and 70B provided in each board 55, 56 and 70 and outputs a game command from a main control board 50 to each board 55, 56 and 70 during a relaying state and so it can be used as a relay board and a distributor. By this, number of parts is reduced compared when providing the relay board and the distributor additionally and the test board 90 forms a basic structure and so attachment to a pachinko game machine 10 can be easily done. Also, the output part of the test board 90 is shared in use between for game command and for test command, and so the number of parts can be reduced. <P>COPYRIGHT: (C)2004,JPO

Description

【００６７】
表１に示した各カウンタは、電源投入時には「０」に設定され、乱数更新処理（Ｓ５）が実行される毎に（例えば、２ｍｓｅｃ毎に）、１インクリメントされる。各カウンタは、カウンタの数値範囲の上限値を越えた場合には、「０」にリセットされて、再び「０」から１インクリメントされる。このように更新された各カウンタの数値は、前記ＲＡＭ５１Ｂのカウンタ数値記憶領域に逐一記憶され、この乱数更新処理（Ｓ５）から抜ける。
【００６８】
乱数更新処理（Ｓ５）から抜けると、センサー入力処理（Ｓ４）で保存したセンサー検出情報が始動入賞口１４への入球によるものか否かがチェックされる（Ｓ６）。具体的には、始動入賞口１４に備えたセンサーが入賞球を検出したか否かをチェックする。そして、始動入賞口１４への入賞球を検出した場合には（Ｓ６でＹｅｓ）、乱数取得処理（Ｓ７）を実行する。一方、始動入賞口１４への入賞球を検出していない場合には、（Ｓ６でＮｏ）、乱数取得処理（Ｓ７）を実行せずにステップＳ８に進む。
【００６９】
乱数取得処理（Ｓ７）では、前記ＲＡＭ５１Ｂのカウンタ数値記憶領域に記憶されているカウンタの数値を取り出して、ＲＡＭ５１Ｂに別途設定した乱数値記憶領域に記憶する。
【００７０】
乱数取得処理（Ｓ７）から抜けると、判定条件が成立しているか否かがチェックされる（Ｓ８）。ここで、「判定条件」とは、遊技の当たり外れに係る判定を実行するために必要な条件をいう。本実施形態では、例えば、このステップＳ８を実行した時点で、以下の▲１▼〜▲３▼の３つの条件が成立していることを「判定条件の成立」としている。
▲１▼「当たり遊技」が実行されている最中ではないこと。
▲２▼特別図柄８０，８１，８２を変動表示中でないこと。
▲３▼保留記憶数が１以上であること。
【００７１】
▲１▼〜▲３▼の条件のうちの少なくとも１つが不成立の場合には、その他の処理（Ｓ１３）にジャンプする。一方、これら条件が全て成立している場合には、大当たり判定処理（Ｓ９）、リーチ有無決定処理（Ｓ１０）、確定停止特別図柄決定処理（Ｓ１１）、変動パターン決定処理（Ｓ１２）が実行される。
【００７２】
なお、本実施形態では、上記▲１▼〜▲３▼の３つを「判定条件」としたが、「判定条件」は３つでなくてもよく、各条件内容も種々の内容に設定してもよい。
【００７３】
上記判定条件が成立した場合には、最初に大当たり判定処理（Ｓ９）が実行される。この処理（Ｓ９）が実行されると、まず高確率状態か低確率状態かがチェックされ、低確率状態時には、取得した大当たり判定用乱数（ラベル−ＴＲＮＤ−Ａ）が「５」又は「５００」の２つの当たり数値の何れかと一致したか否かがチェックされる。一方、高確率状態時には、取得した大当たり判定用乱数（ラベル−ＴＲＮＤ−Ａ）が、「５」、「５０」、「１００」、「２００」、「３００」、「３５０」、「４００」、「４５０」、「５００」、「６００」の１０個の当たり数値の何れかと一致したか否かがチェックされる。
【００７４】
そして、大当たり判定用乱数（ラベル−ＴＲＮＤ−Ａ）が何れの当たり数値と一致しなかった場合には、この処理（Ｓ９）を抜ける。一方、大当たり判定用乱数（ラベル−ＴＲＮＤ−Ａ）が何れかの当たり数値と一致した場合には、大当たりフラグＡ１をセットして、この処理（Ｓ９）を抜ける。
【００７５】
次いで、リーチ有無決定処理（Ｓ１０）が実行される。この処理（Ｓ１０）が実行されると、大当たりフラグＡ１がセットされているか否かがチェックされる。大当たりフラグＡ１がセットされている場合、即ち「大当たり状態」の場合には、リーチ有り（リーチ状態移行可）と決定して、リーチフラグＢをセットし、この処理（Ｓ１０）を抜ける。つまり、大当たりになった場合には、必ずリーチ状態になる。
【００７６】
一方、大当たりフラグＡ１がセットされていない場合、即ち「外れ」の場合には、リーチ有無決定乱数（ラベル−ＴＲＮＤ−Ｒ１）が、「２４」又は「４９」に一致した場合にのみ、リーチ有りと決定して、リーチフラグＢにセットし、この処理（Ｓ１０）を抜ける。また、リーチ有無決定乱数（ラベルーＴＲＮＤ−Ｒ１）が、「２４」又は「４９」に一致しなかった場合には、リーチ無しと決定して、リーチフラグＢをセットせずに初期状態のままにする。
【００７７】
次いで、確定停止特別図柄決定処理（Ｓ１１）が実行される。この処理（Ｓ１１）が実行されると、大当たりフラグＡ１がセットされているか否かがチェックされ、大当たりフラグＡ１がセットされている場合、即ち大当たりの場合には、大当たり特別図柄乱数（ラベル−ＴＲＮＤ−ＡＺ１）の数値に対して予め決められている図柄の組合せを、大当たり図柄組合せとして決定して、そのコマンドをＲＡＭ５１Ｂのコマンドバッファに格納する。即ち、例えば、大当たり特別図柄乱数（ラベル−ＴＲＮＤ−ＡＺ１）＝「１」の場合には、確定大当たり図柄組合せとして、表示部３４に「１」が３つ並んだぞろ目である「１ １ １」が表示されるコマンドに決定する。また、大当たり特別図柄乱数（ラベル−ＴＲＮＤ−ＡＺ１）＝「７」の場合には、確定大当たり図柄組合せとして、表示部３４に「７」が３つ並んだぞろ目である「７ ７ ７」が表示されるコマンドに決定する。他の大当たり特別図柄乱数（ラベル−ＴＲＮＤ−ＡＺ１）においても同様に、大当たり特別図柄乱数（ラベル−ＴＲＮＤ−ＡＺ１）の数値に応じて、「０」〜「１１」の数字図柄の何れかが３つ並んだぞろ目を、確定大当たり図柄組合せとして決定して、それぞれに対応するコマンドをＲＡＭ５１Ｂのコマンドバッファに格納する。
【００７８】
一方、大当たりフラグＡ１がセットされていない場合、即ち外れの場合には、３つの特別図柄乱数（ラベル−ＴＲＮＤ−Ｂ１，Ｂ２，Ｂ３）に基づいて、各特別図柄８０，８１，８２がぞろ目とならない組合せに決定し、そのコマンドをコマンドバッファに格納する。ここで、リーチフラグＢがセットされている場合には、左特別図柄８０と右特別図柄８２とが同一図柄で、中特別図柄８１のみ左・右特別図柄８０，８２と異なる図柄組合せに決定する。具体的には、表示部３４において、「１ ２ １」や「３ ５ ３」の如く表示するコマンドを決定する。つまり、変動表示の過程でリーチ状態になるが、最終的には、外れが確定するように停止表示の図柄組み合わせをセットする。
【００７９】
一方、リーチフラグＢがセットされていない場合には、各特別図柄８０，８１，８２が全て異なる図柄組合せに決定する。具体的には、表示部３４において、「１ ２ ３」や「７ ５ ３」の如く表示するコマンドに決定する。つまり、変動表示の過程で、リーチにもならず、外れが確定するように停止表示の図柄組み合わせをセットする。
【００８０】
次いで、変動パターン決定処理（Ｓ１２）が実行される。この処理（Ｓ１２）が実行されると、大当たりフラグＡ１、変動パターン決定乱数（ラベル−ＴＲＮＤ−Ｔ１）及びリーチフラグＢによって、大当たり時や外れ時の変動パターンが設定される。
【００８１】
この処理（Ｓ１２）の後、その他の処理（Ｓ１３）が行われる。その他の処理（Ｓ１３）には、確率変動報知処理が含まれている。確率変動報知処理では、大当たり遊技が終了後に、大当たり図柄決定用乱数（ラベル−ＴＲＮＤ−ＡＺ１）の取得数値がチェックされ、大当たり成立時における各特別図柄８０，８１，８２の組み合わせが「１」、「３」、「５」、「７」、「９」、「１１」の何れかのぞろ目であったときには、遊技が確率変動状態（高確率状態）に移行することを遊技者に報知する。一方、大当たり成立時における各特別図柄８０，８１，８２の組み合わせが「２」、「４」、「６」、「８」、「１０」、「１２」の何れかのぞろ目であったときには、確率変動状態とならず、次回の大当たりまで通常遊技状態（低確率状態）を継続することを遊技者に報知する。
【００８２】
その他の処理（Ｓ１３）では、この確率変動報知処理の他に、本発明に深く関連しない処理を実行して、メイン制御用プログラムＭから抜ける。そして、２ｍｓｅｃ後に、再びメイン制御用プログラムＭがランされ、ステップＳ１から繰り返される。以上が、メイン制御用プログラムＭの説明である。
【００８３】
さて、メイン制御用プログラムＭと同じ周期（例えば、２．０００ｍｓｅｃ）で、表示制御基盤７０に備えた表示制御用ＣＰＵ７０Ａが、表示制御用プログラムＮを、表示制御データＲＯＭ７０Ｂから取り出してランする。なお、音声制御用プログラム及び発光体制御用プログラムについては、表示制御用プログラムＮと同様な構成なので説明を省略する。
【００８４】
この表示制御用プログラムＮが実行されると、メイン制御用プログラムＭの確定停止特別図柄決定処理（Ｓ１１）及び変動パターン決定処理（Ｓ１２）で決定された確定停止特別図柄及び変動パターンの画像が表示制御基盤７０で作成され、表示部３４に表示される。また、検査基盤９０の切替スイッチ９４が検査状態とされ、検査する基盤として、表示制御基盤７０が選択された場合には、表示制御用ＣＰＵ７０Ａが表示制御データＲＯＭ７０Ｂ内のデータを、検査基盤９０に出力する。
【００８５】
表示制御用プログラムＮは図７に示されており、まず電源投入時か否かがチェックされる（Ｓ６０）。電源投入時である場合（Ｓ６０でＹｅｓ）には、初期設定（Ｓ６１）として、例えばスタックの設定、定数設定、ＣＰＵの設定、ＳＩＯ、ＰＩＯ、ＣＴＣ（割り込み時間用コントローラ）の設定等が行われる。なお、電源投入時のみに必要な処理は、表示制御用プログラムＮが、電源投入後の１回目にランされたときだけ実行され、それ以降は実行されない。
【００８６】
次に、コマンド入力処理（Ｓ６２）が行われ、メイン制御基盤５０からの遊技コマンドや検査基盤９０からの検査コマンドを入力する。より詳細には、図９及び図１０に示す検査プログラムＴのステップＳ２６で出力された遊技コマンドやステップＳ３３で出力された検査開始コマンド及びステップＳ５８で出力された次データ要求コマンドを入力する。
【００８７】
次に、コマンド入力処理（Ｓ６２）で入力されたコマンドが、検査基盤９０からの検査開始コマンドであるか否かがチェックされる（Ｓ６３）。検査開始コマンドではない場合には（Ｓ６３でＮｏ）、ステップＳ６５に進み、検査開始コマンドである場合には（Ｓ６３でＹｅｓ）、検査フラグをＯＮとしてから（Ｓ６４）、ステップＳ６５に進む。
【００８８】
ステップＳ６５では、検査フラグがＯＮであるか否かがチェックされる。検査フラグがＯＮではない場合（Ｓ６５でＮｏ）、即ち切替スイッチ９４が中継状態のときは、その他の遊技機処理が行われ（Ｓ６６）、メイン制御基盤５０及び検査基盤９０以外の他の制御基盤５５，５６等からのサブ遊技コマンドを入力する。その後、表示制御処理（Ｓ６８）が行われ、メイン制御基盤５０からの遊技コマンドや他の制御基盤５５，５６等からのサブ遊技コマンドに基づいて、表示制御基盤７０において画像が作成され表示部３４にて表示する。
【００８９】
ここで、検査フラグがＯＮであった場合には（Ｓ６５でＹｅｓ）、検査処理（Ｓ６７）が実行される。検査処理（Ｓ６７）は、図８に示されており、まず、検査データ設定処理（Ｓ７０）が実行され、表示制御データＲＯＭ７０Ｂに記憶された各種データの中から、検査基盤９０に出力するデータを設定する。具体的には、表示制御データＲＯＭ７０Ｂ内のアドレスに基づいて、０番地のデータから順に設定される。
【００９０】
次いで、検査データ出力処理（Ｓ７１）が実行され、検査データ設定処理（Ｓ７０）で設定されたデータが、検査基盤９０に出力される。その後、表示制御データＲＯＭ７０Ｂ内の全てのデータを検査基盤９０に出力したか否かがチェックされ（Ｓ７２）、全てのデータが出力されていない場合、即ち表示制御データＲＯＭ７０Ｂの検査が完了していない場合には、直ちにこの処理（Ｓ６７）を抜ける一方、全てのデータを出力した場合には（Ｓ７２でＹｅｓ）、検査フラグをＯＦＦとして（Ｓ７３）、この処理（Ｓ６７）を抜ける。以上が、表示制御用プログラムＮの説明である。
【００９１】
次に図９に基づいて検査プログラムＴについて説明する。メイン制御用プログラムＭと同じ周期（例えば、２．０００ｍｓｅｃ）で、検査基盤９０に備えた検査用ＣＰＵ９３が、検査プログラムＴを、検査データＲＯＭ９１から取り出してランする。すると、電源投入時か否かがチェックされ、電源投入時である場合（Ｓ２０でＹｅｓ）には、初期設定（Ｓ２１）として、例えばスタックの設定、定数設定、ＣＰＵの設定、ＳＩＯ、ＰＩＯ、ＣＴＣ（割り込み時間用コントローラ）の設定等が行われる。なお、電源投入時のみに必要な処理は、検査プログラムＴが、電源投入後の１回目にランされたときだけ実行され、それ以降は実行されない。
【００９２】
検査プログラムＴが、電源投入後、２回目以降にランされたときには（Ｓ２０でＮｏ）、切替スイッチ９４が検査状態となっているか否かがチェックされる（Ｓ２２）。切替スイッチ９４が検査状態でない場合には（Ｓ２２でＮｏ）、メイン制御基盤５０からの遊技コマンドを各基盤５５，５６，７０に送信可能と判断して、メイン制御基盤５０から、メインプログラムＭのステップＳ３（図６を参照）において出力された遊技コマンドが入力したか否かを判断する（Ｓ２３）。メイン制御基盤５０から遊技コマンドが入力していないときには（Ｓ２３でＮｏ）、直ちに検査プログラムＴを抜ける。メイン制御基盤５０から遊技コマンドが入力したときには（Ｓ２３でＹｅｓ）、その遊技コマンドが表示制御基盤７０に対するものか否かがチェックされる（Ｓ２４）。すると、遊技コマンドと共に入力したストローブ信号に基づいて検査用ＣＰＵ９３が遊技コマンドの出力先を判別し、表示制御基盤７０に対するものであった場合には（Ｓ２４でＹｅｓ）、入力された遊技コマンドを表示制御基盤７０に出力する（Ｓ２６）。
【００９３】
一方、入力された遊技コマンドが、表示制御基盤７０に対するものでなかった場合には（Ｓ２４でＮｏ）、音声制御基盤５６に対するものか否かがチェックされる（Ｓ２５）。音声制御基盤５６に対するものであった場合には（Ｓ２５でＹｅｓ）、入力された遊技コマンドを音声制御基盤５６に出力する（Ｓ２７）。また、音声制御基盤５６に対するものでなかった場合（Ｓ２５でＮｏ）、即ち発光体制御基盤５５に対するものであった場合には、入力された遊技コマンドを発光体制御基盤５５に出力する（Ｓ２８）。
【００９４】
さて、切替スイッチ９４が検査状態の場合（Ｓ２２でＹｅｓ）には、各制御データＲＯＭ５５Ｂ，５６Ｂ，７０Ｂの検査が実行される。具体的には、まず、検査中フラグがＯＮか否か（Ｓ２９）がチェックされ、検査中フラグがＯＮの場合には、ステップＳ３５にジャンプする。検査中フラグがＯＮではない場合には（Ｓ２９）、切替スイッチ９４によって選択された基盤が、各基盤５５，５６，７０のうちの何れであるかを判別し、選択された基盤に対応する基準ＲＯＭデータを検査データＲＯＭ９１から読み出してセットする（Ｓ３０）。
【００９５】
次いで、検査開始ボタンがＯＮか否かがチェックされ（Ｓ３１）、ＯＮではなかった場合には（Ｓ３１でＮｏ）、検査を開始しないと判断して、ステップＳ２２を実行する。検査開始ボタンがＯＮにされた場合には（Ｓ３１でＹｅｓ）、検査編集エリアの初期化を行う（Ｓ３２）。その後、各基盤５５，５６，７０のうちの切替スイッチ９４によって選択された基盤に検査開始コマンドが送信され（Ｓ３３）、検査中フラグをＯＮとしててから（Ｓ３４）、データ判定処理（Ｓ３５）が実行される。なお、データ判定処理（Ｓ３５）を抜けると、ステップＳ２２が実行され、切替スイッチ９４が検査状態とされている間は、ステップＳ２２〜ステップＳ３５の処理が繰り返し実行される。
【００９６】
データ判定処理（Ｓ３５）は図１０に示されており、まず選択した制御データＲＯＭの検査が完了したか否かがチェックされ（Ｓ４０）、検査が完了した場合には（Ｓ４０でＹｅｓ）直ちにこの処理（Ｓ３５）を抜ける。一方、検査が完了していない場合には（Ｓ４０でＮｏ）、データ入力処理が実行され（Ｓ４１）、検査する基盤の制御データＲＯＭから出力（図８のステップＳ７１）されたデータを取り込む。次いで、データ入力処理（Ｓ４１）によって、新規なデータが入力されたか否かがチェックされ（Ｓ４２）、新規なデータが入力されていない場合には（Ｓ４２でＮｏ）、直ちにこの処理（Ｓ３５）を抜ける。一方、新規なデータが入力された場合には（Ｓ４２でＹｅｓ）、切替スイッチ９４に基づいて、入力されたデータが表示制御データＲＯＭ７０Ｂのデータか否かがチェックされる（Ｓ４３）。入力されたデータが表示制御データＲＯＭ７０Ｂのデータであった場合には（Ｓ４３でＹｅｓ）、表示制御検査処理（Ｓ５５）が実行される。より詳細には、ステップＳ３０で設定した基準ＲＯＭデータから、入力された表示制御データＲＯＭ７０Ｂのデータのアドレスと同一のアドレスのデータを読み出す。そして、これらのデータを照合して、表示制御データＲＯＭ７０Ｂのデータの正否を判定する。次いで、検査基盤側検査データ設定処理（Ｓ５６）が実行され、次のデータを検査するための設定が行われる。
【００９７】
その後、表示制御データＲＯＭ７０Ｂ内の全てのデータの検査が終了したか否かがチェックされ（Ｓ５７）、終了していない場合には（Ｓ５７でＮｏ）、表示制御基盤７０に次データ要求コマンドを出力して（Ｓ５８）、表示制御基盤７０に表示制御データＲＯＭ７０Ｂ内の次のアドレスのデータを出力させてから（図８のステップＳ７１）、この処理（Ｓ３５）を抜ける。一方、表示制御データＲＯＭ７０Ｂ内の全てのデータの検査が終了した場合には、検査結果を結果表示部９５に出力し（Ｓ４９）、検査中フラグをリセットしてから（Ｓ５０）、この処理（Ｓ３５）を抜ける。
【００９８】
入力されたデータが音声制御データＲＯＭ５６Ｂであった場合には（Ｓ４３でＮｏ，Ｓ４４でＹｅｓ）、音声制御検査処理（Ｓ５１）が実行される。より詳細には、ステップＳ３０で設定した基準ＲＯＭデータから、入力された音声制御データＲＯＭ５６Ｂのデータのアドレスと同一のアドレスのデータを読み出す。そして、これらのデータを照合して、音声制御データＲＯＭ５６Ｂのデータの正否を判定する。次いで、検査基盤側検査データ設定処理（Ｓ５２）が実行され、音声制御データＲＯＭ５６Ｂ内の全てのデータの検査が完了したか否かがチェックされる（Ｓ５３）。完了していない場合には（Ｓ５３でＮｏ）、音声制御基盤５６に次データ要求コマンドを出力して（Ｓ５４）、この処理（Ｓ３５）を抜ける。一方、音声制御データＲＯＭ５６Ｂ内の全てのデータの検査が終了した場合には、前述した表示制御基盤７０の時と同様に、検査結果を結果表示部９５に出力し（Ｓ４９）、検査中フラグをリセットしてから（Ｓ５０）、この処理（Ｓ３５）を抜ける。
【００９９】
入力されたデータが発光体制御データＲＯＭ５５Ｂであった場合（Ｓ４３でＮｏ，Ｓ４４でＮｏ）は、発光体制御検査処理（Ｓ４５）実行される。より詳細には、ステップＳ３０で設定した基準ＲＯＭデータから、入力された発光体制御データＲＯＭのデータのアドレスと同一のアドレスのデータを読み出す。そして、これら２つのデータを照合して、発光体制御データＲＯＭ５５Ｂのデータの正否を判定する。次いで、検査基盤側検査データ設定処理（Ｓ４６）が実行され、発光体制御データＲＯＭ５５Ｂ内の全てのデータの検査が完了したか否かがチェックされる（Ｓ４７）。完了していない場合には（Ｓ４７でＮｏ）、発光体制御基盤５５に次データ要求コマンドを出力して（Ｓ４８）、この処理（Ｓ３５）を抜ける。一方、発光体制御データＲＯＭ５５Ｂ内の全てのデータの検査が終了した場合には、検査結果を結果表示部９５に出力し（Ｓ４９）、検査中フラグをリセットしてから（Ｓ５０）、この処理（Ｓ３５）を抜ける。以上がデータ判定処理（Ｓ３５）の説明であり、検査プログラムＴの説明である。
【０１００】
本実施形態の検査基盤９０の構成は以上であって、次に動作説明を行う。各基盤５５，５６，７０に備えた各制御データＲＯＭ５５Ｂ，５６Ｂ，７０Ｂを検査する場合には、切替スイッチ９４を検査状態として検査する基盤を選択する。例えば、検査する基盤を表示制御基盤７０に設定して、検査開始ボタンをＯＮすると、表示制御基盤７０に対応した出力コネクタ４２から検査プログラムＴに基づく検査コマンドが出力され、表示制御基盤７０に備えた表示制御データＲＯＭ７０Ｂの検査が開始される。ここで、表示制御データＲＯＭ７０Ｂには、メイン制御基盤５０からの遊技コマンドに基づいて表示部３４の表示を決定する表示制御用プログラムＮが記憶されているので、表示制御データＲＯＭ７０Ｂを検査することによって、この表示制御用プログラムＮの正否をチェックすることができる。そして、検査プログラムＴによる検査が完了すると、検査結果が結果表示部９５に表示され、検査員はこの表示を視認して検査結果を容易に知ることができる。
【０１０１】
表示表示制御データＲＯＭ７０Ｂの検査が終了して、例えば、音声制御基盤５６に備えた音声制御データＲＯＭ５６Ｂを検査する場合には、切替スイッチ９４によって音声制御基盤５６を選択する。そして検査開始ボタンをＯＮとすると、前述のようにして音声制御データＲＯＭ５６Ｂの検査が行われ、音声制御データＲＯＭ５６Ｂに記憶された音声制御用プログラムが検査される。そして検査が終了すると、結果表示部９５に検査結果が表示される。
【０１０２】
表示表示制御データＲＯＭ７０Ｂの検査が終了して、発光体制御基盤５５に備えた発光体制御データＲＯＭ５５Ｂを検査する場合には、切替スイッチ９４によって発光体制御基盤５５を選択する。すると、前述のように発光体制御データＲＯＭ５５Ｂの検査が行われ、発光体制御用プログラムが検査されて、その検査結果が表示される。
【０１０３】
ところで、各基盤５５，５６，７０を検査中、即ち、切替スイッチ９４が検査状態となっているときは、メイン制御基盤５０からの遊技コマンドが各基盤５５，５６，７０に送信されない。これにより、各基盤５５，５６，７０の検査をよりスムーズに行うことができる。
【０１０４】
さて、パチンコホールが営業中、即ち検査基盤９０を検査手段として使用しないときは、検査基盤９０に備えた切替スイッチ９４を中継状態としておく。すると、メイン制御基盤５０から出力された遊技コマンド、具体的には、表示部３４での表示やスピーカ５９Ｓから発生させる音声及びサイドランプ２２の発光態様等の制御に関わるコマンドは、検査基盤９０の入力コネクタ４１に入力し、各遊技コマンドの出力先に応じて、出力コネクタ４２，４２，４２から、それぞれ対応する各基盤５５，５６，７０に出力される。そして、これにより、各基盤５５，５６，７０がメイン制御基盤５０からの遊技コマンドに応じて制御を行うことが可能となり、パチンコ遊技機１０で遊技を行うことが可能となる。
【０１０５】
このように、本実施形態の検査基盤９０は、各基盤５５，５６，７０の検査を行うと共に、中継状態時には、メイン制御基盤５０からの遊技コマンドを、各基盤５５，５６，７０に出力するので、中継基盤及び分配器としても利用できる。これにより、中継基盤及び分配器を別途設けた場合に比べて部品点数の削減が図られる。また、検査基盤９０は、基盤構造をなすので、パチンコ遊技機１０への取り付けを容易に行うことができる。
【０１０６】
＜第２実施形態＞
本実施形態は、図１２に示されており、検査基盤９０から出力するコマンド（検査コマンド、遊技コマンド）の出力先の選択及び切り替え方法が前記第１実施形態と異なる。以下、第１実施形態と異なる構成に関してのみ説明し、同じ構成の部位には、第１実施形態と同一符号を付して、重複説明は省略する。なお、同図では、表示制御基盤７０と音声制御基盤５６に対応する構成のみが示されているが、発光体制御基盤５５に対応する構成もこれらと同様な構成となっている。
【０１０７】
本実施形態の検査基盤９０には、メイン制御基盤５０から各基盤５５，５６，７０への遊技コマンド用のスリーステートバッファ３０，３０，３０と、検査用ＣＰＵ９３から各基盤５５，５６，７０への検査コマンド（検査開始コマンド、次データ要求コマンド）用のスリーステートバッファ３１，３１，３１とが備えられている。
【０１０８】
切替スイッチ９４が検査状態のときは、検査用ＣＰＵ９３から、デコーダ９６に所定のコードが入力され、遊技コマンド用のスリーステートバッファ３０，３０，３０が禁止状態とされると共に、検査コマンド用のスリーステートバッファ３１，３１，３１が許可状態とされる。さらに、デコーダ９８に所定のコードが入力され、各基盤５５，５６，７０のうちの選択された基盤に対応したラッチ９７のみが許可状態とされ、他の２つのラッチ９７，９７が禁止状態とされる。これにより、各基盤５５，５６，７０のうちの何れかの基盤を検査しているときは、メイン制御基盤５０からの遊技コマンドを各基盤５５，５６，７０に送信できないようにすると共に、各基盤５５，５６，７０のうちの検査対象の基盤に対してのみ、検査コマンドを送信することが可能となる。
【０１０９】
切替スイッチ９４が中継状態のときは、検査用ＣＰＵ９３からデコーダ９６に所定のコードが入力され、遊技コマンド用のスリーステートバッファ３０，３０，３０が許可状態とされると共に、検査コマンド用のスリーステートバッファ３１，３１，３１が禁止状態とされる。これにより、遊技を行っているとき、即ち、切替スイッチ９４を中継状態としているときは、メイン制御基盤５０からの遊技コマンドが、検査基盤９０を通過して各基盤５５，５６，７０に送信される。即ち、検査基盤９０は、遊技コマンドについての処理を一切行わず、入力した遊技コマンドをそのまま各基盤５５，５６，７０に出力する。
【０１１０】
このように、本実施形態によれば、切替スイッチ９４が中継状態のときに、メイン制御基盤５０から検査基盤９０に入力した遊技コマンドが、スリーステートバッファ３０，３０，３０を通過して各基盤５５，５６，７０に送信される。これにより、検査用ＣＰＵ９３が遊技コマンドの出力先を判別してから、各基盤５５，５６，７０に送信した場合に比べて、検査用ＣＰＵ９３の処理負担を軽減することができる。また、検査基盤９０は、入力した遊技コマンドをそのまま各基盤５５，５６，７０に出力しているので、メイン制御基盤５０と各基盤５５，５６，７０とをハーネス４５によって直接接続しても、各基盤５５，５６，７０は制御を行うことができる。これにより、検査基盤９０が取り外された場合でも、パチンコ遊技機１０は遊技を行うことができる。
【０１１１】
＜他の実施形態＞
本発明は、前記実施形態に限定されるものではなく、例えば、以下に説明するような実施形態も本発明の技術的範囲に含まれ、さらに、下記以外にも要旨を逸脱しない範囲内で種々変更して実施することができる。
（１）前記第１及び第２実施形態においては、本発明の検査基盤９０をパチンコ遊技機１０に備えていたが、遊技機であれば、コイン遊技機やスロットマシン等に備えていてもよい。
【０１１２】
（２）各コネクタ４０，４１，４２，４３は、メイン制御基盤５０の出力コネクタ４０と検査基盤９０の出力コネクタ４２とが同一構成であって、検査基盤９０の入力コネクタ４１と各基盤５５，５６，７０の入力コネクタ４３とが同一構成であれば、全てのコネクタ４０，４１，４２，４３が同一構成であってもよいし、出力コネクタ４０，４２と入力コネクタ４１，４３とが異なる構成でもよい。
【０１１３】
（３）前記第１及び第２実施形態では、検査基盤９０は、表示制御基盤７０、音声制御基盤５６及び発光体制御基盤５５に備えられた制御データＲＯＭ７０Ｂ，５６Ｂ，５５Ｂを検査していたが、他の基盤（例えば、メイン制御基盤５０、電源基盤及び払出制御基盤等）に備えられた制御データＲＯＭを検査するように構成してもよい。
【０１１４】
（４）前記第１及び第２実施形態では、出力コネクタ４０と入力コネクタ４１との間、及び出力コネクタ４２と入力コネクタ４３との間は何れもハーネス４５を介して接続されていたが、例えば、何れか一方の間のみをハーネス４５を介して接続し、他方の間はコネクタ同士を直接接続させてもよい。
【０１１５】
（５）前記第１及び第２実施形態では、切替スイッチ９４を操作して、検査する制御データＲＯＭを選択していたが、切替スイッチ９４を検査状態としておけば、検査基盤９０が各制御データＲＯＭ５５Ｂ，５６Ｂ，７０Ｂを順番に検査するようにしてもよい。
【０１１６】
（６）前記第１及び第２実施形態では、検査結果が、結果表示部９５に表示されていたが、表示器３４に表示されるようにしてもよい。
【０１１７】
（７）検査基盤９０は、常にパチンコ遊技機１０に備えられていてもよいし、検査時のみパチンコ遊技機１０に取り付けるようにしてもよい。
【０１１８】
（８）前記第１実施形態では、メイン制御基盤５０と音声制御基盤５６及び表示制御基盤７０とを中継するラインと、検査用ＣＰＵ９３から音声制御基盤５６及び表示制御基盤７０に検査信号を出力するラインとを共通にしてあったが（図４参照）、図１３に示すように、メイン制御基盤５０と音声制御基盤５６及び表示制御基盤７０とを中継するラインと、検査用ＣＰＵ９３から音声制御基盤５６及び表示制御基盤７０に検査信号を出力するラインとを別々に分けた構成にしてもよい。
【０１１９】
（９）前記第１及び第２実施形態では、電気基板上に検査データＲＯＭ９１（検査用記憶手段）と入力コネクタ４１（入力部）と出力コネクタ４２（出力部）とを実装して一体的としていたが、本発明の「一体的」とはこれに限定されず、例えば、検査用記憶手段と入力部と出力部とを別々の電気基板上に実装して、これら各電気基板同士を固定して一体的としてもよいし、検査用記憶手段と入力部と出力部とを合わせてパッケージした素子とすることで一体的としてもよい。
【図面の簡単な説明】
【図１】本発明の第１実施形態の検査基盤を適用したパチンコ遊技機の正面図
【図２】パチンコ遊技機の背面図
【図３】パチンコ遊技機の電気的構成を示すブロック図
【図４】メイン制御基盤、表示制御基盤及び音声制御基盤の間における信号の送受信を示すブロック図
【図５】検査基盤の電気的構成を示すブロック図
【図６】メイン制御プログラムを示すフローチャート
【図７】表示制御用プログラムを示すフローチャート
【図８】検査処理を示すフローチャート
【図９】検査プログラムを示すフローチャート
【図１０】データ判定処理を示すフローチャート
【図１１】メイン制御基盤と検査基盤と表示制御基盤の接続部分の正面図
【図１２】第２実施形態に係る検査基盤の電気的構成を示すブロック図
【図１３】他の実施形態（８）に係る信号の送受信を示すブロック図
【符号の説明】
１３…表示装置（表示器）
２２…サイドランプ（発光体）
４０…出力コネクタ（結合手段）
４１…入力コネクタ（入力部、上位側結合手段）
４２…出力コネクタ（出力部、下位側結合手段）
４３…入力コネクタ（結合手段）
５０…メイン制御基盤
５５…発光体制御基盤
５５Ｂ…発光体制御データＲＯＭ（制御用記憶手段）
５６…音声制御基盤
５６Ｂ…音声制御データＲＯＭ（制御用記憶手段）
５９Ｓ…スピーカ（音声発生手段）
７０…表示制御基盤
７０Ｂ…表示制御データＲＯＭ（制御用記憶手段）
９０…検査基盤（遊技機検査器）
９１…検査データＲＯＭ（検査用記憶手段）
９４…切替スイッチ（切り替え手段、選択手段）
９５…結果表示部（表示手段）
Ｍ…メイン制御プログラム（制御プログラム）
Ｎ…表示制御プログラム（制御プログラム）[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a gaming machine inspection device for inspecting a pachinko gaming machine.
[0002]
[Prior art]
BACKGROUND ART Conventionally, there has been a gaming machine inspection device for inspecting a program stored in a game control device of a gaming machine (for example, Patent Document 1).
[0003]
[Patent Document 1]
JP-A-10-290876 (paragraphs [0009] to [0014], FIG. 3)
[0004]
[Problems to be solved by the invention]
However, the conventional gaming machine inspection device is not used except at the time of program inspection, and effective utilization of the gaming machine inspection device has been desired.
[0005]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a gaming machine inspection device that can be used at times other than the time of program inspection.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a gaming machine inspection apparatus according to the first aspect of the present invention is connected to a gaming machine having a control storage means for storing a control program and a game control means for executing the control program. A gaming machine inspection device for inspecting a control program, comprising an inspection storage device storing an inspection program, capable of transmitting an inspection signal based on the inspection program to the game control device, The present invention is characterized in that an input section for inputting an electric signal and an output section for outputting the electric signal input from the input section to the outside of the gaming machine inspector are provided.
[0007]
According to a second aspect of the present invention, in the gaming machine inspection apparatus according to the first aspect, an inspection storage unit, an input unit, and an output unit are integrally provided.
[0008]
According to a third aspect of the present invention, in the gaming machine inspection apparatus according to the second aspect, the inspection storage unit, the input unit, and the output unit are provided on the same electric board.
[0009]
According to a fourth aspect of the present invention, in the gaming machine inspection apparatus according to any one of the first to third aspects, an electric signal input to the input unit and an electric signal output from the output unit are the same. Having.
[0010]
According to a fifth aspect of the present invention, in the gaming machine inspection device according to any one of the first to fourth aspects, the output unit is used for both the output of the electric signal input to the input unit and the output of the inspection signal. Has features.
[0011]
According to a sixth aspect of the present invention, in the gaming machine inspection apparatus according to the fifth aspect, a switching unit for switching a signal output from the output unit to one of an electric signal and an inspection signal is provided.
[0012]
According to a seventh aspect of the present invention, in the gaming machine inspection device according to any one of the first to sixth aspects, the gaming machine is provided with first and second game control means as game control means, A game control signal as an electric signal transmitted to the first and second game control means for the game control means to control the game is input to an input unit of the game machine inspector, and the game control It is characterized in that the signal is output from the output section of the gaming machine inspection device to the second game control means.
[0013]
The invention according to claim 8 is the gaming machine inspection device according to claim 7, wherein the input unit of the gaming machine inspection device is detachably connected to the coupling means provided at the output unit of the first game control unit. An output unit of the gaming machine inspection device, which is removably connected to an upper coupling unit for electrically connecting to an output unit of the first game control unit and to a coupling unit provided at an input unit of the second game control unit; And lower connection means for electrically connecting the input means to the input section of the second game control means, and the lower connection means has the same shape as the connection means provided at the output section of the first game control means. However, it has features.
[0014]
According to a ninth aspect of the present invention, in the gaming machine inspection device according to the seventh or eighth aspect, the input unit of the gaming machine inspection device is detachably coupled to the coupling means provided at the output unit of the first game control unit. Is removably connected to an upper connecting means for electrically connecting an output part of the first game control means and a connecting means provided at an input part of the second game control means. A lower coupling means for electrically connecting the output section to an input section of the second game control means, wherein the upper coupling means has the same shape as the coupling means provided at the input section of the second game control means. Is characterized by
[0015]
According to a tenth aspect of the present invention, in the gaming machine inspection device according to any one of the first to ninth aspects, the gaming machine inspection device transmits a game control signal received from the first game control means to a plurality of second game control devices. It is characterized in that it is a distributor for distribution to the control means.
[0016]
According to an eleventh aspect of the present invention, in the gaming machine inspection device according to any one of the first to ninth aspects, a plurality of output units of the gaming machine inspection device are provided, and which output unit selects an output unit to output an inspection signal. The feature is that the selection means for the is provided.
[0017]
According to a twelfth aspect of the present invention, in the gaming machine inspection device according to any one of the eighth to eleventh aspects, the first game control means is a main control board for controlling a game state of the game machine, and The game control means controls a sound control board for controlling a sound generation means provided on the game machine and / or a display control board for controlling a display provided on the game machine and / or a light emitting body provided on the game machine. It is characterized by being a luminous body control base.
[0018]
According to a thirteenth aspect of the present invention, in the gaming machine inspection device according to any one of the first to twelfth aspects, a display means for displaying an inspection result of the control program is provided.
[0019]
Function and effect of the present invention
<Invention of claim 1>
According to the gaming machine inspection device of the first aspect, an input unit for inputting an electric signal to the gaming machine inspection device from the outside, and an output for outputting the electric signal input from the input unit to the outside of the gaming machine inspection device Since the unit is provided, in addition to the inspection of the control program, the gaming machine inspection device can be used as a relay of the electric signal, and can be effectively used at times other than the inspection of the control program.
[0020]
<Inventions of Claims 2 and 3>
According to the gaming machine inspection device of the second aspect, the storage device for inspection, the input unit and the output unit are provided integrally, so that the inspection device for the gaming machine can be handled as one unit, and Mounting becomes easier. Specifically, the inspection storage means, the input unit, and the output unit may be mounted on the electric board (the invention of claim 3).
[0021]
<Invention of Claim 4>
According to the gaming machine inspection device of the fourth aspect, since the electric signal input to the input unit and the electric signal output from the output unit are the same, the electric signal is directly transmitted without passing through the gaming machine inspection device due to various circumstances. It is possible to easily cope with the need to input and output.
[0022]
<Invention of claim 5>
According to the gaming machine inspection device of the fifth aspect, since the output portion is used for both the output of the electric signal and the output of the inspection signal, the number of parts can be reduced.
[0023]
<Invention of claim 6>
According to the gaming machine inspection device of the sixth aspect, the switching device for switching the signal to be output from the output unit to one of an electric signal from outside the gaming machine inspection device and an inspection signal based on an inspection program is provided. , The signal to be output from the gaming machine inspection device can be selected. Accordingly, when the inspection signal is output, the electric signal is not output, so that the inspection of the control program can be performed smoothly.
[0024]
<Inventions of Claims 7 and 12>
According to the gaming machine inspection device of the seventh aspect, since the game control signal from the first game control device is configured to be output to the second game control device via the gaming machine inspection device, The machine inspection device can also be used as a relay of a game control signal from the first game control means to the second game control means. Here, the first game control means may be a main control board, and the second game control means may be a voice control board and / or a display control board and / or a luminous body control board. 11 inventions).
[0025]
<Inventions of claims 8 and 9>
Since the lower connecting means of the game machine inspecting device of the eighth aspect has the same shape as the connecting means provided in the output section of the first game control means, the parts can be shared and the manufacturing cost can be reduced. Further, since the upper side connecting means of the game machine inspecting device of the ninth aspect has the same shape as the connecting means provided in the input section of the second game control means, the parts can be shared and the manufacturing cost can be reduced. .
[0026]
<Invention of Claim 10>
In the gaming machine inspection device according to the tenth aspect, the gaming machine inspection device also functions as a distributor for distributing the game control signal received from the first game control means to the plurality of second game control means. The configuration is simplified as compared with the case where a distributor is separately provided.
[0027]
<Invention of Claim 11>
According to the gaming machine inspection device of claim 11, since the gaming machine inspection device is provided with a plurality of output units, when a plurality of game control units are provided, separate output units are provided for each game control unit. Can be set. Further, since it is possible to select which output unit of the plurality of output units outputs the inspection signal, it is possible to select a game control unit to be inspected.
[0028]
<Invention of Claim 13>
According to the gaming machine inspection apparatus of the twelfth aspect, the display means for displaying the inspection result of the control program is provided, so that the inspection result can be easily recognized by the inspector.
[0029]
BEST MODE FOR CARRYING OUT THE INVENTION
<First embodiment>
Hereinafter, a first embodiment of a gaming machine inspection device to which the present invention is applied will be described with reference to FIGS. FIG. 1 shows a pachinko gaming machine 10 having an inspection base 90 as a “gaming machine inspection device” of the present invention. As shown in FIG. 1, the game board 11 of the pachinko gaming machine 10 has a display device 13 (corresponding to a “display device” of the present invention) in the center of a substantially circular game area R1 surrounded by a guide rail 12. ). Below the display device 13 in the game area R1, a starting winning port 14, a large winning port 15, and a missed ball receiving port 16 are provided side by side at intervals from the top. A ramp windmill 17, a start gate 18, a windmill 19, and general winning openings 20 and 21 are provided in order from the top and the left and right sides of the game area R1 across the display device 13 and the like. On both sides, arc-shaped side lamps 22, 22 (corresponding to the “light-emitting body” of the present invention) are provided. Further, in addition to these winning ports and the like, a plurality of nails (not shown) stand in the game area R1.
[0030]
As shown in FIG. 1, an upper plate 27A and a lower plate 27B are provided below the game board 11 of the pachinko gaming machine 10 in two vertical stages. Then, by operating the operation knob 28 provided at the right end of the lower plate 27B, the game balls accommodated in the upper plate 27A are flipped out toward the game board 11. When the button 29 provided on the upper plate 27A is pressed, the game ball moves from the upper plate 27A to the lower plate 27B and is stored therein. Further, a pair of speakers 59S (corresponding to "sound generating means" of the present invention) are provided on both sides of the upper plate 27A.
[0031]
Next, the required parts will be described in more detail.
As shown in FIG. 1, the starting winning port 14 has movable wing pieces 14C, 14C on both sides. The movable wing pieces 14C, 14C are always open in the starting winning opening 14 in such a size that one game ball can be won, and when the predetermined condition is satisfied when the game ball passes through the starting gate 18, the movable wing piece 14C is movable. The wing pieces 14C, 14C expand right and left over a predetermined period (the state of FIG. 1), and it becomes easy to win the starting winning opening 14. In addition, when a game ball enters the start winning port 14, a determination is made as to whether or not the game is successful, as described later, and a predetermined number of prize balls are paid out to the upper plate 27A.
[0032]
The special winning opening 15 is formed horizontally long and is always closed by the movable door 15T. Then, when a so-called "big hit game" is executed by the establishment of a predetermined condition described later, the big winning opening solenoid provided on the back of the game board 11 is driven, and the movable door 15T falls forward for a predetermined period. . As a result, the special winning opening 15 is opened, and many game balls can be won in the special winning opening 15 by using the movable door 15T as a guide. Here, when a period from when the movable door 15T is opened to when it is closed is referred to as a “round”, in one round, the opening time of the movable door 15T reaches 29 seconds or the large winning opening 15 The process ends if any one of the conditions of whether ten game balls have been won is satisfied first.
[0033]
Inside the special winning opening 15, a continuous winning opening and a counting winning opening (not shown) are provided. Either the continuous winning opening or the counting winning opening is selectively opened. More specifically, when the movable door 15T is opened, the continuous winning opening is initially open, and after winning the continuous winning opening, the continuous winning opening is closed and the counting winning opening is switched to open. Then, when there is a prize in the continuous winning opening, this is detected by the jackpot state continuation sensor provided in the continuous winning opening, and after the end condition is satisfied and the round is finished, the next round is continuously executed. You. When there is a winning in the counting winning opening, this is detected by a winning ball counting sensor provided in the counting winning opening, and the winning balls to the special winning opening 15 are counted together with the winning balls to the continuous winning opening. Then, it is checked whether or not these have reached a total of 10 as described above.
[0034]
The display device 13 is formed by assembling a liquid crystal module (not shown, specifically, a TFT-LCD module) on the rear end surface of the decorative frame 23 having a frame structure as a whole. The front part of the liquid crystal module surrounded by the decorative frame 23 is a display unit 34, and a player can see an image displayed on the display unit 34 through the decorative frame 23.
[0035]
As shown in FIG. 1, the display unit 34 normally displays three left, middle, and right special symbols 80, 81, and 82 side by side. Each of these special symbols 80, 81, 82 is composed of, for example, a plurality of types in which numerals of "0" to "11" are written. The type is confirmed and displayed on the display unit 34. Then, when the game ball wins in the starting winning opening 14, it is determined whether the game is winning or not, and each of the special symbols 80, 81, 82 is scrolled up and down and displayed in a fluctuating manner, and after a predetermined time, for example, left, middle, right The special symbols 80, 81, 82 are stopped and displayed in this order. At this time, for example, when the result of the hit / fail judgment is a hit and all the special symbols 80, 81, and 82 are the same symbol, that is, when the special symbols are aligned, the game becomes the "big hit state" and the movable door 15T is opened. It is.
[0036]
Also, when a game ball enters the starting winning opening 14 while the display unit 34 is displaying the fluctuation or in a big hit state, a predetermined random number is up to four due to the entering ball. It is suspended and temporarily stored. Then, when the display of the special symbols 80, 81, and 82 is started to be changed on the display unit 34, the number of reserved memories is reduced by one, and this operation is repeated until the number of reserved memories becomes zero. Further, the number of the reserved storages is notified to the player by the lighting numbers of a total of four LEDs 25 arranged in pairs on both sides of the decoration frame 23 in the upper side of the decoration frame 23.
[0037]
Further, the pachinko gaming machine 10 of the present embodiment has a probability variation function, and the combination of the special symbols 80, 81, 82 when the jackpot is established is “1,” “3,” “5,” “7,” “ If the hit number is 9 or 11, the probability fluctuation occurs after the end of the jackpot game, and the next jackpot occurrence probability is lower than the normal gaming state (low probability state, 1/315). The state shifts to a high probability fluctuation state (high probability state, 5/315), and this probability fluctuation state is continued until the next jackpot. Also, the combination of the special symbols 80, 81, and 82 at the time of the jackpot formation was any one of "2", "4", "6", "8", "10", and "12". Sometimes, the normal game state is continued until the next jackpot without shifting to the probability fluctuation state.
[0038]
In the display unit 34, a normal symbol display area 24 is provided at the lower left corner of the display area of the special symbols 80, 81, 82. The normal symbol display area 24 determines whether or not the normal symbol start sensor provided in the start gate 18 detects passing of the game ball, and, for example, sets a number from “0” to “9” to a predetermined period. After variable display over the predetermined range, a predetermined number is fixedly displayed. Then, when the confirmed and displayed number is, for example, an odd number, the movable wing pieces 14C, 14C provided in the starting winning opening 14 are tilted sideways for a predetermined period (for example, 0.4 seconds). The symbols displayed in the ordinary symbol display area 24 are not limited to numbers, but may be alphabets, symbols, or the like.
[0039]
Also, when the game balls pass through the start gate 18 while the normal symbol display area 24 is being displayed in a fluctuating manner, the game balls that have passed through are counted up to a maximum of four. Then, when the normal symbol display area 24 is stopped and displayed, the accumulated number is reduced by one, the variable display of the ordinary symbol display area 24 is started, and this operation is repeated until the accumulated number becomes zero. Further, the cumulative number is notified to the player by the number of lighting of the three counting lamps 24S provided side by side at the center of the upper side of the decorative frame 23.
[0040]
As shown in FIG. 2, a main control board 50 according to the present invention is provided in the center of the rear surface of the pachinko gaming machine 10. An audio control board 56 and a display control board 70 are provided. That is, in the present embodiment, the main control board 50 corresponds to the “first game control means” of the present invention, and the illuminant control board 55, the voice control board 56, and the display control board 70 correspond to the “second game control board” of the present invention. Game control means. "
[0041]
An inspection base 90 is provided below the bases 50, 55, 56, 70. Further, various control bases such as a power supply base, a payout control base, and a launch control base are provided below the bases 50, 55, 56, 70, and 90. Here, the inspection base 90 is screwed to the rear surface of the pachinko gaming machine 10 like the other bases 50, 55, 56, 70, etc., so that it can be easily attached to and detached from the pachinko gaming machine 10. it can.
[0042]
Next, an electrical configuration of the pachinko gaming machine 10 according to the present embodiment will be described with reference to FIGS. In FIG. 4, the illuminant control board 55 is omitted because it has the same configuration as the display control board 70 and the voice control board 56. As shown in FIG. 3, the main control board 50 includes, as a main part, a one-chip microcomputer 51 formed by packaging a CPU 51A, a RAM 51B, and a ROM 51C.
[0043]
The one-chip microcomputer 51 receives signals from the above-described winning ports 14, 15, 20, 21 and the sensors provided in the starting gate 18 via an interface (not shown). A game command (corresponding to a "game control signal" of the present invention) is output to the launch control base, the payout control base, the display control base 70, and the like to control each part. Here, the game command from the main control board 50 is once input to an inspection board 90 described later, and is output from the inspection board 90 to each of the boards 55, 56, 70. That is, the inspection board 90 of the present embodiment plays a role as a relay board (relay means) from the main control board 50 to each of the boards 55, 56, 70.
[0044]
The main control board 50 includes an initial reset circuit and a periodic reset circuit (not shown). The initial reset circuit outputs an initialization signal to a reset terminal of the one-chip microcomputer 51 when the power of the pachinko gaming machine 10 is turned on. The periodic reset circuit outputs an interrupt pulse to the one-chip microcomputer 51 periodically (for example, every 2 msec). Each time the one-chip microcomputer 51 receives the interrupt pulse, the one-chip microcomputer 51 runs the main control main program M (corresponding to the “control program” of the present invention) stored in the ROM 51C, and outputs the output connector 40 (see FIG. A game command is output from the "combining means provided in the output unit of the first game control means" of the present invention).
[0045]
The display control board 70 includes a display control data ROM 70B (corresponding to “control storage means” of the present invention) for storing control data for displaying game images on the display unit 34, and special symbols, background images, and characters. And an image data ROM for storing image data such as images and character designs. Then, based on the game command input to the input connector 43 (refer to FIG. 4, which corresponds to the “coupling means provided in the input unit of the second game control means” of the present invention) via the inspection board 90, display control is performed. The CPU 70A extracts predetermined display control data from the display control data ROM 70B, generates control data in a storage area of the control data RAM, and outputs the control data to the VDP. The VDP reads necessary data from the image data ROM based on a command from the display control CPU 70A, creates map data such as a special design, a background image, a character design, and a character image in the display image, and stores the map data in the VRAM. Then, the stored image data is converted into RGB signals by a D / A conversion circuit and output to the display device 13. Further, the VDP 62 outputs a composite synchronization signal SYNC to the display device 13. Then, the display device 13 displays an image on the display unit 34 based on the transmitted RGB signals and the composite synchronization signal SYNC.
[0046]
The display control board 70 includes an initial reset circuit (not shown). The initial reset circuit outputs an initialization signal to a reset terminal of the display control CPU 70A when the power of the pachinko gaming machine 10 is turned on. The display control CPU 70A runs the display control program N (corresponding to the “control program” of the present invention) stored in the display control data ROM 70B. Then, the display device 13 is driven and controlled based on the game command transmitted from the main control board 50. When an inspection command (corresponding to an “inspection signal” of the present invention) to be described later is input from the inspection board 90, the data of the display control data ROM 70B is output to the inspection board 90.
[0047]
The sound control board 56 includes a sound control data ROM 56B (corresponding to “control storage means” of the present invention) for storing control data for generating sound from the speaker 59S, and the input connector 43 via the inspection board 90. (Refer to FIG. 4, which corresponds to the "combining means provided in the input unit of the second game control means" of the present invention). The sound control CPU 56A runs the sound control program (corresponding to the “control program” of the present invention) stored in the sound control data ROM 56B, and generates sound from the speaker 59S. Specifically, the voice control CPU 56A outputs a signal to the voice synthesis circuit based on a game command from the main control board 50. The voice synthesizing circuit reads necessary voice data from the voice data ROM based on a signal from the voice control CPU 56A, synthesizes the voice signal, and outputs the synthesized signal to the amplifier. Then, the synthesized audio signal is amplified by the amplifier and output to the speaker 59S, and a sound is generated from the speaker 59S. Further, when a test command is input from the test board 90, the voice control CPU 56A outputs data of the voice control data ROM 56B to the test board 90.
[0048]
The illuminant control board 55 is provided with a illuminant control data ROM 55B that stores control data for causing the left and right side lamps 22 and 22 and the LEDs provided on the decorative frame 23 of the display device 13 to emit light, and the like (the “control” of the present invention). ) And input connector 43 (see FIG. 4, which corresponds to “the coupling means provided in the input section of the second game control means” of the present invention) via the inspection board 90. And a control data RAM for temporarily storing the played game command. The light emission control CPU 55A runs the light emission control program (corresponding to the “control program” of the present invention) stored in the light emitter control data ROM 55B, and causes the side lamps 22, 22 and the LED to emit light. Specifically, a signal is output to the light emission data control circuit based on a game command from the main control board 50. Upon receiving the signal, the light emission data control circuit reads necessary data from the light emission data ROM based on the signal from the light emission control CPU 55A, and causes the left and right side lamps 22, 22 and LEDs to emit light. Further, when the inspection signal is input from the inspection base 90, the illuminant control CPU 55A outputs the data of the illuminant control data ROM 55B to the inspection base 90.
[0049]
The inspection board 90 includes an input connector 41 (corresponding to the “input unit” and “upper-side coupling unit” of the present invention) and an output connector 42 (“output unit” and “lower-side coupling of the present invention”) on the electric board. Means), an inspection data ROM 91 (corresponding to the "inspection storage means" of the present invention), an inspection CPU 93 and the like. The inspection data ROM 91 stores an inspection program T for inspecting each of the substrates 55, 56, 70. The inspection CPU 93 runs this inspection program T and inspects each of the substrates 55, 56, 70. A command is output, and the data output from each control data ROM 55B, 56B, 70B and stored in the inspection RAM 92 is checked. More specifically, the test board 90 stores program data of a regular display control program, a voice control program, and a light emission control program to be stored in each of the boards 55, 56, and 70. The inspection base 90 checks whether or not these regular program data and the program data actually stored in the bases 55, 56, 70 match.
[0050]
The inspection board 90 is provided with output connectors 42, 42, 42 for each of the boards 55, 56, 70 (see FIG. 4), and a changeover switch 94 ("switching means" and "selecting means" of the present invention). ) Is provided. The changeover switch 94 can be switched between an inspection state and a relay state. In the relay state, game commands input from the main control board 50 to the inspection board 90 are controlled by the output connectors 42, 42, 42 via the output connectors 42, 42, 42. Output to the substrates 55, 56, 70. On the other hand, in the inspection state, an inspection command is output to each of the substrates 55, 56, and 70 based on the inspection program T. Here, when the changeover switch 94 is in the inspection state, which of the output connectors 42, 42, 42 outputs the inspection command, that is, which control data ROM 55B, 56B, 70B to inspect. Can be selected. The input connector 41 may be provided separately for each of the bases 55, 56, 70 in accordance with the output destination of the game command output from the main control base 50, or may be provided irrespective of the output destination of the game command. It may be.
[0051]
These will be described in more detail with reference to FIGS. Although FIG. 5 shows only the configuration related to the display control board 70 and the audio control board 56, the configuration related to the illuminant control board 55 is the same.
[0052]
As shown in FIG. 5, the inspection board 90 is provided with latches 97, 97, 97 for each of the boards 55, 56, 70. When the changeover switch 94 is set to the relay state, the inspection CPU 93 determines to which of the bases 55, 56, and 70 the game command input from the main control base 50 is directed. Here, a strobe signal for specifying an output destination of the game command is output from the main control board 50 along with the game command. The inspection CPU 93 determines the output destination of the game command based on the strobe signal. Then, a predetermined code is output to the decoder 98 based on the discrimination result, and the decoder 98 sets only the latch corresponding to the discrimination result among the latches 97, 97, 97 to the enabled state, and sets the other latches to the disabled state. I do. As a result, the game command is output only to the board corresponding to the strobe signal among the boards 55, 56, 70.
[0053]
Therefore, the inspection board 90 functions as a distributor that distributes one game command received from the main control board 50 to each of the boards 55, 56, and 70 and transmits the same. In addition, a strobe signal for specifying all of the boards 55, 56, 70 is provided, and the inspection board 90 sends one game command received from the main control board 50 to all the boards 55, 56, 70 at one time. It may function as a distributor in a narrow sense for distribution.
[0054]
When the changeover switch 94 is set to the inspection state, only the latch 97 corresponding to the board selected by the changeover switch 94 among the latches 97, 97, 97 provided for each of the boards 55, 56, 70 is set to the permission state. Then, the other two latches 97, 97 are disabled. Then, by turning on an inspection start button (not shown), the inspection is started, and an inspection command is output from the inspection CPU 93 only to the selected one of the substrates 55, 56, and 70.
[0055]
As shown in FIG. 3, when an inspection command is input to each of the boards 55, 56, and 70, the CPUs 55A, 56A, and 70A provided for each of the boards 55, 56, and 70 are stored in the control data ROMs 55B, 56B, and 70B. The output data is output to the inspection base 90. When any of the control data ROMs 55B, 56B, and 70B is read into the inspection base 90, the data is temporarily stored in the inspection RAM 92, and the data is compared with the reference ROM data stored in the control data ROM 91 of the inspection base 90. You. Then, the inspection result is output to the result display unit 95 (corresponding to “display means” of the present invention). Here, when a game command is input from the main control board 50 to the test board 90 during the test of the control data ROMs 55B, 56B, 70B, the test CPU 93 ignores the game command and ignores the control command. 56, 70 are not transmitted.
[0056]
Note that the result display unit 95 may be, for example, a liquid crystal display or a light-emitting body such as an LED. The changeover switch 94 is provided, for example, on the rear side of the pachinko gaming machine 10 and has a configuration in which an inspector can switch between an inspection state and a relay state by operating a knob provided on the changeover switch 94. Further, when the inspection state is further set, the base to be inspected can be switched by operating the knob.
[0057]
Next, the configuration of the main control board 50, the inspection board 90, and the connection portion between the inspection board 90 and each of the boards 55, 56, 70 will be described with reference to FIG. Although FIG. 2 shows only the connection part related to the display control board 70, the connection parts related to the other control boards 55 and 56 have the same configuration.
[0058]
As shown in FIG. 11, the harness 45 electrically connects the main control board 50 and the inspection board 90. The harness 45 includes, for example, an output connector 45A and an input connector 45B at both ends of a flat cable (electric wire). Then, the output connector 45A of the harness 45 is connected to the output connector 40 provided on the main control board 50, and the input connector 45B of the harness 45 is connected to the input connector 41 provided on the test board 90, so that the main control The board 50 and the inspection board 90 are electrically connected. Thus, the game command output by the main control board 50 is transmitted to the inspection board 90 through the harness 45.
[0059]
The inspection board 90 and the display control board 70 are connected by the harness 46. This harness 46 also includes an output connector 46A and an input connector 46B at both ends of the flat cable (electric wire). Then, the output connector 46A of the harness 46 is connected to the output connector 42 provided on the inspection board 90, and the input connector 46B of the harness 46 is connected to the input connector 43 provided on the display control board 70. And the display control board 70 are electrically connected. Thereby, the game command or the inspection command output from the inspection board 90 is transmitted to the display control board 70 through the harness 46.
[0060]
Here, in the present embodiment, the output connector 40 provided on the main control board 50 and the output connector 42 provided on the inspection board 90 have the same structure. Therefore, the output side connectors 45A and 46A of the harnesses 45 and 46 to be connected to each other have the same structure. The input connector 41 provided on the inspection board 90 and the input connector 43 provided on the display control board 70 have the same structure. Therefore, the input connectors 45B and 46B of the harnesses 45 and 46, which are mating partners, have the same structure. That is, the harness 45 and the harness 46 not only have a harness structure, but also have the same structure with all the components. Thus, the components of the output connectors 40 and 42 can be shared, and the components of the input connectors 41 and 43 can be shared. Furthermore, since the components of the harnesses 45 and 46 can be shared, the manufacturing cost can be reduced.
[0061]
By the way, between the inspection board 90 and the display control board 70, both the game command and the inspection command are transmitted using the same electric path (signal transmission path) in the harness 46. In other words, the game command and the inspection command output from the inspection board 90 are both transmitted from the same output connector 42 to the display control board 70. For this purpose, as described above, the inspection base 90 is provided with the changeover switch 94, and can be switched between an inspection state in which an inspection command is output from the inspection base 90 and a relay state in which a game command is output. In this way, in the inspection base 90, the number of components can be reduced by using the output connector 42 for transmitting the game command and for transmitting the inspection command.
[0062]
Next, the operation of the pachinko gaming machine 10 having the above configuration will be described with reference to FIGS. When the power of the pachinko gaming machine 10 is turned on, the one-chip microcomputer 51 takes out the main control program M shown in FIG. 3 from the ROM 51C at a predetermined cycle (for example, every 2.000 msec) and runs it. Then, it is checked whether or not the power is turned on. If the power is turned on (Yes in S1), initialization (S2) is performed, an initialization signal is output from the initial reset circuit, and for example, the stack Settings, constant settings, CPU settings, SIO, PIO, CTC (interrupt time controller) settings, and the like are performed. The processing required only at the time of turning on the power is executed only when the main control program M is run for the first time after the power is turned on, and is not executed thereafter.
[0063]
Next, a command output process (S3) is performed. In the command output process (S3), it is checked whether or not various game commands determined by the fixed stop special symbol determination process (S11) and the variation pattern determination process (S12) described later are stored in the command buffer of the RAM 51B. If the game command is stored, the game command in the command buffer is output to the display control board 70, the voice control board 56, the illuminant control board 55, and the like via the inspection board 90.
[0064]
Subsequent to the command output process (S3), a sensor input process (S4) is performed. In the sensor input process (S4), the presence / absence of detection information such as winning balls by the sensors provided in the winning openings 14, 15, 20, 21 and the like is checked. Is stored in the RAM 51B.
[0065]
Next, a random number update process (S5) is performed. In the present embodiment, the counters shown in Table 1 are provided to generate random numbers.
[0066]
[Table 1]

[0067]
Each counter shown in Table 1 is set to “0” when the power is turned on, and is incremented by one every time the random number update process (S5) is executed (for example, every 2 msec). When each counter exceeds the upper limit of the numerical range of the counter, the counter is reset to “0” and is incremented again from “0” by one. The value of each counter updated in this manner is stored one by one in the counter value storage area of the RAM 51B, and the process exits from the random number update process (S5).
[0068]
When the process exits from the random number update process (S5), it is checked whether the sensor detection information stored in the sensor input process (S4) is due to a ball entering the winning opening 14 (S6). Specifically, it is checked whether or not a sensor provided in the starting winning port 14 has detected a winning ball. Then, when a winning ball to the starting winning port 14 is detected (Yes in S6), a random number acquisition process (S7) is executed. On the other hand, when a winning ball to the starting winning opening 14 has not been detected (No in S6), the process proceeds to step S8 without executing the random number acquisition process (S7).
[0069]
In the random number acquisition process (S7), the value of the counter stored in the counter value storage area of the RAM 51B is extracted and stored in the random value storage area separately set in the RAM 51B.
[0070]
When the process exits from the random number acquisition process (S7), it is checked whether the determination condition is satisfied (S8). Here, the “judgment condition” refers to a condition necessary for executing a judgment regarding a game hit or miss. In the present embodiment, for example, when the following three conditions (1) to (3) are satisfied at the time when step S8 is executed, it is defined as “satisfaction of the determination condition”.
(1) The "winning game" is not being executed.
(2) The special symbols 80, 81, and 82 are not being displayed in a variable manner.
{Circle around (3)} The number of stored memories is one or more.
[0071]
If at least one of the conditions (1) to (3) is not satisfied, the process jumps to other processing (S13). On the other hand, if all of these conditions are satisfied, a jackpot determination process (S9), a reach presence / absence determination process (S10), a fixed stop special symbol determination process (S11), and a fluctuation pattern determination process (S12) are executed. .
[0072]
In the present embodiment, the above three conditions (1) to (3) are set as “judgment conditions”. However, the number of “judgment conditions” is not limited to three. May be.
[0073]
When the above-described determination condition is satisfied, a jackpot determination process (S9) is first performed. When this process (S9) is executed, it is first checked whether the state is a high probability state or a low probability state, and in the low probability state, the acquired random number (label-TRND-A) for jackpot determination is "5" or "500". A check is made to see if any of the two winning numbers matches. On the other hand, in the high probability state, the acquired jackpot determination random numbers (label-TRND-A) are “5”, “50”, “100”, “200”, “300”, “350”, “400”, A check is made to see if any one of the ten winning numbers "450", "500", and "600" matches.
[0074]
If the random number for the jackpot determination (label-TRND-A) does not match any of the winning numbers, the process exits from this processing (S9). On the other hand, if the jackpot determination random number (label-TRND-A) matches any of the jackpot numbers, the jackpot flag A1 is set, and the process exits from this process (S9).
[0075]
Next, a reach presence / absence determination process (S10) is executed. When this process (S10) is executed, it is checked whether the big hit flag A1 is set. When the big hit flag A1 is set, that is, in the case of the "big hit state", it is determined that there is reach (reach state transition is possible), the reach flag B is set, and the process (S10) is exited. That is, when a big hit occurs, the game always reaches the reach state.
[0076]
On the other hand, when the jackpot flag A1 is not set, that is, in the case of “missing”, there is a reach only when the reach determination random number (label-TRND-R1) matches “24” or “49”. Is set, the reach flag B is set, and the process (S10) is exited. If the reach determination random number (label TRND-R1) does not match “24” or “49”, it is determined that there is no reach and the reach flag B is not set and the initial state is maintained. I do.
[0077]
Next, a fixed stop special symbol determination process (S11) is executed. When this processing (S11) is executed, it is checked whether or not the jackpot flag A1 is set. If the jackpot flag A1 is set, that is, if the jackpot is a jackpot, the jackpot special symbol random number (label -TRND) A combination of symbols predetermined for the numerical value of -AZ1) is determined as a jackpot symbol combination, and the command is stored in the command buffer of the RAM 51B. That is, for example, when the special jackpot symbol random number (label-TRND-AZ1) = “1”, “1 1” is a set of three “1” s arranged on the display unit 34 as the determined jackpot symbol combination. "1" is determined as the displayed command. When the jackpot special symbol random number (label-TRND-AZ1) = “7”, “7 7 7”, which is a set of three “7” in the display unit 34, is determined as the determined jackpot symbol combination. Is determined to the command displayed. Similarly, in other jackpot special symbol random numbers (label-TRND-AZ1), any one of the numeric symbols “0” to “11” is set to 3 according to the numerical value of the jackpot special symbol random number (label-TRND-AZ1). The aligned rows are determined as a determined jackpot symbol combination, and the corresponding command is stored in the command buffer of the RAM 51B.
[0078]
On the other hand, if the jackpot flag A1 is not set, that is, if the jackpot is off, each of the special symbols 80, 81, and 82 is aligned based on three special symbol random numbers (labels -TRND-B1, B2, and B3). The combination is determined to be invisible, and the command is stored in the command buffer. If the reach flag B is set, the left special symbol 80 and the right special symbol 82 are the same symbol, and only the middle special symbol 81 is determined to be a different symbol combination from the left and right special symbols 80 and 82. . Specifically, the display unit 34 determines a command to be displayed, such as “1 2 1” or “3 5 3”. That is, the reach state is reached in the process of the variable display, but finally, the symbol combination of the stop display is set so that the departure is determined.
[0079]
On the other hand, when the reach flag B is not set, all the special symbols 80, 81, and 82 are determined to be different symbol combinations. Specifically, the display unit 34 determines the command to be displayed as “1 2 3” or “75 3”. That is, in the process of the fluctuation display, the symbol combination of the stop display is set so as not to reach and to determine the departure.
[0080]
Next, a fluctuation pattern determination process (S12) is performed. When this process (S12) is executed, a change pattern at the time of a big hit or at the time of a miss is set by the big hit flag A1, the change pattern determination random number (label-TRND-T1), and the reach flag B.
[0081]
After this process (S12), another process (S13) is performed. The other processing (S13) includes a probability variation notification processing. In the probability variation notification process, after the jackpot game is over, the acquired numerical value of the jackpot symbol determination random number (label-TRND-AZ1) is checked, and the combination of each of the special symbols 80, 81, 82 when the jackpot is established is "1". When any one of "3", "5", "7", "9", and "11" is reached, the player is notified that the game is shifted to the probability fluctuation state (high probability state). I do. On the other hand, the combination of each of the special symbols 80, 81, and 82 when the jackpot was established was any one of "2", "4", "6", "8", "10", and "12". Sometimes, the player is notified that the normal gaming state (low-probability state) is continued until the next big hit without being in the probability fluctuation state.
[0082]
In the other processing (S13), in addition to the probability fluctuation notification processing, processing not deeply related to the present invention is executed, and the process exits from the main control program M. After 2 msec, the main control program M is run again, and the process is repeated from step S1. The above is the description of the main control program M.
[0083]
Now, at the same cycle as the main control program M (for example, 2.000 msec), the display control CPU 70A provided in the display control board 70 retrieves the display control program N from the display control data ROM 70B and runs it. Note that the audio control program and the illuminant control program have the same configuration as the display control program N, and thus description thereof is omitted.
[0084]
When the display control program N is executed, images of the fixed stop special symbol and the variation pattern determined in the fixed stop special symbol determination process (S11) and the variation pattern determination process (S12) of the main control program M are displayed. It is created by the control board 70 and displayed on the display unit 34. When the changeover switch 94 of the inspection board 90 is set to the inspection state and the display control board 70 is selected as the board to be inspected, the display control CPU 70A transfers the data in the display control data ROM 70B to the inspection board 90. Output.
[0085]
The display control program N is shown in FIG. 7, and it is first checked whether or not the power is turned on (S60). When the power is turned on (Yes in S60), for example, stack setting, constant setting, CPU setting, SIO, PIO, CTC (interrupt time controller) settings, etc. are performed as initial settings (S61). . The processing required only at the time of turning on the power is executed only when the display control program N is run for the first time after the power is turned on, and is not executed thereafter.
[0086]
Next, a command input process (S62) is performed, and a game command from the main control board 50 and a test command from the test board 90 are input. More specifically, the game command output in step S26 of the inspection program T shown in FIGS. 9 and 10, the inspection start command output in step S33, and the next data request command output in step S58 are input.
[0087]
Next, it is checked whether or not the command input in the command input process (S62) is an inspection start command from the inspection base 90 (S63). If it is not an inspection start command (No in S63), the process proceeds to step S65. If it is an inspection start command (Yes in S63), the inspection flag is turned on (S64), and the process proceeds to step S65.
[0088]
In step S65, it is checked whether the inspection flag is ON. When the inspection flag is not ON (No in S65), that is, when the changeover switch 94 is in the relay state, other game machine processing is performed (S66), and other control bases other than the main control base 50 and the inspection base 90 are performed. Sub game commands from 55, 56, etc. are input. Thereafter, a display control process (S68) is performed, and an image is created in the display control board 70 based on the game command from the main control board 50 and the sub game commands from the other control boards 55 and 56, and the display unit 34 is formed. Display with.
[0089]
Here, when the inspection flag is ON (Yes in S65), the inspection process (S67) is executed. The inspection process (S67) is shown in FIG. 8. First, the inspection data setting process (S70) is executed, and among the various data stored in the display control data ROM 70B, the data to be output to the inspection base 90 is output. Set. Specifically, based on the addresses in the display control data ROM 70B, the data is set in order from the data at address 0.
[0090]
Next, test data output processing (S71) is performed, and the data set in the test data setting processing (S70) is output to the test base 90. Thereafter, it is checked whether or not all the data in the display control data ROM 70B has been output to the inspection board 90 (S72). If all the data has not been output, that is, the inspection of the display control data ROM 70B has not been completed. In this case, the process immediately exits this process (S67), while if all data has been output (Yes in S72), the inspection flag is turned off (S73), and the process exits this process (S67). The above is the description of the display control program N.
[0091]
Next, the inspection program T will be described with reference to FIG. At the same cycle as the main control program M (for example, 2.000 msec), the inspection CPU 93 provided on the inspection board 90 retrieves the inspection program T from the inspection data ROM 91 and runs it. Then, it is checked whether or not the power is turned on. If the power is turned on (Yes in S20), for example, stack setting, constant setting, CPU setting, SIO, PIO, CTC are performed as initial settings (S21). (Interrupt time controller) is set. The processing required only at the time of power-on is executed only when the inspection program T is run for the first time after power-on, and is not executed thereafter.
[0092]
When the inspection program T is run for the second time or later after the power is turned on (No in S20), it is checked whether the changeover switch 94 is in the inspection state (S22). When the changeover switch 94 is not in the inspection state (No in S22), it is determined that the game command from the main control board 50 can be transmitted to each of the boards 55, 56, 70, and the main control board 50 It is determined whether or not the game command output in step S3 (see FIG. 6) has been input (S23). If no game command has been input from the main control board 50 (No in S23), the process immediately exits the inspection program T. When a game command is input from the main control board 50 (Yes in S23), it is checked whether the game command is for the display control board 70 (S24). Then, based on the strobe signal input together with the game command, the inspection CPU 93 determines the output destination of the game command, and if the output destination is for the display control board 70 (Yes in S24), the input game command is displayed. The data is output to the control board 70 (S26).
[0093]
On the other hand, if the input game command is not for the display control board 70 (No in S24), it is checked whether it is for the voice control board 56 (S25). If the command is for the voice control board 56 (Yes in S25), the input game command is output to the voice control board 56 (S27). If it is not for the voice control board 56 (No in S25), that is, when it is for the luminous body control board 55, the input game command is output to the luminous body control board 55 (S28). .
[0094]
When the changeover switch 94 is in the inspection state (Yes in S22), the inspection of each control data ROM 55B, 56B, 70B is executed. Specifically, first, it is checked whether or not the inspection flag is ON (S29). If the inspection flag is ON, the process jumps to step S35. If the inspection-in-progress flag is not ON (S29), it is determined which of the substrates 55, 56, and 70 is the substrate selected by the changeover switch 94, and the reference corresponding to the selected substrate is determined. The ROM data is read from the inspection data ROM 91 and set (S30).
[0095]
Next, it is checked whether or not the inspection start button is ON (S31). If it is not ON (No in S31), it is determined that the inspection is not to be started, and step S22 is executed. When the examination start button is turned on (Yes in S31), the examination editing area is initialized (S32). Thereafter, an inspection start command is transmitted to the substrate selected by the changeover switch 94 among the substrates 55, 56, and 70 (S33), and the inspection flag is turned ON (S34), and the data determination process (S35) is performed. Be executed. When the process exits from the data determination process (S35), step S22 is executed, and while the changeover switch 94 is in the inspection state, the processes of steps S22 to S35 are repeatedly executed.
[0096]
The data determination process (S35) is shown in FIG. 10. First, it is checked whether or not the inspection of the selected control data ROM is completed (S40). When the inspection is completed (Yes in S40), this process is immediately performed. The process exits from the processing (S35). On the other hand, if the inspection has not been completed (No in S40), a data input process is executed (S41), and the data output (step S71 in FIG. 8) is taken in from the control data ROM of the base to be inspected. Next, whether or not new data has been input is checked by data input processing (S41) (S42). If new data has not been input (No in S42), this processing (S35) is immediately performed. Exit. On the other hand, when new data is input (Yes in S42), it is checked based on the changeover switch 94 whether the input data is data in the display control data ROM 70B (S43). When the input data is the data of the display control data ROM 70B (Yes in S43), the display control inspection processing (S55) is executed. More specifically, data of the same address as that of the input data of the display control data ROM 70B is read from the reference ROM data set in step S30. Then, these data are collated to determine whether the data in the display control data ROM 70B is correct. Next, the inspection base-side inspection data setting process (S56) is executed, and settings for inspecting the next data are made.
[0097]
Thereafter, it is checked whether the inspection of all data in the display control data ROM 70B has been completed (S57), and if not completed (No in S57), a next data request command is output to the display control board 70. Then (S58), the data of the next address in the display control data ROM 70B is output to the display control board 70 (step S71 in FIG. 8), and the process (S35) is exited. On the other hand, when the inspection of all the data in the display control data ROM 70B is completed, the inspection result is output to the result display unit 95 (S49), the inspection flag is reset (S50), and this processing (S35). ).
[0098]
If the input data is the voice control data ROM 56B (No in S43, Yes in S44), a voice control inspection process (S51) is performed. More specifically, from the reference ROM data set in step S30, data at the same address as the data address of the input voice control data ROM 56B is read. Then, these data are collated to determine whether the data in the voice control data ROM 56B is correct. Next, an inspection base-side inspection data setting process (S52) is executed, and it is checked whether or not inspection of all data in the voice control data ROM 56B has been completed (S53). If not completed (No in S53), a next data request command is output to the voice control board 56 (S54), and the process exits from this processing (S35). On the other hand, when the inspection of all data in the voice control data ROM 56B is completed, the inspection result is output to the result display unit 95 as in the case of the display control board 70 described above (S49), and the inspection flag is set. After the reset (S50), the process exits from this process (S35).
[0099]
If the input data is the luminous body control data ROM 55B (No in S43, No in S44), a luminous body control inspection process (S45) is executed. More specifically, from the reference ROM data set in step S30, data at the same address as the address of the data of the input light emitting element control data ROM is read. Then, the two data are collated to determine whether the data in the luminous body control data ROM 55B is correct. Next, an inspection base side inspection data setting process (S46) is executed, and it is checked whether or not inspection of all data in the illuminant control data ROM 55B has been completed (S47). If the processing has not been completed (No in S47), a next data request command is output to the illuminant control board 55 (S48), and the process exits from this processing (S35). On the other hand, when the inspection of all data in the illuminant control data ROM 55B is completed, the inspection result is output to the result display unit 95 (S49), and the inspection flag is reset (S50). Exit from S35). The above is the description of the data determination processing (S35), and is the description of the inspection program T.
[0100]
The configuration of the inspection board 90 according to the present embodiment is as described above, and the operation will be described next. When inspecting each control data ROM 55B, 56B, 70B provided in each of the substrates 55, 56, 70, the changeover switch 94 is set to the inspection state and the substrate to be inspected is selected. For example, when the board to be inspected is set to the display control board 70 and the inspection start button is turned on, an inspection command based on the inspection program T is output from the output connector 42 corresponding to the display control board 70, and the display control board 70 is prepared. The inspection of the displayed display control data ROM 70B is started. Here, the display control data ROM 70B stores the display control program N for determining the display on the display unit 34 based on the game command from the main control board 50. The correctness of the display control program N can be checked. Then, when the inspection by the inspection program T is completed, the inspection result is displayed on the result display unit 95, and the inspector can visually recognize the display and easily know the inspection result.
[0101]
When the inspection of the display / display control data ROM 70B is completed and, for example, the audio control data ROM 56B provided in the audio control board 56 is inspected, the switch 94 selects the audio control board 56. When the inspection start button is turned ON, the audio control data ROM 56B is inspected as described above, and the audio control program stored in the audio control data ROM 56B is inspected. When the inspection is completed, the inspection result is displayed on the result display section 95.
[0102]
When the inspection of the display / display control data ROM 70B is completed and the illuminant control data ROM 55B provided in the illuminant control board 55 is to be inspected, the illuminant control board 55 is selected by the changeover switch 94. Then, the inspection of the luminous body control data ROM 55B is performed as described above, the luminous body control program is inspected, and the inspection result is displayed.
[0103]
By the way, the game commands from the main control board 50 are not transmitted to the boards 55, 56, 70 when the boards 55, 56, 70 are being tested, that is, when the changeover switch 94 is in the test state. Thereby, the inspection of each of the substrates 55, 56, 70 can be performed more smoothly.
[0104]
By the way, when the pachinko hall is in business, that is, when the inspection base 90 is not used as the inspection means, the changeover switch 94 provided on the inspection base 90 is set to the relay state. Then, the game command output from the main control board 50, specifically, the command related to the display on the display unit 34, the sound generated from the speaker 59 </ b> S, and the control of the light emission mode of the side lamp 22, is transmitted to the inspection board 90. The game command is input to the input connector 41, and is output from the output connector 42, 42, 42 to each of the corresponding boards 55, 56, 70 according to the output destination of each game command. Thus, each of the boards 55, 56, and 70 can perform control in accordance with a game command from the main control board 50, and can play a game with the pachinko gaming machine 10.
[0105]
As described above, the inspection board 90 of the present embodiment inspects each of the boards 55, 56, and 70, and outputs a game command from the main control board 50 to each of the boards 55, 56, and 70 in the relay state. Therefore, it can be used as a relay base and a distributor. Thereby, the number of parts can be reduced as compared with the case where the relay base and the distributor are separately provided. Further, since the inspection base 90 has a base structure, it can be easily attached to the pachinko gaming machine 10.
[0106]
<Second embodiment>
This embodiment is shown in FIG. 12, and is different from the first embodiment in the method of selecting and switching the output destination of a command (inspection command, game command) output from the inspection base 90. Hereinafter, only the configuration different from that of the first embodiment will be described. Parts having the same configuration will be assigned the same reference numerals as those of the first embodiment, and redundant description will be omitted. Although FIG. 2 shows only the configuration corresponding to the display control board 70 and the audio control board 56, the configuration corresponding to the illuminant control board 55 has the same configuration.
[0107]
In the inspection board 90 of this embodiment, the three-state buffers 30, 30, and 30 for game commands from the main control board 50 to the boards 55, 56, and 70, and the inspection CPU 93 to the boards 55, 56, and 70, respectively. , Three-state buffers 31, 31, 31 for the inspection commands (inspection start command, next data request command).
[0108]
When the changeover switch 94 is in the inspection state, a predetermined code is input from the inspection CPU 93 to the decoder 96, and the three-state buffers 30, 30, and 30 for game commands are disabled, and the three-state buffers for inspection commands are disabled. The state buffers 31, 31, 31 are set to the enabled state. Further, a predetermined code is input to the decoder 98, and only the latch 97 corresponding to the selected board among the boards 55, 56, 70 is enabled, and the other two latches 97, 97 are disabled. Is done. As a result, when any one of the boards 55, 56, and 70 is being inspected, the game command from the main control board 50 cannot be transmitted to the boards 55, 56, and 70. The inspection command can be transmitted only to the inspection target substrate out of the substrates 55, 56, and 70.
[0109]
When the changeover switch 94 is in the relay state, a predetermined code is input from the inspection CPU 93 to the decoder 96, and the three-state buffers 30, 30, and 30 for game commands are enabled, and the three-state buffers for inspection commands are set. The buffers 31, 31, 31 are disabled. Thus, when playing a game, that is, when the changeover switch 94 is in the relay state, a game command from the main control board 50 is transmitted to each of the boards 55, 56, and 70 through the inspection board 90. You. That is, the inspection board 90 does not perform any processing on the game command, and outputs the input game command to each of the boards 55, 56, and 70 as it is.
[0110]
As described above, according to the present embodiment, when the changeover switch 94 is in the relay state, the game command input from the main control board 50 to the inspection board 90 passes through the three-state buffers 30, 30, 30, and becomes 55, 56 and 70. Thereby, the processing load on the inspection CPU 93 can be reduced as compared with the case where the inspection CPU 93 determines the output destination of the game command and transmits the game command to each of the bases 55, 56, 70. In addition, since the inspection board 90 outputs the input game command as it is to each board 55, 56, 70, even if the main control board 50 and each board 55, 56, 70 are directly connected by the harness 45, Each of the boards 55, 56, 70 can perform control. Thus, even when the inspection base 90 is removed, the pachinko gaming machine 10 can play a game.
[0111]
<Other embodiments>
The present invention is not limited to the above-described embodiments. For example, the following embodiments are also included in the technical scope of the present invention, and furthermore, various embodiments may be made without departing from the spirit of the present invention. It can be changed and implemented.
(1) In the first and second embodiments, the inspection base 90 of the present invention is provided in the pachinko gaming machine 10, but any gaming machine may be provided in a coin gaming machine, a slot machine, or the like. .
[0112]
(2) The connectors 40, 41, 42, and 43 have the same configuration as the output connector 40 of the main control board 50 and the output connector 42 of the test board 90, and the input connector 41 of the test board 90 and each board 55, As long as the input connectors 43 and 56 have the same configuration, all the connectors 40, 41, 42 and 43 may have the same configuration, or the output connectors 40 and 42 and the input connectors 41 and 43 may have different configurations. May be.
[0113]
(3) In the first and second embodiments, the inspection board 90 inspects the control data ROMs 70B, 56B, and 55B provided in the display control board 70, the voice control board 56, and the illuminant control board 55. The control data ROM provided on another board (for example, the main control board 50, the power supply board and the payout control board, etc.) may be configured to be inspected.
[0114]
(4) In the first and second embodiments, both the output connector 40 and the input connector 41 and the output connector 42 and the input connector 43 are connected via the harness 45. Alternatively, only one of the connectors may be connected via the harness 45, and the other connector may be directly connected to each other.
[0115]
(5) In the first and second embodiments, the control data ROM to be inspected is selected by operating the changeover switch 94. However, if the changeover switch 94 is set to the inspection state, the inspection base 90 can control each control data ROM. The ROMs 55B, 56B, and 70B may be inspected sequentially.
[0116]
(6) In the first and second embodiments, the inspection result is displayed on the result display unit 95, but may be displayed on the display unit.
[0117]
(7) The inspection base 90 may be always provided in the pachinko gaming machine 10 or may be attached to the pachinko gaming machine 10 only at the time of inspection.
[0118]
(8) In the first embodiment, a line for relaying between the main control board 50, the voice control board 56, and the display control board 70, and a test signal is output from the test CPU 93 to the voice control board 56 and the display control board 70. Although the line and the line were common (see FIG. 4), as shown in FIG. 13, the line that relays the main control board 50, the voice control board 56, and the display control board 70, and the voice control board from the inspection CPU 93. The configuration may be such that the line for outputting the inspection signal to the display control board 56 and the display control board 70 are separately provided.
[0119]
(9) In the first and second embodiments, the inspection data ROM 91 (inspection storage means), the input connector 41 (input section), and the output connector 42 (output section) are mounted on the electric board to be integrated. However, the term "integrally" of the present invention is not limited to this.For example, the storage unit for inspection, the input unit, and the output unit are mounted on separate electric boards, and these electric boards are fixed to each other. And the inspection storage means, the input unit and the output unit may be packaged together to form an integrated device.
[Brief description of the drawings]
FIG. 1 is a front view of a pachinko gaming machine to which an inspection board according to a first embodiment of the present invention is applied.
FIG. 2 is a rear view of the pachinko gaming machine.
FIG. 3 is a block diagram showing an electrical configuration of the pachinko gaming machine.
FIG. 4 is a block diagram showing transmission and reception of signals among a main control board, a display control board, and a voice control board;
FIG. 5 is a block diagram showing an electrical configuration of the inspection board.
FIG. 6 is a flowchart showing a main control program.
FIG. 7 is a flowchart showing a display control program.
FIG. 8 is a flowchart showing an inspection process.
FIG. 9 is a flowchart showing an inspection program.
FIG. 10 is a flowchart illustrating data determination processing.
FIG. 11 is a front view of a connection portion between a main control board, an inspection board, and a display control board.
FIG. 12 is a block diagram showing an electrical configuration of an inspection board according to a second embodiment.
FIG. 13 is a block diagram showing signal transmission / reception according to another embodiment (8).
[Explanation of symbols]
13 Display device (display)
22 ... Side lamp (light emitter)
40 ... output connector (coupling means)
41 ... input connector (input section, upper side coupling means)
42 output connector (output unit, lower side coupling means)
43 ... input connector (coupling means)
50: Main control board
55 ... Emission body control base
55B: luminous body control data ROM (control storage means)
56 Voice control base
56B: Voice control data ROM (control storage means)
59S: Speaker (voice generation means)
70 ... Display control board
70B: display control data ROM (control storage means)
90… Inspection base (game machine inspection device)
91 ... inspection data ROM (inspection storage means)
94 ... Changeover switch (switching means, selecting means)
95: Result display section (display means)
M: Main control program (control program)
N: Display control program (control program)

Claims (13)

A gaming machine inspection device connected to a gaming machine including a control storage unit storing a control program and a game control unit executing the control program, and inspecting the control program,
An inspection storage device storing an inspection program, wherein an inspection signal based on the inspection program can be transmitted to the game control unit,
An input unit for inputting an electric signal to the gaming machine inspection device from the outside, and an output unit for outputting the electric signal input from the input unit to the outside of the gaming machine inspection device, Gaming machine inspection equipment. The gaming machine inspection device according to claim 1, wherein the inspection storage means, the input unit, and the output unit are provided integrally. The gaming machine inspection device according to claim 2, wherein the inspection storage means, the input unit, and the output unit are provided on the same electric board. The gaming machine inspection device according to any one of claims 1 to 3, wherein an electric signal input to the input unit and an electric signal output from the output unit are the same. The gaming machine inspection device according to claim 1, wherein the output unit is used for both the output of the electric signal input to the input unit and the output of the inspection signal. The gaming machine inspection device according to claim 5, further comprising switching means for switching a signal output from the output unit to one of the electric signal and the inspection signal. The gaming machine is provided with first and second game control means as the game control means,
A game control signal as the electric signal transmitted to the first to second game control means in order for the second game control means to control a game is input to an input unit of the game machine inspection device. 7. The game control device according to claim 1, wherein the game control signal is output from an output unit of the gaming machine inspection device to the second game control means. Machine inspection equipment. An upper unit for detachably connecting to an input unit provided at an output unit of the first game control unit to electrically connect an input unit of the gaming machine inspection device to an output unit of the first game control unit; Side coupling means;
A lower part for detachably connecting to the coupling means provided at the input part of the second game control means for electrically connecting the output part of the gaming machine inspection device to the input part of the second game control means. Side coupling means,
The gaming machine inspection device according to claim 7, wherein the lower-side connecting unit has the same shape as a connecting unit provided in an output unit of the first game control unit. An upper unit for detachably connecting to an input unit provided at an output unit of the first game control unit to electrically connect an input unit of the gaming machine inspection device to an output unit of the first game control unit; Side coupling means;
A lower part for detachably connecting to the coupling means provided at the input part of the second game control means for electrically connecting the output part of the gaming machine inspection device to the input part of the second game control means. Side coupling means,
The gaming machine inspection device according to claim 7, wherein the upper-side coupling unit has the same shape as a coupling unit provided in an input unit of the second game control unit. The gaming machine inspection device is a distributor for distributing the game control signal received from the first game control means to a plurality of second game control means. 10. The gaming machine inspection device according to any one of 9 above. 10. The game machine testing machine according to claim 1, wherein a plurality of output units are provided, and a selection unit for selecting which output unit outputs the inspection signal is provided. A gaming machine inspection device according to item 1. The first game control means is a main control base for controlling a game state of the gaming machine,
The second game control means is provided on a sound control board for controlling a sound generation means provided on the game machine and / or a display control board for controlling a display provided on the game machine and / or on the game machine. The gaming machine inspection device according to any one of claims 8 to 11, wherein the inspection device is a luminous body control board for controlling a luminous body. 13. The gaming machine inspection device according to claim 1, further comprising a display unit that displays an inspection result of the control program.

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