201248255 六、發明說明: 【發明所屬之技術領域】 種具 本發明是有關於一種顯示器,且特別是有關於— 有較佳顯示效果的顯示器。 【先前技術】 ^媒體社會的急速進步乡衫惠於半導體元件 不裝置的飛躍性進步。就顯示器而言,具有高書質、^‘p 利用效率佳、低消耗功率、純料優雜性的液晶= If (liquid 〇rystal display ^ LC〇 場之主流。 一般來說,液晶顯示器主要包括一背光模組、—液晶 顯示面板、—上偏光片以及—下偏光片。背光模紐配置^ 液晶顯示面板的下$,用以提供液晶顯示面板所需的背光 源。上偏光片及下偏光片則分別配置於液晶顯示面板的上 表面與下表面,其可調整光的指向性。更具體來說,為了 兼顧液晶顯示器的品質及規格,擴散片、擴散膜等光^膜 片一直是背光模組重要的搭配元件。以擴散片為例,^具 有混光及集光等功能,以使液晶顯示器能夠有良好的^貝^ 品質。因此,背光模組之光源所發出的光在經過擴散片後 會形成亮度均勻的面光源’此面光源再由下偏光片調整成 具有適當指向性的光源’以提供液晶顯示面板進行顯示。 然而,目前市面上液晶顯示器的設計皆僅考慮到擴散 片與方光模組之間的搭配吻合性,意即擴散片是否可使背 4 201248255 光模組提供均勻的面切,但並 示面板之間的搭㈣合性。=片與液晶顯 間的搭配不吻合時,會曰、 κ政片與顯示面板之 :::的現象,降: 【發明内容】 本發明提供—種顯 可讓使用者具有較佳的目視效果y有良好的顯示品質,且 本發明提出-種輪^ s 模組以及一擴散片。續 頜不面板、一背光 一晝素單元具有一μ 板具有多個晝素單元,其中每 方了擴散wm餘配置於顯示面板的下 層’其中擴散層具有多個擴散=模 口的==::;:粒徑的比值大於= 上偏光片配置於顯示面板的-上: 一-;顯不面板相對於上表面的—下表面 上,且位於顯示面板與擴散片之間。 在本發明之一實施例中,上述之擴散片更包括-基材 與-抗靜電層。擴散層與抗靜電層配置於基材的相對兩側 表面上。 本發明還提出-種顯示器,其包括一顯示面板、 光模組、-擴散片、一上偏光片、一下偏光片以及多個霧 201248255 化粒子。顯示面板具有彼此相對的—上表面與一下表面以 及多個晝素單元’其中每-畫素單元具有—開σ。背光模 組配置於I貞*面板的。擴散#配置於顯示面板與背光 模組,間且包括^擴散層’其中擴散層具有多個擴散粒 子。每-晝素單元之開口的大小與擴散粒子的平均粒徑的 比值小於等於3.36。上偏光片g〔置於顯示面板的上表面 上。下偏光片配置於顯示面板的下表面上,且位於顯示面 板,擴散片之間。霧化粒子配置於下偏光片鄰近擴散片的 一表面上,且面對擴散粒子。 在=發明之-實施例中’上述之擴散片更包括一基 靜電層。擴散層與抗靜電層配置於基材的相對兩側 光模ΐ發,更ff—種顯示器,其包括-顯示面板、-背 化粒子/廣散、—上偏光片、—下偏光片以及多個霧 =晝;:面板ίΓί此相對的-上表面與-下表 組配置二員板::一畫素單元具有-開口。背光模 模組之間擴^配置於顯示面板與背光 子。每—書音輩元、"9,,、中擴散層具有多個擴散粒 比值大於i於3.36。=的^小與擴散粒子的平均粒徑的 上。下偏* Η “1片配置於顯示面板的上表面 板與擴散片之間。霧化=片,於顯示面 的一表面上。 ;上偏光片达離顯示面板 本1月之»;^例中,上述之擴散片更包括一基材 6 201248255 靜電層。擴散層與抗靜電層配置於基材的相對兩側 本發明另提出-種顯示器,其包括一顯示面板、一背 光模組以及多鶴化粒子。顯示面板包括—絲元件陣列 基^彩色絲基板以及-顯示介質層。彩色滤光基板 配置於主動元件陣列基板的對向,且包括—基材以及多個 配置於基材上的彩色渡光圖案。顯示介質層配置於主動元 ,陣列基板與純縣基板之間。f光模組配置於顯示面 板的下方。霧化粒子配置於彩色滤光圖針,其中每一霧 化粒子的折射率大於每—彩Μ光圖案的折射率。 ^本發日狀—實施财,上述之彩色航基板更包括 ’目、陣圖案’而黑矩陣圖案配置於基材上,且黑矩陣圖 I、有多個開口’彩色濾光圖案位於開口中。 j本發明之—實施例中’上述之顯示器更包括一擴散 盘北止上偏光片以及—下偏光片。擴散片配置於顯示面板 V:光模組之間。上偏光片配置於顯示面板的-上表面 下偏光片配置於顯示面板相對於上表面的一下表面 且位於顯示面板與擴散片之間。 本發明,提出—種顯示器,其包括—顯示面板、一背 且ΐίί夕個霧化粒子。顯示面板包括-主動元件陣列 i於主光基板以及顯示介f層。彩色遽光基板配 二7L陣列基板的對向,且包括一芙材、一黑矩陣 圖案以及多個彩色满朵圖安 土 圖宰配置;其中黑矩陣圖案與彩色遽光 置於基材上,黑矩陣圖案具有多個開Π,且彩色滤 201248255 光圖/案位於開口中。顯示介質層配置於主動元件陣列基板 ,彩色濾光基板之間。背光模組配置於顯示面板的下方。 霧化粒子配置於彩色濾光基板的基材上,且位於基材與黑 矩陣圖案之間以及基材與彩色滤細案之間,i 子的分布於基材上定義I凸表面或—凹表面。' 在本發明之一實施例中,上述之每一霧化粒子的折射 率大於每一彩色濾光圖案的折射率。 基於上述,在本發明之顯示器的設計中,主要是透過 調整每一晝素單元之開口的大小與擴散層中這些擴散粒子 的平均粒徑的比值,來使顯示器具有較佳的顯示品質,意 即顯示面板與擴散片之間具有較佳的搭配吻合性,進而當 使用者觀賞本發明之顯示n時’可具有較佳的目視效果。 為讓本發明之上述特徵和優點能更明顯易懂,下文特 舉實施例’並配合所附圖式作詳細說明如下。 【實施方式】 圖1為本發明之一實施例之一種顯示器的剖面示意 圖。請參考圖1,在本實施例中,顯示器100a包括一顯示 面板110a、一背光模組120以及一擴散片13〇。詳細來說, 顯示面板110a是由一主動元件陣列基板115、一對向基板 117以及一顯示介質層119所組成,其中主動元件陣^基 板115具有一顯示區113a、一環繞顯示區n3a的非顯示 區U3b以及多個晝素單元115a,而每一晝素單元115a具 有一開口 116,且此開口 116位於顯示區U3a内。此外, 8 201248255 顯示面板110a具有彼此相對的一上表面iua與一下表面 111b。對向基板117例如是一彩色濾光基板,而顯示介質 層119例如是一液晶層,但在此並不以此為限。 彦光模組120配置於顯示面板11 〇a的下方,其中背 光模組120是由至少一光源122與一導光板124所組成, 且背光模組120例如是—側邊入光式背光模組,但在此並 不以此為限。 擴散片130配置於顯示面板與背光模組120之 間,其中擴散片130包括一基材132、一擴散層丨34以及 一抗靜電層130。具體來說,擴散層134與抗靜電層136 配置於基材132的相對兩側表面上,且擴散層134具有多 個擴散粒子134a。特別是,在本實施例中,每一晝素單元 115&之開口116的大小與擴散層134之這些擴散粒子13如 的平均粒徑的比值大於等於2。 此外,為了增加提升顯示器1〇〇a的顯示品質,本實 轭例之顯示器l〇〇a可更包括一上偏光片14〇a以及一下偏 光片150a,以增加濾光的效果,並減少串音(cr〇sstalk) 現象的發生。其中,上偏光片14〇a配置於顯示面板u〇a 的上表面Ilia上,而下偏光片15〇a配置於顯示面板n〇a 的下表面111b上,且下偏光板15〇a位於顯示面板110a 與擴散片130之間。再者,除了擴散片13〇之外,亦可增 設其他的光學膜片Π1、172、173於顯示面板u〇a與背光 模組120之間。一般而言’光學膜片171、172、173可以 包括稜鏡片、集光片、增光片、保護片或上述之光學膜片 201248255 的組合,以進一步優化出光效果。在此,對於光學膜片 171、172、173的種類及其數量可依據不同的使用需求而 作調整,並不對其進行限定。 在本實施例之顯示器100a的設計中,除了可透過擴 散片130來改善背光模組120所提供之面光源的分布以 使出光較為均勻外’亦透過調整每一晝素單元U5a之開口 116的大小與擴散層134中這些擴散粒子13牝的平均板和 的比值,例如是大於等於2’來使得顯示器1〇〇a整體具^ 較佳的顯示品質’意即顯示面板ll〇a與擴散片13〇之間具 有較佳的搭配吻合性,進而當使用者觀賞本實施例之顯; 器100a時’可具有較佳的目視效果。 ’ “ 以下將利用四個不同之實施例來分別說明顯示器 100b、100c、100d、l〇〇e的設計。在此必須說明的是,; 述實施例沿用前述實施例的元件標號與部分内容,其中採 用相同的標號來表示相同或近似的元件,並且省略了相同 技術内容的說明。關於省略部分的說明可參考前述實施 例,下述實施例不再重複贅述。 圖2A為本發明之一實施例之一種顯示器的剖面示意 圖。圖2B為圖2A之擴散片、下偏光板及霧化粒子的放大 剖面示意圖。請同時參考圖2A與圖2B,本實施例之顯示 器100b與圖1之顯示器i00a相似,差異之處在於:本實 施例之顯示器l〇〇b更包括多個霧化粒子160b,其中這些 霧化粒子160b配置於下偏光片15〇b鄰近擴散片13〇的一 表面152上,且這些霧化粒子16〇b面對這些擴散粒子 201248255 134a。特別是,在本實施例中,每一晝素單元U5a之開口 116的大小與這些擴散粒子13如的平均粒徑的比值小於 於 3.36。 ' 在本實施例中,這些霧化粒子160b配置於下偏光片 150b的表面152上,因此背光模組12〇所發出的光線[從 擴散片130進入至下偏光片15〇b時,一部分的光線以因 丈這些務化粒子160b的影響,產生反射而又回到擴散片 130,而另一部分的光線L2則直接通過下偏光片150b而 進入顯示面板110a中。如此一來,由背光模組12〇所提供 的光線能均勻地分散’以使得顯示器1〇〇b整體具有較佳的 顯示品質。再者,由於本實施例採用每一畫素單元ιΐ5& 之開口 116的大小與這些擴散粒子丨3 4 a的平均粒徑的比值 小於等於3.36之設計’因此本實施例之顯示面板㈣與 擴散片130之間具有較佳的搭配吻合性,進而當使用者觀 賞本實施例之顯示器l〇0b時,可具有較佳的目視效果。 圖3A為本發明之又一實施例之一麵示器的剖面示 意圖。圖3B為圖3A之擴散片、上偏光板及霧化粒子的放 大剖面示意圖。請同時參考圖3A與圖3B,本實施例之顯 示器1〇〇C與圖1之顯示器⑽a相似,差異之處在於:本 實施例之顯不H lGGe更包括多個霧化粒子16Qe,其中這 些霧化粒子廳配置於上偏光片丨输遠離顯示面板u〇a 的一表面142上。特別是,在本實施例中,每一晝素單元 115a之開口 116的大小與這些擴散粒子134&的平均粒徑 的比值大於等於3.36。 201248255 在本實施例中,這些霧化粒子160c配置於上偏光片 140c的表面142上’因此背光模組12〇所發出的光線l從 擴散片130進入至上偏光片i40c時,光線L除了會受到 這些擴散粒子134a的影響而產生擴散效應之外,也會受到 上偏光板140c上之這些霧化粒子160c的影響而於這些霧 化粒子160c的表面上產生散射效應,而有部分光線L可 直接穿射而進入顯不面板11 〇a中。如此*—來,由背光模組 120所提供的光線能均勻地分散,以使得顯示器1〇〇c整體 具有較佳的顯示品質。再者’由於本實施例採用每一晝素 單元115a之開口 116的大小與這些擴散粒子134a的平均 粒徑的比值大於等於3.36之設計,因此本實施例之顯示面 板110a與擴散片130之間具有較佳的搭配吻合性,進而當 使用者觀賞本實施例之顯示器100c時,可具有較佳的目視 效果。 圖4A為本發明之又一實施例之一種顯示器的剖面示 思圖。圖4B為圖4A之洛色遽光基板的局部放大剖面示音 圖。請同時參考圖4A與圖4B,本實施例之顯示器1〇〇d 與圖1之顯示器l〇〇a相似’差異之處在於:本實施例之顯 不100d具有多個霧化粒子160d。詳細來說,本實施例 之彩色滤光基板117’包括一基材117a’、多個彩色淚光圖 案117b以及一黑矩陣圖案117c,其中這些彩色渡光圖案 117b與黑矩陣圖案117c配置於基材117a,上,而黑矩陣圖 案U7c具有多個開口 117d,且這些彩色濾光圖案丨丨几位 於這些開口 117d中。特別是,這些霧化粒子160d配置於 12 201248255 追些彩色濾光圖案117b中,且每一霧化粒子16〇d的折射 率大於每一彩色濾光圖案117b的折射率。 在本實施例中,由於這些霧化粒子16〇d配置於這些 彩,濾光圖案117b中,且每一霧化粒子16〇d的折射率二 於每一彩色濾光圖案117b的折射率。因此,當背光模組 120所提供的光線通過這些彩色濾光圖案ll7b時,光線會 又到這些霧化粒子160d的影響而在這些霧化粒子16如的 表面上產生散射效應,進而可提昇顯示器1〇〇d整體的顯示 品質。再者,當使用者觀賞本實施例之顯示器1〇〇(1時,亦 可具有較佳的目視效果。 九圖5A為本發明之又一實施例之一種顯示器的剖面示 思圖。圖5B為圖5A之一實施例之一種彩色濾光基板的局 部放大剖面示意圖。圖5C為圖5A之另一實施例之一種彩 色濾光基板的局部放大剖面示意圖。請同時參考圖5A、圖 5B及5C,本實施例之顯示器1〇〇e與圖i之顯示器i〇〇a 相似,差異之處在於:本實施例之顯示器1〇〇e具有多個霧 化粒子160e。詳細來說,本實施例之彩色濾光基板117,, 包括一基材117a,,、多個彩色濾光圖案U7b以及一黑矩陣 圖案117c,其中這些彩色濾光圖案117b與黑矩陣圖案U7c 配置於基材117a’’上,而黑矩陣圖案117c具有多個開口 117d,且這些彩色濾光圖案117b位於這些開口 U7d中。 於此’這些霧化粒子16〇e配置於基材ii7a,,上,且位於基 材117a與黑矩陣圖案117c以及基材117a’’與這些彩色濟 光圖案117b之間,其中每一霧化粒子i6〇e的折射率大於 13 201248255 每一彩色濾光圖案117b的折射率。特別是,這些霧化粒子 160e的分布於基材117a,上定義出一突出於基材U7a,,的 凸表面118a (或一配置於基材117a,,内的凹表面U8b)。 由於這些霧化粒子160e配置於彩色濾光基板117,,的 基材117a’’上,且每一霧化粒子16〇e的折射率大於每—彩 色濾光圖案117b的折射率。因此,當背光模組12〇所提供 的光線通過彩色濾光基板117,,的基材U7a”時,光線會受 到這些霧化粒子16〇e所構成之凸表面U8a (或凹表面 118b)的影響而於這些霧化粒子廳的表面上產生散射效 應,進而可提昇顯示器l00e整體的顯示品質。再者,當使 用者觀賞本實施例之齡器職時,亦可具有較佳的= 效果。 亦工π逖,隹本發明之顯示器的設計中,主 調整每—晝素單元之開口的大小與擴散層中這些擴散粒子 的平均粒徑的比值及搭崎絲子,來使顯㈣具有較佳 品質’意即顯示面板與擴散片之間具有較佳的搭配 H進W❹者觀f本發明之顯示器時,可具 佳的目視縣。再者,砂透過增設霧錄子於 2光片、彩色η基板的彩色濾光圖案 可增加光_散紐果,啸高顯示= 雖然本發明已以實施例揭露如上,然 本發明,任何所屬技術領域中具有通常知識者,在脫二 本發明之精神和範_,當可作些許之__飾,g 201248255 發明之保護範圍當視後附之申請專利範圍所界定者為準。 【圖式簡單說明】 圖1為本發明之一實施例之一種顯示器的剖面示意 圖。 圖2A為本發明之另一實施例之一種顯示器的剖面示 意圖。 圖2B為圖2A之擴散片、下偏光板及霧化粒子的放大 刮面示意圖。 圖3A為本發明之又一實施例之一種顯示器的剖面示 意圖。 圖3B為圖3A之擴散片、上偏光板及霧化粒子的放大 剖面示意圖。 圖4A為本發明之又一實施例之一種顯示器的剖面示 意圖。 圖4B為圖4A之彩色濾光基板的局部放大剖面示意 圖。 圖5A為本發明之又一實施例之一種顯示器的剖面示 意圖。 圖5B為圖5A之一實施例之一種彩色濾光基板的局部 放大剖面示意圖。 圖5C為圖5A之另一實施例之一種彩色濾光基板的局 部放大剖面示意圖。 15 201248255 【主要元件符號說明】 100a、100b、100c、100d、100e :顯示器 110a、llOd、llOe :顯示面板 111a :上表面 111b :下表面 113a :顯示區 113b :非顯示區 115 :主動元件陣列基板 115a :晝素單元 116 :開口 117 :對向基板 117’、117’’ :彩色濾光基板 117a’、117a’’ :基材 117b :彩色濾光圖案 117c :黑矩陣圖案 117d :開口 118a ··凸表面 118b :凹表面 119 :顯示介質層 120 :背光模組 122 :光源 124 :導光板 130 :擴散片 132 :基板 16 201248255 134 :擴散層 134a :擴散粒子 136 :抗靜電層 140a、140c :上偏光片 142 :表面 150a、150b :下偏光片 152 :表面 160b、160c、160d、160e :霧化粒子 171、172、173 :光學膜片 L、LI、L2 :光線 17201248255 VI. Description of the Invention: [Technical Field of the Invention] The present invention relates to a display, and more particularly to a display having a better display effect. [Prior Art] ^ The rapid advancement of the media society has benefited from the dramatic advancement of semiconductor components. As far as the display is concerned, the liquid crystal with high book quality, good utilization efficiency, low power consumption, and pure material compatibility is the mainstream of If (liquid 〇rystal display ^ LC market. In general, liquid crystal displays mainly include A backlight module, a liquid crystal display panel, an upper polarizer, and a lower polarizer. A backlight module configuration ^ The lower display of the liquid crystal display panel is used to provide a backlight required for the liquid crystal display panel. The upper polarizer and the lower polarizer The sheets are respectively disposed on the upper surface and the lower surface of the liquid crystal display panel, which can adjust the directivity of the light. More specifically, in order to balance the quality and specifications of the liquid crystal display, the diffusion film, the diffusion film, and the like are always backlit. The important matching components of the module. Take the diffuser as an example, and have the functions of mixing and collecting light, so that the liquid crystal display can have good quality. Therefore, the light emitted by the light source of the backlight module is diffused. After the film, a surface light source with uniform brightness will be formed. This surface light source is then adjusted by a lower polarizer into a light source with appropriate directivity to provide a liquid crystal display panel for display. However, the current market The design of the upper liquid crystal display only considers the matching between the diffuser and the square light module, which means that the diffuser can provide a uniform face cut for the back 4 201248255 optical module, but the display between the panels (four) If the combination of the film and the liquid crystal display does not match, the phenomenon of the :, κ political film and the display panel:::, the drop: [Invention] The present invention provides a display that allows the user to have better The visual effect y has good display quality, and the present invention proposes a seed wheel s module and a diffusion sheet. The continuation jaw non-panel, a backlight and a halogen unit have a μ plate and a plurality of halogen elements, wherein each The diffusion wm is disposed in the lower layer of the display panel, wherein the diffusion layer has a plurality of diffusion = die ==::;: the ratio of the particle diameter is greater than = the upper polarizer is disposed on the display panel - one -; The panel is located on the lower surface of the upper surface and is located between the display panel and the diffusion sheet. In one embodiment of the invention, the diffusion sheet further comprises a substrate and an antistatic layer. The diffusion layer and the antistatic layer Layers are placed on opposite sides of the substrate The present invention also provides a display comprising a display panel, a light module, a diffusion sheet, an upper polarizer, a lower polarizer, and a plurality of fog 201248255 particles. The display panels have opposite surfaces to each other. The surface and the plurality of pixel units each of which has an -open σ. The backlight module is disposed on the I 贞 * panel. The diffusion # is disposed between the display panel and the backlight module, and includes a diffusion layer The diffusion layer has a plurality of diffusion particles, and the ratio of the size of the opening of each of the halogen units to the average particle diameter of the diffusion particles is 3.36 or less. The upper polarizer g is placed on the upper surface of the display panel. The lower polarizer is disposed on the display. The lower surface of the panel is located between the display panel and the diffusion sheet. The atomized particles are disposed on a surface of the lower polarizer adjacent to the diffusion sheet and face the diffusion particles. In the invention - the embodiment, the diffusion sheet described above further comprises a base electrostatic layer. The diffusion layer and the antistatic layer are disposed on opposite sides of the substrate, and the display device comprises a display panel, a backing particle/a wide dispersion, an upper polarizer, a lower polarizer, and a plurality of displays. Fog=昼;: Panel ίΓί This relative-upper surface and - the following table group configures the two-member board:: One pixel unit has - opening. The backlight modules are expanded between the display panel and the backlight. Each of the book sounds, the "9,,, the middle diffusion layer has a plurality of diffusion particles ratio greater than i at 3.36. = ^ is small with the average particle size of the diffusing particles. Lower bias* Η “1 piece is placed between the upper surface plate of the display panel and the diffusion sheet. Atomization = sheet on one surface of the display surface. The upper polarizer is off the display panel of this month of the month»; The diffusion sheet further includes a substrate 6 201248255 electrostatic layer. The diffusion layer and the antistatic layer are disposed on opposite sides of the substrate. The present invention further provides a display including a display panel, a backlight module, and a plurality of The display panel comprises a silk element array substrate, a color silk substrate and a display medium layer. The color filter substrate is disposed on the active device array substrate, and includes a substrate and a plurality of substrates disposed on the substrate. a color light-emitting pattern, the display medium layer is disposed between the active element, the array substrate and the pure county substrate, and the f-light module is disposed under the display panel. The atomized particles are disposed on the color filter needle, wherein each atomized particle The refractive index is greater than the refractive index of each of the color light patterns. The present invention has a color matrix substrate including a 'mesh, array pattern' and a black matrix pattern disposed on the substrate, and a black matrix pattern. I, have The opening color filter pattern is located in the opening. In the embodiment of the present invention, the display device further includes a diffusion disk north stop upper polarizer and a lower polarizer. The diffusion sheet is disposed on the display panel V: the light module The upper polarizer is disposed on the upper surface of the display panel. The polarizer is disposed on the lower surface of the display panel relative to the upper surface and is located between the display panel and the diffusion sheet. The present invention provides a display including - display The display panel comprises an active element array i on the main light substrate and the display layer f. The color light-emitting substrate is matched with the two 7L array substrates, and includes a material, a The black matrix pattern and the plurality of color full maps are disposed on the substrate; the black matrix pattern and the colored phosphor are placed on the substrate, the black matrix pattern has a plurality of openings, and the color filter 201248255 light pattern/case is located in the opening. The display medium layer is disposed between the active device array substrate and the color filter substrate. The backlight module is disposed under the display panel. The atomized particles are disposed on the substrate of the color filter substrate. Above, and between the substrate and the black matrix pattern and between the substrate and the color filter, the distribution of i is defined on the substrate as a convex surface or a concave surface. In an embodiment of the invention, The refractive index of each of the atomized particles is greater than the refractive index of each color filter pattern. Based on the above, in the design of the display of the present invention, mainly by adjusting the size of the opening of each element and the diffusion layer The ratio of the average particle diameter of the diffusing particles is such that the display has better display quality, that is, the display panel and the diffuser have better matching, and when the user views the display n of the present invention, In order to make the above-mentioned features and advantages of the present invention more comprehensible, the following detailed description of the embodiments will be described in detail below with reference to the accompanying drawings. A schematic cross-sectional view of a display of an embodiment. Referring to FIG. 1, in the embodiment, the display 100a includes a display panel 110a, a backlight module 120, and a diffusion sheet 13A. In detail, the display panel 110a is composed of an active device array substrate 115, a pair of substrates 117, and a display medium layer 119. The active device array 115 has a display area 113a and a non-display area n3a. The display area U3b and the plurality of pixel units 115a, and each of the pixel units 115a has an opening 116, and the opening 116 is located in the display area U3a. Further, 8 201248255 display panel 110a has an upper surface iiu and a lower surface 111b opposed to each other. The opposite substrate 117 is, for example, a color filter substrate, and the display medium layer 119 is, for example, a liquid crystal layer, but is not limited thereto. The light module 120 is disposed under the display panel 11 〇a, wherein the backlight module 120 is composed of at least one light source 122 and a light guide plate 124, and the backlight module 120 is, for example, a side-lighting backlight module. , but not limited to this. The diffusion sheet 130 is disposed between the display panel and the backlight module 120. The diffusion sheet 130 includes a substrate 132, a diffusion layer 34, and an antistatic layer 130. Specifically, the diffusion layer 134 and the antistatic layer 136 are disposed on opposite side surfaces of the substrate 132, and the diffusion layer 134 has a plurality of diffusion particles 134a. In particular, in the present embodiment, the ratio of the size of the opening 116 of each of the halogen units 115 & and the average particle diameter of the diffusion particles 13 of the diffusion layer 134 is greater than or equal to two. In addition, in order to increase the display quality of the display 1a, the display 10a of the yoke example may further include an upper polarizer 14a and a lower polarizer 150a to increase the filtering effect and reduce the string. The occurrence of a (cr〇sstalk) phenomenon. The upper polarizer 14〇a is disposed on the upper surface Ilia of the display panel u〇a, and the lower polarizer 15〇a is disposed on the lower surface 111b of the display panel n〇a, and the lower polarizer 15〇a is located on the display. Between the panel 110a and the diffusion sheet 130. Further, in addition to the diffusion sheet 13, other optical films Π 1, 172, and 173 may be added between the display panel u 〇 a and the backlight module 120. In general, the optical film 171, 172, 173 may comprise a combination of a gusset, a light concentrating sheet, a brightness enhancing sheet, a protective sheet or the optical film 201248255 described above to further optimize the light output. Here, the types and the number of the optical films 171, 172, and 173 can be adjusted according to different use requirements, and are not limited thereto. In the design of the display 100a of the present embodiment, in addition to the diffusion sheet 130, the distribution of the surface light source provided by the backlight module 120 can be improved to make the light output more uniform. The transmission 116 of each of the element units U5a is also adjusted. The ratio of the average plate sum of the size of the diffusion particles 13牝 in the diffusion layer 134 is, for example, 2' or more to make the display 1〇〇a have a better display quality, that is, the display panel 11〇a and the diffusion sheet. 13 具有 has better matching and matching, and when the user views the display 100a, the user can have better visual effects. 'The design of the displays 100b, 100c, 100d, l〇〇e will be described separately using four different embodiments. It must be noted here that the embodiments follow the component numbers and parts of the foregoing embodiments, The same reference numerals are used to designate the same or similar elements, and the description of the same technical content is omitted. The description of the omitted parts can be referred to the foregoing embodiments, and the following embodiments will not be repeated. FIG. 2A is an implementation of the present invention. 2B is a schematic cross-sectional view of a diffuser, a lower polarizer, and an atomized particle of FIG. 2A. Referring to FIG. 2A and FIG. 2B, the display 100b of the present embodiment and the display i00a of FIG. Similarly, the difference is that the display 10b of the embodiment further includes a plurality of atomized particles 160b, wherein the atomized particles 160b are disposed on a surface 152 of the lower polarizer 15〇b adjacent to the diffusion sheet 13〇, And these atomized particles 16〇b face these diffusion particles 201248255 134a. In particular, in the present embodiment, the size of the opening 116 of each of the pixel units U5a is the same as these The ratio of the average particle diameter of the scattered particles 13 is less than 3.36. In the present embodiment, the atomized particles 160b are disposed on the surface 152 of the lower polarizer 150b, so that the light emitted by the backlight module 12 is diffused [from diffusion When the sheet 130 enters the lower polarizer 15〇b, a part of the light is reflected by the chemical particles 160b and returned to the diffusion sheet 130, and the other portion of the light L2 passes directly through the lower polarizer 150b. The display panel 110a is entered into the display panel 110a. Thus, the light provided by the backlight module 12A can be uniformly dispersed to make the display 1b overall have better display quality. Furthermore, since this embodiment adopts each The ratio of the size of the opening 116 of the pixel unit ιΐ5& to the average particle diameter of the diffusing particles 丨34 4 a is less than or equal to the design of 3.36. Therefore, the display panel (4) of the present embodiment has a better match with the diffusion sheet 130. And the user can have a better visual effect when viewing the display 100b of the embodiment. Fig. 3A is a schematic cross-sectional view of the surface display device according to still another embodiment of the present invention. 3A and 3B, the display 1〇〇C of the present embodiment is similar to the display (10)a of FIG. 1 , the difference is: The embodiment of the present invention further includes a plurality of atomized particles 16Qe, wherein the atomized particle chambers are disposed on a surface 142 of the upper polarizer that is away from the display panel u〇a. In particular, in this embodiment, The ratio of the size of the opening 116 of each of the halogen units 115a to the average particle diameter of the diffusion particles 134& is greater than or equal to 3.36. 201248255 In the present embodiment, these atomized particles 160c are disposed on the surface 142 of the upper polarizer 140c' Therefore, when the light 1 emitted from the backlight module 12 is passed from the diffusion sheet 130 to the upper polarizer i40c, the light L is affected by the diffusion particles 134a to cause a diffusion effect, and is also subjected to the upper polarizing plate 140c. The effect of the atomized particles 160c produces a scattering effect on the surface of these atomized particles 160c, and part of the light L can directly penetrate into the display panel 11a. Thus, the light provided by the backlight module 120 can be evenly dispersed, so that the display 1 〇〇c as a whole has better display quality. Further, since the ratio of the size of the opening 116 of each of the halogen units 115a to the average particle diameter of the diffusion particles 134a is 3.36 or more, the present embodiment is between the display panel 110a and the diffusion sheet 130. The user has a better matching effect, and when the user views the display 100c of the embodiment, the user can have a better visual effect. 4A is a cross-sectional view of a display according to still another embodiment of the present invention. Fig. 4B is a partially enlarged cross-sectional view showing the Luo light-emitting substrate of Fig. 4A. Referring to FIG. 4A and FIG. 4B simultaneously, the display 1〇〇d of the present embodiment is similar to the display 10a of FIG. 1 in that the display 100b of the present embodiment has a plurality of atomized particles 160d. In detail, the color filter substrate 117' of the present embodiment includes a substrate 117a', a plurality of colored tear patterns 117b, and a black matrix pattern 117c, wherein the color light pattern 117b and the black matrix pattern 117c are disposed on the base The material 117a is upper, and the black matrix pattern U7c has a plurality of openings 117d, and these color filter patterns are located in the openings 117d. In particular, the atomized particles 160d are disposed in the color filter patterns 117b of 12 201248255, and the refractive index of each of the atomized particles 16〇d is greater than the refractive index of each of the color filter patterns 117b. In the present embodiment, since the atomized particles 16〇d are disposed in the color, the filter pattern 117b, and the refractive index of each of the atomized particles 16〇d is equal to the refractive index of each of the color filter patterns 117b. Therefore, when the light provided by the backlight module 120 passes through the color filter patterns 11bb, the light will be affected by the atomized particles 160d to generate a scattering effect on the surface of the atomized particles 16, for example, thereby improving the display. 1〇〇d overall display quality. Furthermore, when the user views the display 1 of the present embodiment (1, it may also have a better visual effect. FIG. 5A is a cross-sectional view of a display according to still another embodiment of the present invention. FIG. 5B FIG. 5C is a partially enlarged cross-sectional view showing a color filter substrate according to another embodiment of FIG. 5A. Please refer to FIG. 5A and FIG. 5B simultaneously. 5C, the display 1〇〇e of the present embodiment is similar to the display i〇〇a of FIG. i, the difference is that the display 1〇〇e of the embodiment has a plurality of atomized particles 160e. In detail, the implementation The color filter substrate 117 includes a substrate 117a, a plurality of color filter patterns U7b, and a black matrix pattern 117c, wherein the color filter patterns 117b and the black matrix pattern U7c are disposed on the substrate 117a'' The black matrix pattern 117c has a plurality of openings 117d, and the color filter patterns 117b are located in the openings U7d. Here, the atomized particles 16〇e are disposed on the substrate ii7a, and are located on the substrate 117a. With black matrix pattern 117c And a refractive index between each of the substrate 117a'' and the color luster pattern 117b, wherein each of the atomized particles i6〇e has a refractive index greater than 13 201248255. The refractive index of each of the color filter patterns 117b. In particular, the atomized particles 160e Disposed on the substrate 117a, a convex surface 118a (or a concave surface U8b disposed in the substrate 117a) protruding from the substrate U7a is defined. Since the atomized particles 160e are disposed in the color filter On the substrate 117a'' of the substrate 117, and the refractive index of each of the atomized particles 16〇e is larger than the refractive index of each of the color filter patterns 117b. Therefore, when the light provided by the backlight module 12〇 passes through the color When the substrate U7a" of the substrate 117, is filtered, the light is affected by the convex surface U8a (or the concave surface 118b) composed of the atomized particles 16〇e, and a scattering effect is generated on the surface of the atomized particle chamber. Further, the display quality of the display l00e can be improved. Further, when the user views the age of the embodiment, the user can also have a better effect. In addition, in the design of the display of the present invention, Main adjustment per-halogen unit The ratio of the size of the opening to the average particle size of the diffusing particles in the diffusion layer and the sifting of the particles to make the display (4) have a better quality' means that the display panel and the diffusion sheet have a better match. f When the display of the present invention is used, it can have a good visual county. Furthermore, the sand can increase the light-scattering effect by adding a haze recording to the color filter pattern of the 2-light film and the color η substrate, and the smear display = although this The invention has been disclosed in the above embodiments, but the present invention, any one of ordinary skill in the art, is in the spirit and scope of the invention, and can be used as a __ decoration, the protection scope of the invention of 201224255 The scope defined in the patent application is subject to change. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic cross-sectional view showing a display according to an embodiment of the present invention. 2A is a cross-sectional view of a display in accordance with another embodiment of the present invention. Fig. 2B is a schematic enlarged plan view showing the diffusion sheet, the lower polarizing plate and the atomized particles of Fig. 2A. Fig. 3A is a cross-sectional view showing a display of still another embodiment of the present invention. Fig. 3B is an enlarged cross-sectional view showing the diffusion sheet, the upper polarizing plate, and the atomized particles of Fig. 3A. 4A is a cross-sectional view of a display according to still another embodiment of the present invention. Fig. 4B is a partially enlarged cross-sectional schematic view of the color filter substrate of Fig. 4A. Figure 5A is a cross-sectional view of a display in accordance with still another embodiment of the present invention. Figure 5B is a partially enlarged cross-sectional view showing a color filter substrate of an embodiment of Figure 5A. Figure 5C is a partially enlarged cross-sectional view showing a color filter substrate of another embodiment of Figure 5A. 15 201248255 [Description of main component symbols] 100a, 100b, 100c, 100d, 100e: display 110a, 110d, 110e: display panel 111a: upper surface 111b: lower surface 113a: display area 113b: non-display area 115: active device array substrate 115a: halogen unit 116: opening 117: opposite substrate 117', 117'': color filter substrate 117a', 117a'': substrate 117b: color filter pattern 117c: black matrix pattern 117d: opening 118a ·· Convex surface 118b: concave surface 119: display medium layer 120: backlight module 122: light source 124: light guide plate 130: diffusion sheet 132: substrate 16 201248255 134: diffusion layer 134a: diffusion particles 136: antistatic layer 140a, 140c: upper Polarizer 142: surface 150a, 150b: lower polarizer 152: surface 160b, 160c, 160d, 160e: atomized particles 171, 172, 173: optical film L, LI, L2: light 17