JP4583517B2 - Image display system - Google Patents

Description

（ただし、ＲL ＝ＲL x ＋ＲL y 、ＲE ＝ＲE x ＋ＲE y 、ＲC ＝ＲC x ＋ＲC y であり、
ｎは導電層の電極間距離Ｌを入力位置表示装置の表示画面のドット幅１／Ｄｎで割った分割数、すな わちｎ＝Ｌ／（１／Ｄｎ ）であり、Ｄｎ は入力位置表示装置の１ｍｍ当たりのドット数。）
【００２３】
【発明の具体的説明】
以下、本発明に係る画像表示システムについて図面を用いて具体的に説明する。 本発明に係る画像表示システムは、描画タブレット１およびアナログスイッチ７を含む定電圧電源８からなる画像入力装置、入力位置検出装置１１および入力位置表示装置１２から構成されている。このうち、入力位置検出装置１１および入力位置表示装置１２は、従来から用いられているもので、Ａ／Ｄコンバーター９、ＣＰＵ１０から構成された入力位置検出装置および液晶表示パネル等で構成された表示装置が用いられている。
【００２４】
まず、画像入力装置を構成している描画タブレットについて説明する。
本発明で用いられる描画タブレット１は、形状およびサイズが互いに等しいＸ座標読み取りパネル２と、Ｙ座標読み取りパネル３とを具備し、Ｘ座標読み取りパネル２の片面に導電層４x およびＸ座標読み取り電極５x1 、５x2 が順次形成され、Ｙ座標読み取りパネル３の片面に導電層４y およびＹ座標読み取り電極５y1 、５y2 が順次形成されている。
【００２５】
さらに、Ｘ座標読み取り電極５x1 、５x2と定電圧電源８のアナログスイッチ７を接続する接続回路６x1 、６x2が形成されており、同様にＹ座標読み取り電極５y1 、５y2と定電圧電源８のアナログスイッチ７を接続する接続回路６y1 、６y2が形成されている。
【００２６】
Ｘ座標読み取りパネル２およびＹ座標読み取りパネル３のうちの一方、例えばＸ座標読み取りパネル２は、通常、可撓性を有する材料、たとえばポリエチレンテレフタレートフィルム（以下、ＰＥＴフィルムという。）のような透明プラスチックフィルムからなっている。
【００２７】
このＸ座標読み取りパネル２の好ましい厚さは、ペン入力の点から導電層４xの厚さを含めて５０μｍ〜１ｍｍである。
また、Ｙ座標読み取りパネル３は、可撓性であっても剛直であってもよい基板、例えばガラス基板からなっている。
【００２８】
これらの導電層４x および導電層４y は、通常、１×１０^-4〜１×１０^-1Ω・ｃｍ、好ましくは２×１０^-4〜４×１０^-2Ω・ｃｍの体積抵抗率を有し、かつ０．０１〜０．２μｍ、好ましくは０．０２〜０．０８μｍの膜厚を有している。
【００２９】
上記のような体積抵抗率を有する導電層４x および導電層４y は、例えばスパッター法等でＩＴＯなどの導電性物質からなる薄膜をＸ座標読み取りパネル２の片面およびＹ座標読み取りパネル３の片面に形成することによって得ることができる。
【００３０】
導電層４x および導電層４y のそれぞれの両端に形成されている、Ｘ座標読み取り電極５x1 、５x2およびＹ座標読み取り電極５y1 、５y2 の電極材料としては、銀などの金属微粒子が分散した樹脂が用いられている。
【００３１】
このような電極の形成法としては、上記の金属微粒子を樹脂に分散させたペ−ストを用いて導電層形成面の両端部に印刷する方法が一般的である。
Ｘ座標読み取り電極５x1 、５x2とアナログスイッチ７とを接続する接続回路６x1、６x2、およびＹ座標読み取り電極５y1 、５y2とアナログスイッチ７とを接続する接続回路６y1 、６y2も、電極と同様に金属微粒子分散樹脂のペ−ストを用いて、通常は導電層が形成されている基板の同一面上に印刷法で形成される。
【００３２】
本発明に係る画像入力装置において、描画タブレットのＸ座標読み取りパネル２およびＹ座標読み取りパネル３における、それぞれの導電層の電極間の抵抗値と電極の抵抗値と接続回路の抵抗値の合計値は、１００〜５０００Ωの範囲にあることが好ましい。すなわち、Ｘ座標読み取りパネル２の導電層の電極間の抵抗をＲL ｘとし、電極５x1 と５x2 の合計抵抗値をＲE ｘとし、電極とアナログスイッチとの接続回路６x1、６x2の合計抵抗値をＲC ｘとするとき、下記（１）式を満足していることが好ましい。
【００３３】
ＲL ｘ＋ＲE ｘ＋ＲC ｘ＝１００〜５，０００Ω （１）
同様に、Ｙ座標読み取りパネル３でも、導電層の電極間の抵抗をＲL ｙし、電極５y1 と５y2 の合計抵抗値をＲE ｙとし、電極とアナログスイッチとの接続回路６y1 、６y2の合計抵抗値をＲC ｙとするとき、下記（２）式を満足していることが好ましい。
【００３４】
ＲL ｙ＋ＲE ｙ＋ＲC ｙ＝１００〜５，０００Ω （２）
これらの全抵抗値が１００Ω未満の場合には、これらの電極間を流れる電流値によって描画タブレットで過大な電力が消費され、逆に５，０００Ωを越える場合には、これらの電極間にほとんど電流が流れず、さらに導電層の接触抵抗が大きくなり、接触抵抗によるノイズが激しくなり、例えば図１におけるＡ／Ｄコンバーター９およびＣＰＵ１０を経て検出される入力信号とノイズとの区別がつかなくなったり、あるいは検出される座標位置に位置ずれが生じたりするようになる。
【００３５】
本発明においては、画像入力装置におけるそれぞれのパネルの導電層抵抗値、電極抵抗値および接続回路抵抗値の合計抵抗値が１００〜５，０００Ωの範囲となるように、導電層４x 、導電層４y を形成する導電性材料および導電層の膜厚が選定されると同時に、導電層の電極間距離、電極や接続回路の材料、形成する電極や接続回路の幅および長さが設定される。
【００３６】
なお、Ｘ座標読み取りパネルの合計抵抗値と、Ｙ座標読み取りパネルの合計抵抗値とは、それぞれが１００〜５，０００Ωの範囲にあればよく、互いに異なる値であっても差支えない。
【００３７】
さらに、本発明においては前記のＸ座標読み取りパネルおよびＹ座標読み取りパネルにおけるそれぞれの導電層の電極間の抵抗値をＲL x、ＲL y とし、それぞれの電極の合計抵抗値をＲE x、ＲE y とし、それぞれの接続回路の合計抵抗値をＲC x、ＲC y としたとき、下記（３）式を満足することを特徴とするものである。
【００３８】
（ＲE ＋ＲC ）／ＲL ≦３／ｎ （３）
（ただし、ＲL ＝ＲL x ＋ＲL y 、ＲE ＝ＲE x ＋ＲE y 、ＲC ＝ＲC x ＋ＲC y であり、
ｎは導電層の電極間距離Ｌを表示装置のドット幅１／Ｄｎ で割った分割数、
すなわちｎ＝Ｌ／（１／Ｄｎ ）であり、Ｄｎ は１ｍｍ当たりのドット数。）
本発明で用いられる描画タブレットにおいては、導電層の抵抗値に対する電極の抵抗と接続回路の抵抗の合計抵抗値が小さく、特定の範囲内にある。
【００３９】
（ＲE ＋ＲC ）／ＲL が３／ｎよりも大きい場合、画像入力装置における入力位置と表示装置における表示位置とに表示ずれが観察され、特に高精度表示、大画面表示の場合にはこの表示ずれが顕著に目立ってくることがある。
【００４０】
さらに、本発明に用いられる描画タブレットの導電層においては、導電層全面にわたってその抵抗は均一である。すなわち、一方の電極端から他の電極端の方向に向かって抵抗を測定したとき、その抵抗は電極端からの距離に比例して直線的に増加する。この直線からのずれ、すなわち直線性の相関係数は、通常、0.95〜1.0の範囲にある。
【００４１】
このような直線性の相関係数は、次のような方法で算出される。
導電層の幅（電極が形成されている側）の長さを１０分割したときの９点から、対応する導電層への最短直線上を５mm間隔で抵抗を測定する（図３）。そのとき各分割したときの点における電極端からの距離（ｒi）とｒiにおける抵抗（Ｒi）としたとき、抵抗の直線性の相関係数を次式により算出する。こうして得られた９つ相関係数の平均を求める。
【００４２】
【数１】

【００４３】
【発明の効果】
本発明に係る画像表示システムにおいては、画像入力装置の描画タブレットにおけるそれぞれのパネルの導電層抵抗値と電極抵抗値と接続回路抵抗値の全抵抗値が１００〜５，０００Ωの範囲にある。さらに電極抵抗値と接続回路抵抗値の合計抵抗値と導電層抵抗値の抵抗比が小さい。従って、入力用ペン等で押圧されている描画タブレット表面の入力位置座標が低消費電力で検出されるとともに、入力位置と表示位置のずれが生じ難く、抵抗補正が少なくて済み、大画面表示あるいは高精度表示が可能である。
【００４４】
【実施例】
以下、本発明を実施例により説明するが、本発明はこれら実施例に限定されるものではない。
【００４５】
【実施例１】
ＰＥＴフィルムの片面に、横約１０ｃｍ、縦約１１ｃｍのＩＴＯ膜からなる導電層をスパッタ法で形成した。さらに、この導電層の周囲に絶縁ペースト（旭化学研究所製 ＣＲ−４２０Ｇ１）を用いて、スクリーン印刷法で絶縁層を形成した。 次に、ＩＴＯ膜上の縦両端部に長さ１０ｃｍ、幅５ｍｍの１対の電極（５x1、５x2）を形成し、この電極の中央よりそれぞれ長さ２０ｃｍ、幅３ｍｍ、および長さ３０ｃｍ，幅３ｍｍの接続回路（６x1および６x2）を、銀ペースト（藤倉化成製：ドータイトＦＡ３０１ＣＡ）を使用してスクリーン印刷法で前記絶縁層上に形成することにより、Ｘ座標読み取り電極間距離（Ｌ）が１０ｃｍ、導電層抵抗値（ＲLx）が４０００Ω、電極抵抗値（ＲEx）が１. ０Ω（０. ５Ω×２）、接続回路抵抗値（ＲCx）が７. ５Ω（３. ０Ω＋４. ５Ω）であるＸ座標読み取りパネルを作成した。
【００４６】
次に、ガラス基板の片面に上記のＸ座標読み取りパネルと同様の方法で、ＩＴＯ膜からなる横１０ｃｍ、縦１１ｃｍの導電層、および長さ１３ｃｍ、幅１ｃｍの１対の電極（５y1、５y2）、長さ２０ｃｍ、幅３ｍｍおよび長さ３０ｃｍ，幅３ｍｍの接続回路（６y1および６y2）を形成することにより、Ｙ座標読み取り電極間距離（Ｌ）が１０ｃｍ、導電層抵抗値（ＲLy）が４０００Ω、電極抵抗値（ＲEy）が０. ５Ω（０. ２５Ω×２）、接続回路抵抗値（ＲCy）が７. ５Ω（３. ０Ω＋４. ５Ω）であるＹ座標読み取りパネルを作成した。
【００４７】
上記のようにして作成したＸ座標読み取りパネルおよびＹ座標読み取りパネルの導電層について、それぞれの抵抗の直線性の相関係数を求めた。
さらに、このＹ座標読み取りパネルのＩＴＯ膜上にスクリーン印刷法により直径１００μｍ、高さ１５μｍの絶縁性ドットスペーサを５ｍｍのピッチで形成した。
【００４８】
以上のようにして得られた絶縁性ドットスペーサ付Ｙ座標読み取りパネルの上に、Ｘ座標読み取りパネルを、図１に示すようにＸ座標読み取り電極とＹ座標読み取り電極とが互いに直交し、それぞれの導電層が互いに対向するように、枠スペ−サ−を介して配置し、描画タブレットを組み立てた。
【００４９】
このようにして得られた描画タブレットは、アナログスイッチ７を介して定電圧定電流電源８と接続し、画像入力装置を組み立てた。この画像入力装置を、Ａ／Ｄコンバーター９およびＣＰＵ１０からなる入力位置検出装置、およびドット数３個／ｍｍの液晶表示画面を有する入力位置表示装置に接続した。このとき、前記の液晶表示画面の上に描画タブレットを重ね合わせ、描画タブレットの上から液晶表示画面が見えるように組み立てて、画像表示システムを構成した。
【００５０】
まず、５Ｖの電圧を描画タブレットに印加し、入力位置と表示位置が一致するような補正を行った場合と補正を行わない場合とについて、入力用ペンの先端で描画タブレット表面を押圧して押圧点のＸ座標およびＹ座標と、表示された液晶表示画面のＸ座標およびＹ座標との表示ズレ、すなわち入力位置に対する表示位置のズレを観察した。
観察方法Ａ：入力位置と表示位置を拡大鏡で観察。
【００５１】
表示ズレのあるもの：×
表示ズレのないもの：○
観察方法Ｂ：入力位置と表示位置をパネルから５０ｃｍ離れた距離から目視観察。
【００５２】
表示ズレのあるもの：×
表示ズレのないもの：○
さらに、経時変化テストとして、テスト開始後途中で補正することなく６月間稼働状態とした後に前記の観察方法Ａにより表示ズレを観察した。
【００５３】
表示ズレのあるもの：×
表示ズレのないもの：○
結果を表１に示す。
消費電力の測定
また、前記したＸ座標読み取りパネルおよびＹ座標読み取りパネルに５Ｖの電圧を印加して、電極間を流れる電流を測定し、各パネル（接続回路を含む）の消費電力を算出した。
【００５４】
結果を表１に示す。
【００５５】
【実施例２】
Ｘ座標読み取りパネルおよびＹ座標読み取りパネルの導電層の抵抗値がそれぞれ２８００Ωである以外は、実施例１と同様のパネルを作成した。
【００５６】
これらのパネルにおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００５７】
結果を表１に示す。
【００５８】
【実施例３】
Ｘ座標読み取りパネルおよびＹ座標読み取りパネルの導電層の抵抗値をそれぞれ４００Ωとし、それぞれの電極抵抗値、接続回路抵抗値が表１に示すものとした以外は実施例１と同様にして各パネルを作成した。
【００５９】
これらのパネルにおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００６０】
結果を表１に示す。
【００６１】
【実施例４】
Ｘ座標読み取りパネルおよびＹ座標読み取りパネルの導電層の抵抗値、電極抵抗値、接続回路抵抗値が表１に示すものとした以外は実施例１と同様にして各パネルを作成した。
【００６２】
これらのパネルにおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００６３】
結果を表１に示す。
【００６７】
【比較例２】
Ｘ座標読み取りパネルおよびＹ座標読み取りパネルの導電層の抵抗値がそれぞれ４００Ωである以外は、実施例１と同様のパネルを作成した。
【００６８】
これらのパネルおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００６９】
結果を表１に示す。
【００７０】
【比較例３】
Ｘ座標読み取りパネルおよびＹ座標読み取りパネルの導電層の抵抗値がそれぞれ ８０Ωである以外は、実施例１と同様のパネルを作成した。
【００７１】
これらのパネルにおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００７２】
結果を表１に示す。
【００７３】
【比較例４】
Ｘ座標読み取りパネルの導電層の抵抗値が２００Ω、Ｙ座標読み取りパネルの導電層の抵抗値が８００Ωである以外は、実施例１と同様のパネルを作成した。
【００７４】
これらのパネルおけるそれぞれの抵抗の直線性の相関係数を算出し、実施例１と同様に描画タブレットを組み立て、表示位置のズレを観察し、経時変化テストおよび消費電力の測定を行った。
【００７５】
結果を表１に示す。
【００７６】
【表１】

【図面の簡単な説明】
【図１】本発明に係る画像表示システムおよび画像入力装置に用いられる描画タブレットを説明するための図面である。
【図２】画像入力ペンの押圧位置の違いによる表示ずれを表す模式図である。
【図３】直線性の相関係数の測定点を示す。
【符号の説明】
１ …描画タブレット
２ …Ｘ座標読み取りパネル
３ …Ｙ座標読み取りパネル
４x …Ｘ座標導電層
４y …Ｙ座標導電層
５x1 …Ｘ座標読み取り電極
５x2 …Ｘ座標読み取り電極
５y1 …Ｙ座標読み取り電極
５y2 …Ｙ座標読み取り電極
６x1、６x2 …Ｘ座標読み取り電極とアナログスイッチ接続回路
６y1、６y2 …Ｙ座標読み取り電極とアナログスイッチ接続回路
７ …アナログスイッチ
８ …定電圧定電流電源
９ …Ａ／Ｄコンバーター
１０ …ＣＰＵ
１１ …入力位置検出装置
１２ …入力位置表示装置[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image display system suitable for pen touch image input and display. More specifically, the present invention relates to an image display system with low power consumption, less display shift, and less correction for correcting display shift. .
[0002]
TECHNICAL BACKGROUND OF THE INVENTION
Conventionally, as a drawing tablet used for an image input apparatus for an image display system, an analog drawing tablet as illustrated in FIG. 1 is known.
[0003]
The drawing tablet 1 includes an X coordinate reading panel 2 and a Y coordinate reading panel 3, and conductive layers 4x and 4y are formed on one side of the X coordinate reading panel 2 and one side of the Y coordinate reading panel 3, respectively. ing.
[0004]
On the surface of the conductive layer 4x formed on one side of the X-coordinate reading panel 2, a pair of X-coordinate reading electrodes 5x1 and 5x2 are formed opposite to each other. A pair of Y coordinate reading electrodes 5y1 and 5y2 are also formed on both surfaces of the conductive layer 4y formed on one side of the Y coordinate reading panel 3 so as to face each other.
[0005]
In the drawing tablet 1, the conductive layer 4x formed on one side of the X coordinate reading panel 2 and the conductive layer 4y formed on one side of the Y coordinate reading panel 3 are interposed via an insulating spacer (not shown). Opposing each other substantially in parallel. In the drawing tablet 1, the X coordinate reading electrodes 5x1, 5x2 and the Y coordinate reading electrodes 5y1, 5y2 are arranged so as to be orthogonal to each other.
[0006]
In such a drawing tablet 1, the X coordinate reading electrodes 5x1, 5x2 and the Y coordinate reading electrodes 5y1, 5y2 are connected to the constant voltage and / or via the analog switch 7 by the connection circuits 6x1, 6x2 and the connection circuits 6y1, 6y2, respectively. It is connected to a constant current power supply 8. Further, the image input device is connected to an input position detection device 11 and an input position display device 12 including an A / D converter 9 and a CPU 10, thereby constituting an image display system.
[0007]
The input position detection method in the analog type position coordinate reading method includes a voltage switching method and a current division method. Here, the case of the voltage switching method will be described. When the constant voltage (constant current) power supply 8 is applied, the analog switch 7 is repeatedly switched at high speed, whereby the constant voltage power supply 8 is electrically connected to the X coordinate reading electrodes 5x1 and 5x2, and the Y coordinate reading electrode 5y1. 5y2 is electrically connected to the input position detecting device position 11, the constant voltage power supply 8 is electrically connected to the Y coordinate reading electrodes 5y1, 5y2, and the X coordinate reading electrodes 5x1, 5x2 are input position detecting devices. 11 and the state electrically connected to 11 are alternately repeated at high speed.
[0008]
When the surface of the X coordinate reading panel of the drawing tablet 1 is pressed with the input pen while the image display system is driven in this way, the conductive layer 4x of the X coordinate reading panel 2 and the conductive layer 4y of the Y coordinate reading panel are brought together. Conducts by contact at point A (Lx, Ly).
[0009]
In this state, when a constant voltage is applied to the X-coordinate reading electrode, a constant voltage is applied to the entire X-coordinate reading panel, and the voltage applied to the point A distributed by the X coordinate (X coordinate) becomes conductive A point. This voltage (X coordinate) is applied to the Y coordinate reading panel through the input position detection device 11.
[0010]
Next, when a constant voltage is applied to the Y-coordinate reading electrode, a constant voltage is applied to the entire Y-coordinate reading panel, and the voltage applied to the point A distributed by the Y-coordinate (Y-coordinate) is read through the conductive A point. When the voltage (Y coordinate) is applied to the panel and detected by the input position detection device 11, the position coordinates (Lx, Ly) of point A are detected.
[0011]
In the image input device as described above, depending on the drawing tablet 1, power consumption required for image input becomes too large, or the surface of the drawing tablet 1 is pressed with an input pen while the image input device is driven. However, there is a problem that the position of the pressing point may not be accurately detected by the input position detecting device.
[0012]
As a drawing tablet that solves such problems, the inventors of the present application have previously proposed, in Japanese Patent Application Laid-Open No. 7-104909, that the resistance value between electrodes of the conductive layer is controlled within a predetermined range.
[0013]
By the way, in such a drawing tablet, conventionally, an electrode formed in a conductive layer or a connection circuit for connecting an electrode and an analog switch has been formed of a pure metal such as gold or silver. However, although metal has low resistance and excellent spreadability, it has problems in that it is inferior in transparency, adhesiveness, strength, weather resistance (environmental resistance), and it is difficult to form fine circuits and films. It was.
[0014]
For this reason, although there is a defect that the resistance is larger than that of metal, there is a method of forming an electrode or a connection circuit by printing on a substrate such as a film using a paste in which metal fine particles such as silver are dispersed in a resin. It has been taken.
[0015]
The resistance value of the electrode and connection circuit formed of such a metal fine particle dispersed resin is small compared to the resistance value of the conductive layer, but cannot be ignored. Therefore, it is necessary to make these resistance values as small as possible.
[0016]
However, even if the resistance value of the electrode and the resistance value of the connection circuit are controlled within a predetermined range, if the ratio of the electrode resistance value and / or the connection circuit resistance value to the conductive layer resistance value is large, the X coordinate of the pressing point and Display displacement may occur between the Y coordinate and the display position of the display device. Further, when the resistance values of these electrodes and the connection circuit are changed in usage environment (for example, temperature change) or changed with time, the same display deviation occurs, and accurate coordinates may not be detected.
[0017]
For example, as shown in FIG. 2, the electrode resistance (RE x) varies depending on the pressing position of the image input pen, and the resistance of the electrode increases toward the end of the tablet, which may cause display displacement. . Such a display shift is less likely to occur when the display screen of the display device is small, but the display shift becomes significant when the display screen is large, and is particularly unsuitable for high-precision display with a high pixel density. There is a drawback of being.
[0018]
For this reason, initial resistance correction is performed at the time of product shipment so that the input position matches the display position. In addition, the resistance values of the conductive layer, electrode, and connection circuit may change over time or depending on the usage environment, resulting in display shifts. Therefore, a program that can correct resistance at multiple points in the conductive layer of the tablet during use Software may be incorporated.
[0019]
By the way, in order to increase the display accuracy of the image display system, it is preferable that the number of correction points is large, but for this reason, there are problems such as an increase in the capacity of the computer and time and cost when performing initial resistance correction. there were. Also, resistance correction during use has been a problem in terms of convenience.
[0020]
OBJECT OF THE INVENTION
The present invention is intended to solve the above-described problems, and can detect and display the position coordinates of the surface of the drawing tablet pressed by the input pen with low power consumption. An object of the present invention is to provide an image display system in which display deviation is less likely to occur in a screen display device, and resistance correction is not required and image input and display can be performed with high accuracy.
[0021]
SUMMARY OF THE INVENTION
An image display system according to the present invention includes an image input device, an input position detection device, and an input position display device. The image input device includes a conductive layer on one side of an insulating substrate and a pair of ends on the surface of the conductive layer. It consists of a drawing tablet in which two panels formed with electrodes facing each other are arranged via a spacer so that the respective conductive layers face each other in parallel, and a constant voltage and / or constant current power source,
(1) A connection circuit that connects each electrode of the two panels and the constant voltage and / or constant current power source, and the electrode is made of a resin in which metal fine particles are dispersed,
(2) The resistance values between the electrodes in the conductive layers of the two panels are RL x and RL y, and the resistance values of the electrodes of the two panels are RE x and RE y, respectively. When the resistance values of the connection circuits of the panels are denoted by RC x and RC y, the following expressions (1), (2) and (3) are satisfied.
[0022]

(However, RL = RLx + RLy, RE = REx + REy, RC = RCx + RCy,
n is the number of divisions obtained by dividing the inter-electrode distance L of the conductive layer by the dot width 1 / Dn of the display screen of the input position display device, that is, n = L / (1 / Dn), and Dn is the input position display Number of dots per mm of device. )
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an image display system according to the present invention will be specifically described with reference to the drawings. The image display system according to the present invention includes an image input device including a constant voltage power source 8 including a drawing tablet 1 and an analog switch 7, an input position detection device 11, and an input position display device 12. Among these, the input position detection device 11 and the input position display device 12 are conventionally used, and an input position detection device constituted by an A / D converter 9 and a CPU 10 and a display constituted by a liquid crystal display panel or the like. The device is used.
[0024]
First, a drawing tablet constituting the image input apparatus will be described.
The drawing tablet 1 used in the present invention includes an X coordinate reading panel 2 and a Y coordinate reading panel 3 having the same shape and size, and a conductive layer 4x and an X coordinate reading electrode 5x1 on one side of the X coordinate reading panel 2. 5x2 are sequentially formed, and a conductive layer 4y and Y coordinate reading electrodes 5y1 and 5y2 are sequentially formed on one surface of the Y coordinate reading panel 3.
[0025]
Further, connection circuits 6x1 and 6x2 for connecting the X coordinate reading electrodes 5x1 and 5x2 and the analog switch 7 of the constant voltage power source 8 are formed. Similarly, the Y coordinate reading electrodes 5y1 and 5y2 and the analog switch 7 of the constant voltage power source 8 are formed. Are formed. Connection circuits 6y1 and 6y2 are formed.
[0026]
One of the X coordinate reading panel 2 and the Y coordinate reading panel 3, for example, the X coordinate reading panel 2, is usually a flexible material such as a transparent plastic such as a polyethylene terephthalate film (hereinafter referred to as a PET film). It consists of a film.
[0027]
The preferable thickness of the X coordinate reading panel 2 is 50 μm to 1 mm including the thickness of the conductive layer 4 x from the point of pen input.
The Y coordinate reading panel 3 is made of a substrate that may be flexible or rigid, for example, a glass substrate.
[0028]
These conductive layers 4x and 4y usually have a volume resistivity of 1 × 10 ⁻⁴ to 1 × 10 ⁻¹ Ω · cm, preferably 2 × 10 ⁻⁴ to 4 × 10 ⁻² Ω · cm. And a film thickness of 0.01 to 0.2 μm, preferably 0.02 to 0.08 μm.
[0029]
For the conductive layer 4x and the conductive layer 4y having the above-described volume resistivity, a thin film made of a conductive material such as ITO is formed on one side of the X coordinate reading panel 2 and one side of the Y coordinate reading panel 3 by, for example, sputtering. Can be obtained.
[0030]
As the electrode material of the X coordinate reading electrodes 5x1 and 5x2 and the Y coordinate reading electrodes 5y1 and 5y2 formed on both ends of the conductive layer 4x and the conductive layer 4y, a resin in which metal fine particles such as silver are dispersed is used. ing.
[0031]
As a method of forming such an electrode, a method of printing on both ends of the conductive layer forming surface using a paste in which the above metal fine particles are dispersed in a resin is generally used.
The connection circuits 6x1 and 6x2 for connecting the X-coordinate reading electrodes 5x1 and 5x2 and the analog switch 7 and the connection circuits 6y1 and 6y2 for connecting the Y-coordinate reading electrodes 5y1 and 5y2 and the analog switch 7 are also made of metal fine particles in the same manner as the electrodes. It is usually formed by a printing method on the same surface of a substrate on which a conductive layer is formed using a paste of a dispersion resin.
[0032]
In the image input device according to the present invention, in the X coordinate reading panel 2 and the Y coordinate reading panel 3 of the drawing tablet, the total value of the resistance value between the electrodes of each conductive layer, the resistance value of the electrode, and the resistance value of the connection circuit is , Preferably in the range of 100 to 5000 Ω. That is, the resistance between the electrodes of the conductive layer of the X coordinate reading panel 2 is RL x, the total resistance value of the electrodes 5x1 and 5x2 is RE x, and the total resistance value of the connection circuits 6x1 and 6x2 between the electrodes and the analog switch is RC. When x, it is preferable that the following formula (1) is satisfied.
[0033]
RL x + RE x + RC x = 100 to 5,000 Ω (1)
Similarly, in the Y coordinate reading panel 3, the resistance between the electrodes of the conductive layer is RL y, the total resistance value of the electrodes 5y1 and 5y2 is RE y, and the total resistance value of the connection circuits 6y1 and 6y2 between the electrodes and the analog switch. Is preferably RC y, the following formula (2) is preferably satisfied.
[0034]
RL y + RE y + RC y = 100 to 5,000 Ω (2)
When these total resistance values are less than 100Ω, excessive power is consumed in the drawing tablet due to the current value flowing between these electrodes, and conversely, when it exceeds 5,000Ω, almost no current flows between these electrodes. Does not flow, the contact resistance of the conductive layer increases, noise due to the contact resistance becomes intense, for example, it becomes impossible to distinguish between the input signal and noise detected through the A / D converter 9 and the CPU 10 in FIG. Alternatively, a positional shift may occur at the detected coordinate position.
[0035]
In the present invention, the conductive layer 4x and the conductive layer 4y are set so that the total resistance value of the conductive layer resistance value, the electrode resistance value, and the connection circuit resistance value of each panel in the image input device is in the range of 100 to 5,000 Ω. The film thickness of the conductive material and conductive layer forming the electrode is selected, and at the same time, the distance between the electrodes of the conductive layer, the material of the electrode and connection circuit, and the width and length of the electrode and connection circuit to be formed are set.
[0036]
The total resistance value of the X coordinate reading panel and the total resistance value of the Y coordinate reading panel may be in the range of 100 to 5,000 Ω, and may be different from each other.
[0037]
Further, in the present invention, the resistance values between the electrodes of the respective conductive layers in the X coordinate reading panel and the Y coordinate reading panel are set as RL x and RL y, and the total resistance values of the respective electrodes are set as RE x and RE y. When the total resistance value of each connection circuit is RC x and RC y, the following expression (3) is satisfied.
[0038]
(RE + RC) / RL≤3 / n (3)
(However, RL = RLx + RLy, RE = REx + REy, RC = RCx + RCy,
n is the number of divisions obtained by dividing the interelectrode distance L of the conductive layer by the dot width 1 / Dn of the display device,
That is, n = L / (1 / Dn), where Dn is the number of dots per mm. )
In the drawing tablet used in the present invention, the total resistance value of the resistance of the electrode and the resistance of the connection circuit with respect to the resistance value of the conductive layer is small and within a specific range.
[0039]
When (RE + RC) / RL is greater than 3 / n, a display shift is observed between the input position in the image input device and the display position in the display device, and this display shift is particularly the case for high-precision display and large-screen display. May be noticeable.
[0040]
Furthermore, the resistance of the conductive layer of the drawing tablet used in the present invention is uniform over the entire surface of the conductive layer. That is, when the resistance is measured from one electrode end toward the other electrode end, the resistance increases linearly in proportion to the distance from the electrode end. The deviation from this straight line, that is, the linear correlation coefficient, is usually in the range of 0.95 to 1.0.
[0041]
Such a linear correlation coefficient is calculated by the following method.
The resistance is measured at intervals of 5 mm on the shortest straight line from the nine points when the width of the conductive layer (the side on which the electrode is formed) is divided into 10 parts (FIG. 3). At this time, when the distance (ri) from the electrode end at each divided point and the resistance (Ri) at ri are used, a correlation coefficient of resistance linearity is calculated by the following equation. The average of the nine correlation coefficients thus obtained is obtained.
[0042]
[Expression 1]

[0043]
【The invention's effect】
In the image display system according to the present invention, the total resistance values of the conductive layer resistance value, the electrode resistance value, and the connection circuit resistance value of each panel in the drawing tablet of the image input device are in the range of 100 to 5,000Ω. Furthermore, the resistance ratio between the total resistance value of the electrode resistance value and the connection circuit resistance value and the conductive layer resistance value is small. Therefore, the input position coordinates on the surface of the drawing tablet being pressed by the input pen or the like are detected with low power consumption, the deviation between the input position and the display position is less likely to occur, less resistance correction is required, and the large screen display or High-precision display is possible.
[0044]
【Example】
EXAMPLES Hereinafter, although an Example demonstrates this invention, this invention is not limited to these Examples.
[0045]
[Example 1]
A conductive layer made of an ITO film having a width of about 10 cm and a length of about 11 cm was formed on one side of the PET film by a sputtering method. Further, an insulating layer (CR-420G1 manufactured by Asahi Chemical Research Laboratory) was used around the conductive layer to form an insulating layer by screen printing. Next, a pair of electrodes (5x1, 5x2) having a length of 10 cm and a width of 5 mm are formed at both longitudinal ends on the ITO film, and 20 cm in length, 3 mm in width, and 30 cm in length from the center of this electrode, respectively. By forming a 3 mm connection circuit (6x1 and 6x2) on the insulating layer by using a silver paste (made by Fujikura Kasei: Dotite FA301CA) on the insulating layer, the distance (L) between the X coordinate reading electrodes is 10 cm. The conductive layer resistance value (RLx) is 4000Ω, the electrode resistance value (REx) is 1.0Ω (0.5Ω × 2), and the connection circuit resistance value (RCx) is 7.5Ω (3.0Ω + 4.5Ω). A coordinate reading panel was created.
[0046]
Next, in the same manner as the above X coordinate reading panel on one side of the glass substrate, a 10 cm wide and 11 cm long conductive layer made of an ITO film, and a pair of electrodes (5y1, 5y2) having a length of 13 cm and a width of 1 cm. By forming a connection circuit (6y1 and 6y2) having a length of 20 cm, a width of 3 mm, a length of 30 cm, and a width of 3 mm, the distance between the Y coordinate reading electrodes (L) is 10 cm, the conductive layer resistance value (RLy) is 4000Ω, A Y coordinate reading panel having an electrode resistance value (REy) of 0.5Ω (0.25Ω × 2) and a connection circuit resistance value (RCy) of 7.5Ω (3.0Ω + 4.5Ω) was prepared.
[0047]
For the conductive layers of the X coordinate reading panel and the Y coordinate reading panel prepared as described above, the correlation coefficient of the linearity of each resistance was obtained.
Furthermore, insulating dot spacers having a diameter of 100 μm and a height of 15 μm were formed on the ITO film of the Y coordinate reading panel by a screen printing method at a pitch of 5 mm.
[0048]
On the Y coordinate reading panel with insulating dot spacers obtained as described above, an X coordinate reading panel is obtained, and as shown in FIG. 1, the X coordinate reading electrode and the Y coordinate reading electrode are orthogonal to each other. A drawing tablet was assembled by arranging the frame layers through a frame spacer so that the conductive layers face each other.
[0049]
The drawing tablet thus obtained was connected to a constant voltage / constant current power source 8 via an analog switch 7 to assemble an image input device. This image input device was connected to an input position detection device comprising an A / D converter 9 and a CPU 10 and an input position display device having a liquid crystal display screen with 3 dots / mm. At this time, a drawing tablet was placed on the liquid crystal display screen and assembled so that the liquid crystal display screen could be seen from the top of the drawing tablet, thereby configuring an image display system.
[0050]
First, a voltage of 5 V is applied to the drawing tablet, and pressing is performed by pressing the drawing tablet surface with the tip of the input pen when correction is performed so that the input position matches the display position and when correction is not performed. The display displacement between the X coordinate and Y coordinate of the point and the X coordinate and Y coordinate of the displayed liquid crystal display screen, that is, the displacement of the display position with respect to the input position was observed.
Observation method A: The input position and the display position are observed with a magnifying glass.
[0051]
Display deviation: ×
No display misalignment: ○
Observation method B: Visual observation of the input position and the display position from a distance of 50 cm from the panel.
[0052]
Display deviation: ×
No display misalignment: ○
Further, as a time-dependent change test, display deviation was observed by the above-described observation method A after setting the operation state for six months without correcting the test halfway.
[0053]
Display deviation: ×
No display misalignment: ○
The results are shown in Table 1.
Measurement of power consumption In addition, a voltage of 5V is applied to the above-described X coordinate reading panel and Y coordinate reading panel to measure the current flowing between the electrodes, and the power consumption of each panel (including the connection circuit). Was calculated.
[0054]
The results are shown in Table 1.
[0055]
[Example 2]
Panels similar to those in Example 1 were prepared except that the resistance values of the conductive layers of the X coordinate reading panel and the Y coordinate reading panel were 2800Ω, respectively.
[0056]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position shift was observed, the time-change test and the power consumption were measured.
[0057]
The results are shown in Table 1.
[0058]
[Example 3]
Except for the resistance values of the conductive layers of the X coordinate reading panel and Y coordinate reading panel being 400Ω, and the respective electrode resistance values and connection circuit resistance values being those shown in Table 1, each panel was set in the same manner as in Example 1. Created.
[0059]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position shift was observed, the time-change test and the power consumption were measured.
[0060]
The results are shown in Table 1.
[0061]
[Example 4]
Each panel was prepared in the same manner as in Example 1 except that the resistance value, electrode resistance value, and connection circuit resistance value of the conductive layer of the X coordinate reading panel and Y coordinate reading panel were as shown in Table 1.
[0062]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position shift was observed, the time-change test and the power consumption were measured.
[0063]
The results are shown in Table 1.
[0067]
[Comparative Example 2]
Panels similar to those in Example 1 were prepared except that the resistance values of the conductive layers of the X coordinate reading panel and the Y coordinate reading panel were 400Ω.
[0068]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position deviation was observed, the time-change test and the power consumption were measured.
[0069]
The results are shown in Table 1.
[0070]
[Comparative Example 3]
Panels similar to those in Example 1 were prepared except that the resistance values of the conductive layers of the X coordinate reading panel and the Y coordinate reading panel were each 80 Ω.
[0071]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position shift was observed, the time-change test and the power consumption were measured.
[0072]
The results are shown in Table 1.
[0073]
[Comparative Example 4]
A panel similar to that of Example 1 was prepared except that the resistance value of the conductive layer of the X coordinate reading panel was 200Ω and the resistance value of the conductive layer of the Y coordinate reading panel was 800Ω.
[0074]
The correlation coefficient of the linearity of each resistance in these panels was calculated, the drawing tablet was assembled in the same manner as in Example 1, the display position deviation was observed, the time-change test and the power consumption were measured.
[0075]
The results are shown in Table 1.
[0076]
[Table 1]

[Brief description of the drawings]
FIG. 1 is a drawing for explaining a drawing tablet used in an image display system and an image input apparatus according to the present invention.
FIG. 2 is a schematic diagram showing a display shift due to a difference in pressing position of the image input pen.
FIG. 3 shows measurement points of a linearity correlation coefficient.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Drawing tablet 2 ... X coordinate reading panel 3 ... Y coordinate reading panel 4x ... X coordinate conductive layer 4y ... Y coordinate conductive layer 5x1 ... X coordinate reading electrode 5x2 ... X coordinate reading electrode 5y1 ... Y coordinate reading electrode 5y2 ... Y coordinate Read electrode 6x1, 6x2 ... X coordinate read electrode and analog switch connection circuit 6y1, 6y2 ... Y coordinate read electrode and analog switch connection circuit 7 ... Analog switch 8 ... Constant voltage constant current power supply 9 ... A / D converter 10 ... CPU
DESCRIPTION OF SYMBOLS 11 ... Input position detection apparatus 12 ... Input position display apparatus

Claims (1)

In an image display system comprising an image input device, an input position detection device, and an input position display device, the image input device is formed such that a single-sided conductive layer of an insulating substrate and a pair of electrodes are opposed to both ends of the surface of the conductive layer A drawing tablet in which two panels are arranged via a spacer so that the respective conductive layers face each other in parallel, and a constant voltage and / or constant current power source,
(1) A connection circuit for connecting each electrode of the two panels and the constant voltage and / or constant current power source, and the electrode is made of a resin in which metal fine particles are dispersed,
(2) The resistance values between the electrodes in the conductive layers of the two panels are RL x and RL y, and the resistance values of the electrodes of the two panels are RE x and RE y, respectively. An image display system satisfying the following expressions (1), (2), and (3) when the resistance values of the connection circuits of the panels are represented by RC x and RC y, respectively:

(However, RL = RLx + RLy, RE = REx + REy, RC = RCx + RCy, and n is the distance L between the electrodes of the conductive layer as the dot width 1 / Dn of the display screen of the input position display device. The number of divided divisions, that is, n = L / (1 / Dn), where Dn is the number of dots per mm.

Images