JP4090556B2 - AV equipment characterized by IF circuit for connecting multiple AV equipment - Google Patents

Description

【００５１】
＜論理判断プロセッサ＞
論理判断プロセッサ１５は、Ｕin、Ｄin、Ｓinの［Ｓ］および［Ｐ］の状態に応じて次の（イ）〜（へ）の処理を行う。
（イ）Ｕin、Ｓinのいずれかの［Ｓ］が《有》の場合にはＤout の［Ｓ］を《有》にする（ａ，ｄ，ｈ，ｊ，ｋ，ｌ，ｎ）。
（ロ）Ｄin、Ｓinのいずれかの［Ｓ］が《有》の場合にはＵout の［Ｓ］を《有》にする（ｅ，ｆ，ｉ，ｊ，ｋ，ｌ，ｏ）。
（ハ）Ｕin、Ｄinのいずれかの［Ｓ］が《有》の場合にはＳout の［Ｓ］を《有》にする（ｂ，ｄ，ｅ，ｆ，ｈ，ｉ，ｎ、ｏ）。
（ニ）Ｕin、Ｓinのいずれかの［Ｐ］が《有》の場合にはＤout の［Ｐ］を《有》にする（ｃ，ｄ，ｆ，ｋ，ｍ，ｎ，ｏ）。
（ホ）Ｄin、Ｓinのいずれかの［Ｐ］が《有》の場合にはＵout の［Ｐ］を《有》にする（ｇ，ｈ，ｉ，ｌ，ｍ，ｎ，ｏ）。
（へ）Ｕin、Ｄinのいずれかの［Ｐ］が《有》の場合にはＳout の［Ｐ］を《有》にする（ｃ，ｄ，ｆ，ｇ，ｈ，ｉ，ｋ，ｌ）。
【００５２】
＜論理判断プロセッサによるＰｉｎＰ回路の制御＞
論理判断プロセッサはＰｉｎＰ回路を制御して次の（ト）〜（ル）の処理を行う。
（ト）Ｓinの［Ｓ］および［Ｐ］が共に《無》であり、かつ、Ｕinの［Ｓ］もしくは［Ｐ］が《有》であればＡＶinをＡＶout とする（ｂ，ｃ，ｄ，ｆ，ｈ）。
【００５３】
（チ）Ｓinの［Ｓ］が《有》であり、かつ、Ｕinの［Ｐ］が《無》の場合にはＡＶs をＡＶout とする（ｊ，ｌ）。
（リ）Ｓinの［Ｓ］が《有》であり、かつ、Ｕinの［Ｐ］が《有》の場合には、ＡＶinをメインチャンネル、ＡＶs をサブチャンネルとして合成し、これをＡＶout とする（ｋ）。
（ヌ）Ｓinの［Ｐ］が《有》であり、かつ、Ｕinの［Ｓ］が《無》の場合にはＡＶs をＡＶout とする（ｍ，ｏ）。
（ル）Ｓinの［Ｐ］が《有》であり、かつ、Ｕinの［Ｓ］が《有》の場合には、ＡＶs をメインチャンネル、ＡＶinをサブチャンネルとして合成し、これをＡＶout とする（ｎ）。
【００５４】
＜利用リクエスト信号を検知した場合の装置制御部の処理＞
利用リクエスト信号を検知した場合、装置制御部は以下の（ヲ）〜（ヨ）の処理を行う。
（ヲ）当該ＡＶ機器が待機状態（Ｓinの［Ｓ］が《有》）または稼動状態（Ｓinの［Ｐ］が《有》）であれば利用リクエストを受け付けない。
（ワ）Ｓout の［Ｓ］が《無》、かつ、Ｓout の［Ｐ］が《無》であれば（ａ）利用リクエストを受け付けて当該ＡＶ機器を待機状態とし、Ｓinの［Ｓ］を《有》にする（ｊ）。タイトル表示のための所定の時間が経過した後、またはカラオケ演奏スタート操作など利用者による稼動開始操作に応じて当該ＡＶ機器を稼動状態とし、Ｓinの［Ｐ］を《有》にし、Ｓinの［Ｓ］を《無》にする（ｍ）。
（カ）Ｓout の［Ｓ］が《無》、かつ、Ｓout の［Ｐ］が《有》であれば（ｃ，ｇ）利用リクエストを受け付けて当該ＡＶ機器を待機状態とし、Ｓinの［Ｓ］を《有》にする（ｋ，ｌ）。Ｓout の［Ｐ］が《無》に変わった段階（ｊ）で当該ＡＶ機器を稼動状態とし、Ｓinの［Ｐ］を《有》にし、Ｓinの［Ｓ］を《無》にする（ｍ）。
（ヨ）当該ＡＶ機器が休止状態になった場合にはＳinの［Ｐ］を《無》にする。
【００５５】
＝＝＝論理判断プロセッサの回路例＝＝＝
図４は、前述した論理判断プロセッサによる待機状態信号［Ｓ］および稼働状態信号［Ｐ］の入出力制御を行う回路の一例である。この例では待機状態信号［Ｓ］の入出力制御を行う回路と稼働状態信号［Ｐ］の入出力制御を行う回路とがＯＲ回路を用いた２ビットパラレルで構成されている。また、図５は各ＡＶ機器が連結された状態におけるこの回路の１ビット分の接続状態を示している。
【００５６】
＝＝＝ＡＶ機器の増設＝＝＝
ところで、新たにＡＶ機器を増設する場合には、最上流に位置するＡＶ機器、すなわち本実施例においてはＩＲＤ装置９に、新たに増設しようとするＡＶ機器のＡＶ出力を入力し、また、ＩＲＤ装置９に、新たに増設しようとするＡＶ機器の下流側ステータス信号出力端子を入力すればよく、この手順により何台でもＡＶ機器を接続することができる。
【００５７】
＝＝＝その他の応用＝＝＝
＜ＰｉｎＰ回路を用いない構成＞
待機状態を用意する必要がない場合には、入力される２つのＡＶ信号を適宜切り換えて一方のＡＶ信号を出力することができるＡＶ信号制御回路を前述したＰｉｎＰ回路の代わりに用いてもよい。この場合には、例えば次の（１）〜（７）の要件を備えた構成とする。
【００５８】
（１）ＩＦ回路は装置制御部、論理判断プロセッサ、ＡＶ信号制御回路により構成される。
【００５９】
（２）装置制御部は当該ＡＶ機器の動作を制御し、利用者が当該ＡＶ機器に設けられた操作パネル等の入力装置に対して所定の操作を行うことにより発生する利用リクエスト信号を検知する。ＡＶ信号制御回路は論理判断プロセッサにより制御される。
【００６０】
（３）ＡＶ信号制御回路には上流からのＡＶ信号ＡＶinおよび当該ＡＶ機器が生成するＡＶ信号ＡＶs を入力され、下流へＡＶout を出力する。論理判断プロセッサには上流側ステータス信号Ｕin、下流側ステータス信号Ｄin、装置制御部からのステータス信号Ｓinが入力され、装置制御部へ向けたステータス信号Ｓout 、上流へ向けたステータス信号Ｕout 、下流へ向けたステータス信号Ｄout を出力する。
【００６１】
（４）Ｕin、Ｄin、Ｕout 、Ｄout には稼動状態信号［Ｐ］が含まれる。稼動状態信号［Ｐ］は、《有》もしくは《無》の状態をとる。
【００６２】
（５）論理判断プロセッサは、Ｕin、Ｄin、Ｓinの［Ｐ］に応じて以下の（イ）〜（ハ）の処理を行う。
（イ）Ｕin、Ｓinのいずれかの［Ｐ］が《有》の場合にはＤout の［Ｐ］を《有》とし（ｂ，ｄ）、Ｕin、Ｓinのいずれの［Ｐ］も《無》の場合にはＤout の［Ｐ］を《無》とする（ａ，ｃ）。
（ロ）Ｄin、Ｓinのいずれかの［Ｐ］が《有》の場合にはＵout の［Ｐ］を《有》とし（ｃ，ｄ）、Ｄin、Ｓinのいずれの［Ｐ］も《無》の場合にはＵout の［Ｐ］を《無》とする（ａ，ｂ）。
（ハ）Ｕin、Ｄinのいずれかの［Ｐ］が《有》の場合にはＳout の［Ｐ］を《有》とし（ｂ，ｃ）、Ｕin、Ｄinのいずれの［Ｐ］も《無》の場合にはＳout の［Ｐ］を《無》にする（ａ，ｄ）。
【００６３】
（６）論理判断プロセッサはＡＶ信号制御回路に対し以下の（ニ）〜（ホ）の制御を行う。
（ニ）Ｕinの［Ｐ］が《有》の場合には、ＡＶinをＡＶout として出力する（ｂ）。（ホ）Ｓinの［Ｐ］が《有》の場合にはＡＶs をＡＶout として出力する（ｄ）。
【００６４】
（７）装置制御部は利用リクエストを検知した場合、以下の（ヘ）〜（ト）の処理を行う。
（へ）Ｓout の［Ｐ］が《無》であれば（ａ）利用リクエストを受け付けて当該ＡＶ機器を稼働状態とし、Ｓinの［Ｐ］を《有》とする（ｄ）。
（ト）当該ＡＶ機器が休止状態になった場合にはＳinの［Ｐ］を《無》にする。
【００６５】
表２は以上に説明した（イ）〜（ト）の処理をまとめたものである。ただし、この表では前述した《有》の状態を「１」、《無》の状態を「０」と表記している。
【００６６】
【表２】

【００６７】
＜ＢＧＶ（BackGround Video）機能＞
ところで、ＩＲＤ装置のように一旦稼動状態にするとＡＶ信号を連続的に出力し続けるタイプのＡＶ機器では、他のＡＶ機器が一台も稼動していない場合にディスプレイ＆スピーカシステムにＡＶ信号を出力するＢＧＶ（BackGround Video）提供機器として活用することができる。なお、この場合には例えばＩＲＤ装置のＩＦ回路に、Ｓout の稼動状態信号［Ｐ］および待機状態信号［Ｓ］を常に監視し、［Ｐ］と［Ｓ］がいずれも《無》であれば休止状態から一気に稼動状態に切り換え、Ｓout の待機状態信号［Ｓ］をさらに監視し続け、他のＡＶ機器のいずれかが待機状態になれば直ちに休止状態に切り換えるようにする機能を設ければよい。
【００６８】
＜複数のＡＶ機器に対して同時に利用リクエストがあった場合の処置＞
ところで、例えば待機中のＡＶ機器が存在しないときに、２台のＡＶ機器が同時に利用リクエストを検知したとする。この場合には、２台とも待機状態に切り換わってしまう恐れがある。これを回避する方法として例えば、待機状態へ移行するプロセスにおいて、ＩＦ回路は、まずステータス信号を待機状態に切り換え、適度な時間差をあけて下流側のステータス信号であるＤinの待機状態信号［Ｓ］を調べる。この時点で下流側に同時に待機状態になったＡＶ機器がないことを確認した上で装置制御部は当該ＡＶ機器への利用リクエストを受け付け、待機状態に移行する。もしも下流側に待機状態のＡＶ機器があれば、当該ＡＶ機器に対する利用リクエストは受け付けない。これで、下流側を優先にした回避処置がとれる。
【００６９】
＜複数台のＡＶ機器が同時に待機状態になれるようにする方法＞
待機状態信号［Ｓ］の数を［Ｓ１］、［Ｓ２］…のように複数個に拡張すれば、２台以上のＡＶ機器が同時に待機状態になれるようにすることができる。この場合、利用リクエストがある度に［Ｓ１］、［Ｓ２］…の状態を順に《有》にしていき、［Ｓ１］の機器が稼働状態に移行した段階で、［Ｓ２］−＞［Ｓ１］、［Ｓ３］−＞［Ｓ２］のように各待機状態信号の状態を順にシフトするようにする。尚、この場合、ディスプレイには稼働状態［Ｐ］にあるＡＶ機器による映像と、待機状態にある全てのＡＶ機器の映像を同時に表示してもよいが、これでは画面が見にくくなるので同時に表示する映像を限定し、表示パネル等に待機状態にあるＡＶ機器の台数や待機順等を表示するようにしてもよい。
【００７０】
＜課金装置による利用リクエスト＞
課金装置を備えるＡＶ機器であれば、この課金装置に対して利用料金の支払いがあった場合に前述した利用リクエスト信号が発生するようにしてもよい。但し、前述した実施例のように稼働状態および待機状態にあるＡＶ機器が１台しか存在できない場合には、課金装置に貨幣の不当飲み込みなどの不具合が生じないように各ＡＶ機器の稼動状態および待機状態に応じて貨幣の投入を許可したり禁止したりする機構を設ける必要がある。
【００７１】
＜ステータス信号の入出力インタフェース＞
前述した実施例におけるステータス信号の入出力インタフェースはＲＳ−２３２Ｃのようなシリアル伝送によるものであってもよいし、また、セントロニクス規格のようなパラレル規格のものであってもよく、各ＡＶ機器の性質等を考慮して最適なものを選択すればよい。
【００７２】
【発明の効果】
本発明によれば、従来のようにＡＶセレクタ等を用意して複雑なセッティング作業をすることなく同一のディスプレイ＆スピーカシステムを共用する形態で複数台のＡＶ機器を連結することができる。しかも、ＩＦ回路により接続規則が画一化されるのでＡＶ機器の増設、撤去、配置換え等における作業は従来に比べて格段に省力化される。
【図面の簡単な説明】
【図１】本発明の一実施例による各機器を連結した状態を説明する図である。
【図２】本発明の一実施例による各機器の動作例を説明する図である。
【図３】本発明の一実施例によるＩＦ回路の概略ブロック構成図である。
【図４】本発明の一実施例による論理判断プロセッサによる待機状態信号［Ｓ］および稼働状態信号［Ｐ］の入出力制御を行う回路の一例を示す図である。
【図５】本発明の一実施例による各ＡＶ機器が連結された状態における図５に示す回路の１ビット分の接続状態を示す図である。
【符号の説明】
３ ディスプレイ＆スピーカシステム
５ カラオケ装置
７ ビデオゲーム装置
８ ＤＶＤ装置
９ ＩＲＤ装置
１１ ＩＦ回路
１２ 装置制御部
１３ 映像合成回路
１５ 論理判断プロセッサ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an AV device characterized by an IF (InterFace) circuit for connecting a plurality of AV (Audio Visual) devices, and more particularly to a technique for sharing the same display, speaker, etc. among a plurality of AV devices.
[0002]
[Prior art]
Along with diversification of customer needs, karaoke rooms in recent karaoke shops offer not only karaoke equipment but also entertainment other than karaoke equipment such as video game equipment and IRD equipment (Integrated Receiver Decorder) for CS digital multi-channel broadcasting. More and more AV equipment is installed.
[0003]
By the way, these AV devices are configured such that a plurality of AV devices share the same display device or speaker device via a switching device such as an AV selector so that a space such as a narrow karaoke room can be used effectively. There are many cases.
[0004]
[Problems to be solved by the invention]
However, since a switching device such as an AV selector is required to smoothly control AV equipment having different properties, it is generally necessary to perform complicated setting work, especially when adding, removing, or rearranging AV equipment. This setting took a lot of work. Further, when installing a number of AV devices exceeding the number of connection ports prepared in advance in the switching device, it is necessary to newly add a switching device.
[0005]
The present invention has been made in view of such circumstances, and an object of the present invention is to form a common and simple way of adding, removing, rearranging and the like of AV devices in a form in which devices such as a display and a speaker are shared. The purpose is to be able to do it freely according to the connection rules.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, an invention according to claim 1 of the present invention is an AV apparatus characterized by an IF (InterFace) circuit for connecting a plurality of AV (Audio Visual) apparatuses, Each requirement of (1) to (7) shall be provided.
[0007]
(1) The IF circuit includes an apparatus control unit, a logic determination processor, and an AV signal control circuit.
[0008]
(2) The device control unit receives a function for controlling the operation of the AV device and a use request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device. And a function to detect. The AV signal control circuit is controlled by a logic determination processor, and has a function of appropriately switching between two input AV signals and outputting one AV signal.
[0009]
(3) The AV signal control circuit receives the AV signal AVin from the upstream and the AV signal AVs generated by the AV device, and outputs the AV signal AVout downstream. The logic judgment processor receives the upstream status signal Uin, the downstream status signal Din, and the status signal Sin from the device control unit, the status signal Sout for the device control unit, the status signal Uout for the upstream, and the downstream Status signal Dout is output.
[0010]
(4) Each AV device takes one of an active state and a sleep state, and Uin, Din, Uout, and Dout include an operation state signal [P] indicating whether or not there is an AV device in the operation state. The operating state signal [P] is in a state of << Yes >> or << No >>.
[0011]
(5) The logic determination processor performs the following processes (a) to (c) according to [P] of Uin, Din, and Sin.
(B) If either [Pin] of Uin or Sin is << Yes >>, set [P] of Dout to << Yes >>, and if [P] of Uin or Sin is << No >>, Dout [P] is set to << No >>.
(B) If [P] of either Din or Sin is “Yes”, the [P] of Uout is set to “Yes”, and if [P] of either Din or Sin is “No”, Uout [P] is set to << No >>.
(C) When either [Pin] of Uin or Din is << Yes >>, the [P] of Sout is set to << Yes >>, and when [P] of Uin or Din is << No >>, Sout Set [P] to << None >>.
[0012]
(6) The logic determination processor controls the following (d) to (e) for the AV signal control circuit.
(D) When Uin [P] is << Yes >>, AVin is output as AVout.
(E) When [P] of Sin is << Yes >>, AVs is output as AVout.
[0013]
(7) When the device control unit detects a use request, it performs the following processes (f) to (g).
(F) If [P] of Sout is << None >>, the use request is accepted and the AV device is set in an operating state, and [P] of Sin is set to << Yes >>.
(G) When the AV device is in a dormant state, set [P] of Sin to << None >>.
[0014]
The invention according to claim 2 of the present invention is an AV device characterized by an IF (InterFace) circuit for connecting a plurality of AV devices, and each of the following requirements (1) to (8): It shall be provided with.
[0015]
(1) The IF circuit includes an apparatus control unit, a logic determination processor, and a video synthesis circuit.
[0016]
(2) The device control unit receives a function for controlling the operation of the AV device and a use request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device. And a function to detect. The video composition circuit is controlled by a logic decision processor.
[0017]
(3) The AV signal AVin from the upstream and the AV signal AVs generated by the AV device are input to the video composition circuit, and the AV signal AVout is output downstream. The logic judgment processor receives the upstream status signal Uin, the downstream status signal Din, and the status signal Sin from the device control unit, the status signal Sout for the device control unit, the status signal Uout for the upstream, and the downstream Status signal Dout is output.
[0018]
(4) The video composition circuit synthesizes AVin and AVs and outputs the signal as AVout. At the time of synthesis, the two AV signals are allocated to the main channel and the sub channel, respectively.
[0019]
(5) Each AV device takes one of an active state, a standby state, and a hibernation state, and Uin, Din, Uout, Dout, Sin, and Sout are standby state signals indicating whether or not there is an AV device in the standby state. [S] and an operation state signal [P] indicating whether or not there is an AV device in an operation state. The standby state signal [S] and the operating state signal [P] are in a state of << Yes >> or << No >>.
[0020]
(6) The logic determination processor performs the following processes (a) to (f) in accordance with the standby state signal [S] and the operation state signal [P] of Uin, Din, and Sin.
(B) If [S] of either Uin or Sin is << Yes >>, the [S] of Dout is set to << Yes >>.
(B) If [S] of either Din or Sin is << Yes >>, Uout [S] is set to << Yes >>.
(C) When [S] of either Uin or Din is << Yes >>, the Sout [S] is set to << Yes >>.
(D) When [P] of either Uin or Sin is << Yes >>, Dout [P] is set to << Yes >>.
(E) If either [Pin] of Din or Sin is << Yes >>, the [P] of Uout is set to << Yes >>.
(F) If [P] of either Uin or Din is << Yes >>, the Sout [P] is set to << Yes >>.
[0021]
(7) The logic determination processor controls the video composition circuit as follows (G) to (L).
(G) If both [S] and [P] of Sin are << No >> and [S] or [P] of Uin is << Yes >>, AVin is set to AVout.
(H) When [S] of Sin is << Yes >> and [P] of Uin is << No >>, AVs is set to AVout.
(I) When [S] of Sin is << Yes >> and [P] of Uin is << Yes >>, AVin is synthesized as the main channel and AVs as the subchannel, and this is set as AVout.
(U) When [P] of Sin is << Yes >> and [S] of Uin is << No >>, AVs is set to AVout.
(L) When [P] of Sin is << Yes >> and [S] of Uin is << Yes >>, AVs is combined as a main channel and AVin as a subchannel, and this is set as AVout.
[0022]
(8) The apparatus control unit performs the following processes (wo) to (yo) when detecting the use request signal.
(W) If the AV device is in a standby state (Sin [S] is << Yes >>) or in an operating state (Sin [P] is << Yes >>), the use request is not accepted.
(W) If Sout's [S] is << None >> and Sout's [P] is << None >>, the usage request is accepted and the AV device is set in a standby state, and Sin [S] is set to << Yes >>. To do. Subsequently, the AV device is set in an operating state, [P] of Sin is set to “Yes”, and [S] of Sin is set to “No”.
(F) If Sout's [S] is << None >> and Sout's [P] is << Yes >>, the usage request is accepted and the AV device is set in a standby state, and Sin [S] is set to << Yes >>. To do. When the Sout [P] changes to << None >>, the AV device is put into operation, the Sin [P] is set to << Yes >>, and the Sin [S] is set to << No >>.
(E) When the AV device is in a dormant state, set [P] of Sin to << None >>.
[0023]
Here, the synthesis of AV signals by the video synthesis circuit is performed using, for example, a PinP (Picture in Picture) circuit.
[0024]
Further, as an input / output interface for each status signal, for example, the RS-232C standard is used.
[0025]
Furthermore, when the AV device includes a charging device, the usage request signal may be generated by inserting money, a prepaid card, an IC card, or the like into the charging device. .
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described in detail. As shown in FIG. 1, a display & speaker system 3 is connected to four AV devices, a karaoke device 5, a video game device 7, a DVD device 8, and an IRD device 9. Each AV device shares the display & speaker system 3. In the following description, the expressions upstream and downstream are used. However, the upstream side refers to the side far from the display & speaker system 3 described above when focusing on a specific AV device, and the downstream side. Means the side closer to the display & speaker system 3. For example, in this embodiment, if this expression is used with attention paid to the video game device 7, the karaoke device 5 is connected to the downstream side of the video game device 7, and the DVD device 8 or the IRD device. 9 is connected to the upstream side of the video game apparatus 7.
[0027]
=== Schematic configuration of each device ===
Next, the schematic configuration of each device will be described.
[0028]
<Display & speaker system>
The display & speaker system 3 includes an AV signal input terminal, a display that displays a video signal input to the AV terminal on a cathode ray tube by a video reproduction circuit, and an audio signal input to the AV terminal via an audio amplifier circuit. It is basically composed of a speaker for output. The display & speaker system 3 reproduces an AV signal input from the outside.
[0029]
<Karaoke equipment>
The karaoke device 5 includes a computer centered on a CPU, a RAM, a ROM, a hard disk device and the like for overall control of the entire device, a background video playback unit such as a laser disk device for playing back a background video used for karaoke performance, and music data. Is basically composed of an audio playback unit for playing back and an operation panel for receiving an instruction from the user. The karaoke apparatus 5 outputs the AV signal reproduced by the background video reproduction unit and the audio reproduction unit to the outside.
[0030]
<Video game device>
The video game apparatus 7 includes a computer centered on a CPU, ROM, RAM, video RAM, and the like that centrally controls the entire apparatus, a sound generator that generates sound effects and game music, an operation input unit such as a game controller, It is basically composed of an operation control unit that controls the operation input unit. The video game device 7 outputs game video and sound generated as the game progresses to the outside as AV signals.
[0031]
<DVD device>
The DVD device 8 is a DVD-ROM playback device having a detachable DVD-ROM mounting section, and plays back and outputs an AV signal recorded on the DVD-ROM.
[0032]
<IRD equipment>
The IRD device 9 receives and reproduces the digital broadcast program captured by the parabolic antenna and outputs the AV signal to the outside.
[0033]
=== Input / output of signals in each device ===
The following signals are input to and output from the input / output terminals of each device.
[0034]
<Display & speaker system>
The AV output signal of the karaoke apparatus 5 is input to the display & speaker system 3.
[0035]
<Karaoke equipment>
The karaoke apparatus 5 receives the AV output signal of the video game apparatus 7 and the upstream status signal.
[0036]
<Video game device>
The video game apparatus 7 receives the downstream status signal of the karaoke apparatus 5, the AV output signal of the DVD apparatus 8, and the upstream status signal.
[0037]
<DVD device>
The DVD device 8 receives the downstream status signal of the video game device 7, the AV output signal of the IRD device 9, and the upstream status signal.
[0038]
<IRD equipment>
A downstream status signal of the DVD device 8 is input to the IRD device 9.
[0039]
=== Operation of each AV device ===
<Operating state, standby state, hibernation state>
Each AV device has three states: an active state, a standby state, and a sleep state.
Operating state: A state in which the AV device is actually performing performance, playback, game play, and the like.
Standby state: The AV device is in a standby state in preparation for the operation state, and the AV device in the standby state shifts to the operation state when a predetermined condition is satisfied, such as the performance of the device in the operation state is completed. .
Dormant state: A state in which the device is neither in a standby state nor in an operating state.
[0040]
<Operation example>
FIG. 2 shows an operation example (s1 to s9) of each AV device with this configuration. In FIG. 2, if the state of the AV device is not particularly described, it means that the AV device is in a dormant state.
[0041]
▲ 1 ▼ s1, s2
s1 is a case where the karaoke apparatus 5 is in a standby state and other devices are in a resting state. The display displays a karaoke title screen on which the song name, artist name, etc. of the karaoke apparatus 5 are written. When the user performs a performance start requesting operation, the karaoke device 5 is in an operating state (s2), and a video such as lyrics telop and background video sent from the karaoke device 5 is displayed on the display, and a karaoke device is displayed from the speaker. Accompaniment music sent from 5 plays. When the performance is finished, the karaoke device 5 shifts to a pause state.
[0042]
(2) s3, s4
In s3, the karaoke apparatus 5 is in an operating state and the video game apparatus 7 is in a standby state. On the display, a video such as lyrics telop and background video sent from the karaoke device 5 is displayed as a parent screen, and a game title screen sent from the video game device 7 is displayed as a child screen. Accompaniment music sent from the karaoke device 5 flows from the speaker. When the performance of the karaoke device 5 is finished, the video game device 7 shifts to the operating state s4. When the game play ends, the video game apparatus 7 shifts to a pause state.
[0043]
(3) s5, s6
In s5, the video game apparatus 7 is in an operating state and the karaoke apparatus 5 is in a standby state. On the display, a game image sent from the video game device 7 is displayed as a parent screen, and an image having the karaoke title screen sent from the karaoke device 5 as a child screen is displayed. A game sound effect and game music sent from the video game apparatus 7 flow from the speaker. When the game play is completed, the video game apparatus 7 shifts to a pause state (s6), and the karaoke title screen is displayed as the parent screen. When the user performs a performance start request operation, the karaoke apparatus 5 shifts to an operating state.
[0044]
(4) s7, s8
In s7, the karaoke apparatus 5 is in an operating state and the DVD apparatus 8 is in a standby state. On the display, images such as lyrics telop and background images sent from the karaoke device 5 are displayed as a main screen, and a title screen such as a promotion video sent from the DVD device 8 is displayed as a sub screen. Accompaniment music is sent. When the performance of the karaoke device 5 is completed, the karaoke device 5 enters a resting state, and the DVD device 8 immediately shifts to an operating state (s8).
[0045]
▲ 5 ▼ s9
In s9, only the IRD device 9 is in operation. The display and the speaker reproduce video and audio sent from the IRD device 9.
[0046]
=== Configuration of IF Circuit ===
The operation of each AV device described above is realized by an IF (InterFace) circuit 11 built in each AV device. FIG. 3 is a schematic block diagram of the IF circuit. As shown in FIG. 3, the IF circuit includes a device control unit 12, a PinP (Picture in Picture) circuit 13, and a logic determination processor 15.
[0047]
<Device control unit>
The device control unit 12 controls the operation of the AV device. Further, a request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device is detected. The following signals are input to and output from the device controller 12.
Sin: Status signal for the logic decision processor Sout: Status signal from the logic decision processor <Logic decision processor>
The logic determination processor 15 inputs and outputs the following status signals.
Sout ... Status signal Sin for the device control unit ... Status signal Uin from the device control unit ... Status signal Uout from the upstream AV device ... Status signal Din for the upstream AV device ... Status signal from the downstream AV device Dout: Status signals for the downstream AV device Here, these status signals include a standby state signal [S] indicating the presence / absence of a standby AV device, and an operation state signal indicating the presence / absence of an active device. [P] is included. The standby state signal [S] and the operating state signal [P] are in a state of << Yes >> or << No >>.
[0048]
<PinP circuit>
The following AV signal is input to and output from the PinP circuit 13.
AVs AV signal AVin generated by the AV device AV signal AVout from the upstream AV device AV signal PinP circuit 13 directed to the downstream AV device or the display & speaker system synthesizes AVin and AVs and outputs the signal. Output as AVout. The PinP circuit 13 allocates two AV signals to the main channel and the subchannel, respectively, at the time of synthesis. The AV signal of the main channel becomes the above-mentioned video signal of the main screen, and the AV signal of the sub-channel becomes the above-mentioned video signal of the child screen. The PinP circuit 13 employs an audio signal included in the AV signal of the main channel as an AVout audio signal. The PinP circuit 13 is controlled by the logic decision processor 15 via the control bus.
[0049]
=== Operation of IF Circuit ===
Here, the operation of the IF circuit will be described. Table 1 summarizes the operations of the IF circuits (A) to (L) described below. However, in this table, the “presence” state described above is represented as “1”, and the state “presence” is represented as “0”.
[0050]
[Table 1]

[0051]
<Logical decision processor>
The logic determination processor 15 performs the following processes (a) to (f) according to the states of [S] and [P] of Uin, Din, and Sin.
(A) When either [S] of Uin or Sin is << Yes >>, [S] of Dout is set to << Yes >> (a, d, h, j, k, l, n).
(B) If [S] of either Din or Sin is << Yes >>, set [S] of Uout to << Yes >> (e, f, i, j, k, l, o).
(C) If [S] of either Uin or Din is << Yes >>, set [S] of Sout to << Yes >> (b, d, e, f, h, i, n, o).
(D) When either [Pin] of Uin or Sin is << Yes >>, [P] of Dout is set to << Yes >> (c, d, f, k, m, n, o).
(E) If [P] of either Din or Sin is << Yes >>, set [P] of Uout to << Yes >> (g, h, i, l, m, n, o).
(F) When [P] of either Uin or Din is << Yes >>, [P] of Sout is set to << Yes >> (c, d, f, g, h, i, k, l).
[0052]
<Control of PinP circuit by logic judgment processor>
The logic determination processor controls the PinP circuit to perform the following processes (g) to (l).
(G) If both [S] and [P] of Sin are << No >> and [S] or [P] of Uin is << Yes >>, AVin is set to AVout (b, c, d, f, h).
[0053]
(H) If [S] of Sin is << Yes >> and [P] of Uin is << No >>, AVs is set to AVout (j, l).
(I) When Sin [S] is << Yes >> and Uin [P] is << Yes >>, AVin is synthesized as the main channel and AVs as the subchannel, and this is set as AVout ( k).
(Nu) If Sin [P] is << Yes >> and Uin [S] is << None >>, AVs is set to AVout (m, o).
(L) When Sin [P] is << Yes >> and Uin [S] is << Yes >>, AVs is synthesized as a main channel and AVin as a subchannel, and this is set as AVout ( n).
[0054]
<Processing of device control unit when usage request signal is detected>
When the usage request signal is detected, the apparatus control unit performs the following processes (wo) to (yo).
(W) If the AV device is in a standby state (Sin [S] is << Yes >>) or in an operating state (Sin [P] is << Yes >>), the use request is not accepted.
(W) If [S] of Sout is << None >> and [P] of Sout is << None >> (a) Accept the use request and put the AV device in a standby state, and set [S] of Sin to << Yes ”(j). After a predetermined time for displaying the title has elapsed, or in response to the operation start operation by the user such as a karaoke performance start operation, the AV device is set to the operating state, the Sin [P] is set to “Yes”, and the Sin [ S] is set to << None >> (m).
(F) If Sout's [S] is << None >> and Sout's [P] is << Yes >>, (c, g) accepts a usage request and puts the AV device in a standby state, and Sin's [S] Is set to (Yes) (k, l). At the stage (j) when the Sout [P] changes to << No >>, the AV device is put into operation, the Sin [P] is set to << Yes >>, and the Sin [S] is set to << No >> (m). .
(E) When the AV device is in a dormant state, set [P] of Sin to << None >>.
[0055]
=== Example of Logic Decision Processor Circuit ===
FIG. 4 is an example of a circuit that performs input / output control of the standby state signal [S] and the operation state signal [P] by the logic determination processor described above. In this example, the circuit that performs input / output control of the standby state signal [S] and the circuit that performs input / output control of the operating state signal [P] are configured in 2-bit parallel using an OR circuit. FIG. 5 shows a connection state for one bit of this circuit in a state where each AV device is connected.
[0056]
=== Addition of AV equipment ===
By the way, when a new AV device is added, the AV output of the AV device to be newly added is input to the AV device located at the uppermost stream, that is, the IRD device 9 in this embodiment, and the IRD is added. It is only necessary to input the downstream status signal output terminal of the AV device to be newly added to the device 9, and any number of AV devices can be connected by this procedure.
[0057]
=== Other applications ===
<Configuration not using a PinP circuit>
When it is not necessary to prepare a standby state, an AV signal control circuit that can appropriately switch between two input AV signals and output one AV signal may be used instead of the above-described PinP circuit. In this case, for example, the following requirements (1) to (7) are satisfied.
[0058]
(1) The IF circuit includes a device control unit, a logic determination processor, and an AV signal control circuit.
[0059]
(2) The device control unit controls the operation of the AV device and detects a use request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device. . The AV signal control circuit is controlled by a logic decision processor.
[0060]
(3) The AV signal control circuit receives the AV signal AVin from the upstream and the AV signal AVs generated by the AV device, and outputs AVout downstream. The logic judgment processor receives the upstream status signal Uin, the downstream status signal Din, and the status signal Sin from the device control unit, the status signal Sout for the device control unit, the status signal Uout for the upstream, and the downstream Status signal Dout is output.
[0061]
(4) The operation state signal [P] is included in Uin, Din, Uout, and Dout. The operating state signal [P] is in a state of << Yes >> or << No >>.
[0062]
(5) The logic determination processor performs the following processes (a) to (c) according to [P] of Uin, Din, and Sin.
(B) If [P] of either Uin or Sin is << Yes >>, set [P] of Dout to << Yes >> (b, d), and any [P] of Uin or Sin is << No >> In this case, [P] of Dout is set to << None >> (a, c).
(B) When [P] of either Din or Sin is << Yes >>, set [P] of Uout to << Yes >> (c, d), and any [P] of Din or Sin is << No >> In this case, [P] of Uout is set to << None >> (a, b).
(C) When [P] of either Uin or Din is << Yes >>, set [P] of Sout to << Yes >> (b, c), and any [P] of Uin or Din is << No >> In this case, [P] of Sout is set to << None >> (a, d).
[0063]
(6) The logic determination processor controls the following (d) to (e) for the AV signal control circuit.
(D) When [P] of Uin is << Yes >>, AVin is output as AVout (b). (E) When [P] of Sin is << Yes >>, AVs is output as AVout (d).
[0064]
(7) When the device control unit detects a use request, it performs the following processes (f) to (g).
(F) If [P] of Sout is << None >> (a) Accept the usage request and put the AV device in the operating state, and set [P] of Sin to << Yes >> (d).
(G) When the AV device is in a dormant state, set [P] of Sin to << None >>.
[0065]
Table 2 summarizes the processes (A) to (G) described above. However, in this table, the “presence” state described above is expressed as “1”, and the state “presence” is expressed as “0”.
[0066]
[Table 2]

[0067]
<BGV (BackGround Video) function>
By the way, in an AV device that continuously outputs an AV signal once it is in an operating state, such as an IRD device, the AV signal is output to the display & speaker system when no other AV device is operating. It can be used as a BGV (BackGround Video) providing device. In this case, for example, the operating state signal [P] and the standby state signal [S] of Sout are always monitored in the IF circuit of the IRD device, and if both [P] and [S] are << None >>. A function may be provided that switches from the hibernation state to the operation state at once, continues to monitor the standby state signal [S] of Sout, and immediately switches to the hibernation state when any other AV device enters the standby state. .
[0068]
<Measures when there are simultaneous usage requests for multiple AV devices>
By the way, it is assumed that, for example, when there are no standby AV devices, two AV devices simultaneously detect use requests. In this case, there is a possibility that both of them will be switched to a standby state. As a method for avoiding this, for example, in the process of transitioning to the standby state, the IF circuit first switches the status signal to the standby state, and waits for an appropriate time difference and waits for the Din standby state signal [S]. Check out. At this time, after confirming that there is no AV device in the standby state at the downstream side at the same time, the device control unit accepts a use request for the AV device and shifts to the standby state. If there is a standby AV device on the downstream side, a use request for the AV device is not accepted. Thus, avoidance measures can be taken with priority given to the downstream side.
[0069]
<Method for enabling a plurality of AV devices to simultaneously enter standby>
If the number of standby state signals [S] is expanded to a plurality of numbers such as [S1], [S2]..., Two or more AV devices can be in a standby state at the same time. In this case, every time there is a use request, the status of [S1], [S2]... Is changed to “Yes” in order, and [S2]-> [S1] when the device of [S1] shifts to the operating state. , [S3]-> [S2], the state of each standby state signal is shifted in order. In this case, the video by the AV device in the operating state [P] and the images of all the AV devices in the standby state may be displayed simultaneously on the display. The video may be limited, and the number of AV devices in standby state and the standby order may be displayed on the display panel or the like.
[0070]
<Use request by billing device>
If the AV device is provided with a charging device, the usage request signal described above may be generated when the usage fee is paid to the charging device. However, when there is only one AV device in the operating state and the standby state as in the above-described embodiment, the operating state of each AV device and the It is necessary to provide a mechanism that permits or prohibits the insertion of money according to the standby state.
[0071]
<Status signal input / output interface>
The status signal input / output interface in the above-described embodiment may be a serial transmission such as RS-232C, or a parallel standard such as a Centronics standard. What is necessary is just to select an optimal thing in consideration of a property etc.
[0072]
【The invention's effect】
According to the present invention, it is possible to connect a plurality of AV devices in a form in which the same display & speaker system is shared without preparing an AV selector or the like and performing a complicated setting operation as in the prior art. In addition, since the connection rules are standardized by the IF circuit, the work of adding, removing, rearranging and the like of the AV equipment is remarkably labor-saving compared to the conventional case.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a state in which devices are connected according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an operation example of each device according to an embodiment of the present invention.
FIG. 3 is a schematic block diagram of an IF circuit according to an embodiment of the present invention.
FIG. 4 is a diagram illustrating an example of a circuit that performs input / output control of a standby state signal [S] and an operation state signal [P] by a logic determination processor according to an embodiment of the present invention.
5 is a diagram showing a connection state of one bit of the circuit shown in FIG. 5 in a state where AV devices according to an embodiment of the present invention are connected. FIG.
[Explanation of symbols]
3 Display & Speaker System 5 Karaoke Device 7 Video Game Device 8 DVD Device 9 IRD Device 11 IF Circuit 12 Device Control Unit 13 Video Composition Circuit 15 Logic Decision Processor

Claims (5)

This is an AV device characterized by an IF (InterFace) circuit for connecting a plurality of AV (Audio Visual) devices, and has the following requirements (1) to (7).
(1) The IF circuit includes an apparatus control unit, a logic determination processor, and an AV signal control circuit.
(2) The device control unit receives a function for controlling the operation of the AV device and a use request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device. And a function to detect. The AV signal control circuit is controlled by a logic determination processor, and has a function of appropriately switching between two input AV signals and outputting one AV signal.
(3) The AV signal control circuit receives the AV signal AVin from the upstream and the AV signal AVs generated by the AV device, and outputs the AV signal AVout downstream. The logic judgment processor receives the upstream status signal Uin, the downstream status signal Din, and the status signal Sin from the device control unit, the status signal Sout for the device control unit, the status signal Uout for the upstream, and the downstream Status signal Dout is output.
(4) Each AV device takes one of an active state and a sleep state, and Uin, Din, Uout, and Dout include an operation state signal [P] indicating whether or not there is an AV device in the operation state. The operating state signal [P] is in a state of << Yes >> or << No >>.
(5) The logic determination processor performs the following processes (a) to (c) according to [P] of Uin, Din, and Sin.
(B) If either [Pin] of Uin or Sin is << Yes >>, set [P] of Dout to << Yes >>, and if [P] of Uin or Sin is << No >>, Dout [P] is set to << No >>.
(B) If [P] of either Din or Sin is “Yes”, the [P] of Uout is set to “Yes”, and if [P] of either Din or Sin is “No”, Uout [P] is set to << No >>.
(C) When either [Pin] of Uin or Din is << Yes >>, the [P] of Sout is set to << Yes >>, and when [P] of Uin or Din is << No >>, Sout Set [P] to << None >>.
(6) The logic determination processor controls the following (d) to (e) for the AV signal control circuit.
(D) When Uin [P] is << Yes >>, AVin is output as AVout.
(E) When [P] of Sin is << Yes >>, AVs is output as AVout.
(7) When the device control unit detects a use request, it performs the following processes (f) to (g).
(F) If [P] of Sout is << None >>, the use request is accepted and the AV device is set in an operating state, and [P] of Sin is set to << Yes >>.
(G) When the AV device is in a dormant state, set [P] of Sin to << None >>. This is an AV device characterized by an IF (InterFace) circuit for connecting a plurality of AV devices, and has the following requirements (1) to (8).
(1) The IF circuit includes an apparatus control unit, a logic determination processor, and a video synthesis circuit.
(2) The device control unit receives a function for controlling the operation of the AV device and a use request signal generated when a user performs a predetermined operation on an input device such as an operation panel provided in the AV device. And a function to detect. The video composition circuit is controlled by a logic decision processor.
(3) The AV signal AVin from the upstream and the AV signal AVs generated by the AV device are input to the video composition circuit, and the AV signal AVout is output downstream. The logic judgment processor receives the upstream status signal Uin, the downstream status signal Din, and the status signal Sin from the device control unit, the status signal Sout for the device control unit, the status signal Uout for the upstream, and the downstream Status signal Dout is output.
(4) The video composition circuit synthesizes AVin and AVs and outputs the signal as AVout. At the time of synthesis, the two AV signals are allocated to the main channel and the sub channel, respectively.
(5) Each AV device takes one of an active state, a standby state, and a hibernation state, and Uin, Din, Uout, Dout, Sin, and Sout are standby state signals indicating whether or not there is an AV device in the standby state. [S] and an operation state signal [P] indicating whether or not there is an AV device in an operation state. The standby state signal [S] and the operating state signal [P] are in a state of << Yes >> or << No >>.
(6) The logic determination processor performs the following processes (a) to (f) in accordance with the standby state signal [S] and the operation state signal [P] of Uin, Din, and Sin.
(B) If [S] of either Uin or Sin is << Yes >>, the [S] of Dout is set to << Yes >>.
(B) If [S] of either Din or Sin is << Yes >>, Uout [S] is set to << Yes >>.
(C) When [S] of either Uin or Din is << Yes >>, the Sout [S] is set to << Yes >>.
(D) When [P] of either Uin or Sin is << Yes >>, Dout [P] is set to << Yes >>.
(E) If either [Pin] of Din or Sin is << Yes >>, the [P] of Uout is set to << Yes >>.
(F) If [P] of either Uin or Din is << Yes >>, the Sout [P] is set to << Yes >>.
(7) The logic determination processor controls the video composition circuit as follows (G) to (L).
(G) If both [S] and [P] of Sin are << No >> and [S] or [P] of Uin is << Yes >>, AVin is set to AVout.
(H) When [S] of Sin is << Yes >> and [P] of Uin is << No >>, AVs is set to AVout.
(I) When [S] of Sin is << Yes >> and [P] of Uin is << Yes >>, AVin is synthesized as the main channel and AVs as the subchannel, and this is set as AVout.
(U) When [P] of Sin is << Yes >> and [S] of Uin is << No >>, AVs is set to AVout.
(L) When [P] of Sin is << Yes >> and [S] of Uin is << Yes >>, AVs is combined as a main channel and AVin as a subchannel, and this is set as AVout.
(8) The apparatus control unit performs the following processes (wo) to (yo) when detecting the use request signal.
(W) If the AV device is in a standby state (Sin [S] is << Yes >>) or in an operating state (Sin [P] is << Yes >>), the use request is not accepted.
(W) If Sout's [S] is << None >> and Sout's [P] is << None >>, the usage request is accepted and the AV device is set in a standby state, and Sin [S] is set to << Yes >>. To do. Subsequently, the AV device is set in an operating state, [P] of Sin is set to “Yes”, and [S] of Sin is set to “No”.
(F) If Sout's [S] is << None >> and Sout's [P] is << Yes >>, the usage request is accepted and the AV device is set in a standby state, and Sin [S] is set to << Yes >>. To do. When the Sout [P] changes to << None >>, the AV device is put into operation, the Sin [P] is set to << Yes >>, and the Sin [S] is set to << No >>.
(E) When the AV device is in a dormant state, set [P] of Sin to << None >>. 3. An AV device characterized by an IF circuit for connecting a plurality of AV devices according to claim 2, wherein the synthesis of AV signals by said video composition circuit is performed using a PinP (Picture in Picture) circuit. . 4. An AV device characterized by an IF circuit for connecting a plurality of AV devices according to claim 1, wherein an input / output interface of each status signal is an RS-232C standard. The AV device includes a billing device, and the usage request signal is generated when money, a prepaid card, an IC card, or the like is inserted into the billing device. An AV device characterized by an IF circuit for connecting a plurality of AV devices according to claim 1.

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