九、發明說明· 【發:所屬之技術績域】 ^本發明係有關〜種丘古々 一 鬲解析轉換至低 ^予式晝素顯示方法,係一種針對 驅動1C的需求個^之影像顯示技術,用以減少顯示器對 【先前技術】 視覺是不同波具 的感覺線作用於視賴而在人腦引起 的檢測具有重m統的基本機能’對於圖像和物體 真 w義。人眼可見光線的波長是390〜78〇 毫试米(nm ), —私可摊山a , 叙可辨出包括紫、藍、青、綠、黃、撥、 、、工:種主要顏色在内的120〜180種不同的顏色。辨色主 要是視覺細胞的功能,因視覺細胞集巾分佈在視網膜中心 I5故該處辨色此力最強,越向周邊部,視網膜對綠、紅、 黃、藍4種顏色的感受力依次消失。 又由物理學可知,用紅、綠、藍3種色光作適當混合, 可產生白光以及光譜上的任何顏色。關於色覺的理論,目 前多用“三原色學說”來解釋。這個學說認為,在視網膜 上存在著分別對紅、綠和藍三種光線的波長特別敏感的三 種視錐細胞或相應的感光色素,當不同波長的光線入眼 時,可引起敏感波長與之相符或相近的視覺細胞發生不同 程度的興奮,於是在大腦產生相應的色覺;三種視覺細胞 若受到同等程度的刺激,則產生白色色覺。 目前平面板顯示器,例如液晶顯示器(LCD)係用於顯 示電腦及其他類比與數位資料,其包含由晝素構成的細 1252465 1以某種樣式點亮來形成影像(字母、數字、祕及其它 圖形)。 該細胞為最小的物理單元來構成―顯示單元,針對目 :4示器之子畫素排列為線條紋狀(Stdpe)(如「第!圖」 色^。線條紋狀(如第!圖)配列是分別代表紅色、綠 现色之子晝素r、g、b成線條紋狀配列。又驅動π為 1C曰二貝不器之基礎零件之—,佔LCD成本比重極高。驅動 、主要功能是輸出需要的電壓至畫素,用以控制液晶分 于的扭轉程度。 p的;LCD需要用到彩色濾光片(c〇i〇r fi CF ), 、士由控制1C的訊號處理,佶俨p北、μ、々 利用彩色縣片的處理,表現Υ ㈣Μ ’可 之製作是於玻璃基板上,:二,彩色濾光片 製作左兑,_ 竹、·工綠、藍三原色之有機材料, 作在母一個子晝素r、g、b之内。 排列:mr圖」中所示之目前常見之彩色遽光片 解析影像,高;产=排列為線條紋狀(stripe)之高 言,如顯示二,的閘極驅㈣而 則每-原晝素τ。之每 一個訊號通道(ehannel) ^ g、b各$要驅動 動1c而言,驅動IC需使用到有_個訊號腳的驅 或文字之小尺核晶齡而言:;=對㈣錢示圖形 之驅動1C’每一顯示器都 、LCD成本比重極高 此夕顆之驅動1C,導致生 1252465 產者之成本壓力將會極高,亦同時造成驅動ic供需的互 相排擠,當需求越多,該驅動1C之單位成本將會越高。 【發明内容】 爰是,本發明之主要目的係在利用人眼色覺的視覺誤 差,減少影像晝素之使用率,在降低少許解析度之情況 下,減少驅動1C之個數,降低液晶顯示的驅動1C成本及 對驅動1C的需求數量。 本發明係一種共享式晝素顯示方法,係驅動1C先對 原晝素之子晝素(r、g、b)取樣,該子晝素取樣係搭配彩色 濾光片之晝素(R、G、B)排列,判斷取樣後相鄰晝素内含 差值,再由相鄰之同色晝素做權重比例的再分配,然後驅 動1C再將經過取樣與權重比例再分配晝素(R、G、B)訊號 到搭配之彩色渡光片顯示。如是,藉由取樣與方式權重比 例再分配,可導致顯示區之晝素(R、G、B)對訊號通道需 求的減少,利用人眼色覺的視覺誤差,減少不必要的影像 晝素,減少驅動1C之個數,降低液晶顯示的驅動1C成本 與對驅動1C的需求數量。 【實施方式】 茲有關本發明之詳細内容及技術說明,現配合圖式說 明如下: 請先參閱「第2圖」所示,係本發明之共享式晝素顯 示方法方塊圖。如圖所示,該方法主要為: (a)係對排列為線條紋狀的原始高解析影像之原晝素 10 (如「第1圖」所示)。 7 1252465Nine, invention description · [fam: the technical domain of the domain] ^ The invention relates to the method of analyzing the conversion of the 丘 々 々 至 至 至 至 至 至 至 至 至 予 予 , , , , , , Technology to reduce the display pair [Prior Art] Vision is the sensory line of different waves acting on the view and the detection caused by the human brain has the basic function of the system. The wavelength of visible light in the human eye is 390~78〇 millimeters (nm), which can be spread out in the mountains, and can be distinguished from purple, blue, blue, green, yellow, dial, and work: the main color is Within 120~180 different colors. Color discrimination is mainly the function of visual cells. Because the visual cell collection is distributed in the center of the retina, it is the strongest color. At the peripheral part, the retinal sensation of green, red, yellow and blue disappears. . It is also known from physics that white light and any color on the spectrum can be produced by appropriately mixing three colors of red, green and blue. The theory of color perception is currently explained by the "three primary colors theory." According to this theory, there are three kinds of cones or corresponding photosensitive pigments on the retina that are particularly sensitive to the wavelengths of red, green and blue light. When different wavelengths of light enter the eye, they can cause sensitive wavelengths to match or be similar. The visual cells are excited to varying degrees, and the corresponding color vision is produced in the brain; if the three visual cells are stimulated to the same extent, a white color vision is produced. Currently, flat panel displays, such as liquid crystal displays (LCDs), are used to display computers and other analogous and digital materials, including fine 1252465 1 made of halogen, which are illuminated in a certain pattern to form images (letters, numbers, secrets, and others). Graphics). The cell is the smallest physical unit to constitute a "display unit", and the sub-pixels of the 4 display are arranged in a line stripe shape (Stdpe) (such as "第!图" color ^. line stripe (such as the first! It is a sub-line, r, g, b, which represents the red and green color, and is line-lined. It also drives the basic part of π to 1C曰二贝不器, which accounts for a very high proportion of LCD cost. The main function is Output the required voltage to the pixel to control the degree of twist of the liquid crystal. p; LCD needs color filter (c〇i〇r fi CF), and the signal processing of 1C control, 佶俨p North, μ, 々 use color county film processing, performance Υ (four) Μ 'can be produced on the glass substrate, two: color filter production left, _ bamboo, · green, blue three primary colors of organic materials, In the parent's sub-single r, g, b. Arrangement: mr map" shows the current common color ray film analysis image, high; production = arranged as a line stripe (stripe), As shown in the second, the gate drive (four) and each source channel (ehannel) ^ g, b Each $ to drive 1c, the driver IC needs to use _ a signal foot drive or text small ruler nuclear age:; = (4) money display graphics drive 1C' each display, LCD The cost is very high. The driving force of 1C will result in a very high cost pressure for the producers of 1252465. At the same time, it will drive the mutual supply and demand of the ic. When the demand is higher, the unit cost of the driver 1C will be higher. SUMMARY OF THE INVENTION The main purpose of the present invention is to reduce the use rate of image pixels by utilizing the visual error of the color perception of the human eye, and to reduce the number of driving 1C and reduce the liquid crystal display when the resolution is reduced by a little. The driving 1C cost and the quantity required for driving 1C. The present invention is a shared halogen display method, which drives 1C to first sample the raw elements (r, g, b) of the original halogen, and the sub-tend sampling system is matched with color. The elements of the filter (R, G, B) are arranged to determine the difference between the adjacent elements after sampling, and then the redistribution of the weight ratio by the adjacent homochromatic elements, then drive 1C and then sample and The weight ratio is redistributed into the prime (R, G, B) signals to Matching the color light film display. If it is, the redistribution of sampling and mode weight ratio can lead to the reduction of the demand for the signal channel (R, G, B) in the display area, and the visual error of the human eye color vision is reduced. Unnecessary image quality, reducing the number of driving 1C, reducing the cost of driving 1C of liquid crystal display and the number of requirements for driving 1C. [Embodiment] The details and technical description of the present invention are described below with reference to the drawings. : Please refer to the "Figure 2" for a block diagram of the shared pixel display method of the present invention. As shown in the figure, the method is mainly as follows: (a) The original high-resolution image arranged in a line stripe shape The original element 10 (as shown in Figure 1). 7 1252465
低解析之影像顯示方法,係針對顯示原始高解析影像之原 晝素10,驅動1C先對原晝素10之子畫素r、g、b取樣 該子畫素r、g、b取樣係搭配彩色濾光片之晝素R、〇、b 排列。 其中,該取樣規則係當搭配之彩色濾光片顯示為晝素 R,則在對原晝素10的取樣則以子晝素r為主;當搭配之 彩色;慮光片顯示為晝素G,則在對原畫素1 〇的取樣則以子 晝素g為主,當搭配之彩色濾光片顯示為晝素B,則在對 原晝素10的取樣則以子畫素b為主。 該取樣方式,現舉例說明如次,請先參閱「第3圖 係本發明之晝素取樣實施例一示意圖,如圖所示,線條紋 狀配置之三個原晝素10分別取出其子晝素r、子畫素g、 子畫素b,然後分別置入搭配之彩色濾光片上所對應之晝 素R、晝素G、晝素B的位置,其中該晝素尺>(}、6係 一二角形狀之配列方式,也就是把晝素R、晝素〇、畫素 B成三角形堆積排列,如是本來三個原畫素1〇分別取出其 子畫素Γ、子晝素S、子晝素b須使用的九個通道(cl〜c9), 在本實施方式只須使用三個通道(Cl〜C3)既可。 取出其四個子晝素r、g 慮光片上所對應之晝素 該畫素R、G、P^l 立請再參閱「第4圖」係本發明之晝素取樣實施例二 不意圖。如圖所示,線條紋狀配置之二個原晝素10分別 g、g、b,然後分另置入搭酉己之彩色 t R、晝素G、晝素b的位置,其中 G、B為上下左右非同色之條狀配列方式,且 1252465 晝素寬度為一大一小(比例為1:2)之條狀交錯排列,如是, 本來習知線條紋狀配置二個原晝素10分別取出其四個子 晝素r、子畫素g、子畫素b須使用的六個通道(cl〜c6), 在本實施方式只須使用四個通道(Cl〜C4)既可。此實施 例之取樣方法,在色覺的考量上對原光色(color)數的選擇 上,損失了部份的畫素R與晝素B之發光點,而對人眼色 覺感受力低的綠光(G),因為對該色光較為不敏感,則全部 保留其發光點。 請再參閱「第5圖」係本發明之晝素取樣實施例三示 意圖。如圖所示,線條紋狀配置之二個原畫素10分別取 出其子晝素r、b,然後別置入搭配之彩色濾光片上所對應 之畫素R、晝素B的位置,而二個原晝素10之子晝素則 經過”相加除2“之運算再置入搭配之彩色濾光片上所對應 之晝素G的位置,其中該晝素R、G、B為上下左右非同 色之條狀配列方式,且晝素寬度為一大一小(比例為1:2) 之條狀交錯排列,與實施例二相同的彩色濾光片排列,但 顯示器之走線則有所不同,但相鄰兩列寬度小之晝素列C2 為一相串接樣式,如是,本來習知線條紋狀配置二個原晝 素10分別取出其四個子畫素r、子晝素g、子晝素b須使 用的六個通道(cl〜c6),在本實施方式只須使用三個通道 (C1〜C3)既可。此實施例之取樣方法,在色覺的考量上 其光色數的選擇上,損失了部份的畫素R與晝素B之發光 點,而對人眼色覺感受力低的綠光(G),因為對該色光較為 不敏感,則全部保留使用其發光點並混合計算顯示。 1252465 請再參閱「第6圖」係本發明之晝素取樣實施例四示 意圖。如圖所示,與前述實施例三相同,線條紋狀配置之 二個原畫素10分別取出其子晝素r、b,然後別置入搭配 之彩色濾光片上所對應之畫素R、晝素B的位置,而二個 原晝素10之子畫素則經過”相加除2“之運算再置入搭配之 彩色濾光片上所對應之畫素G的位置,其中該晝素R、 G、B為上下左右非同色之條狀配列方式,與前述實施例 三不同的是本彩色濾光片配列的晝素寬度相同,如是,本 來習知線條紋狀配置二個原晝素10分別取出其四個子晝 素r、子晝素g、子晝素b須使用的六個通道(cl〜c6), 在本實施方式只須使用三個通道(Cl〜C3)既可。此實施 例之取樣方法,在色覺的考量上其光色數的選擇上與前述 實施例三相同,損失了部份的晝素R與晝素B之發光點, 而對人眼色覺感受力低的綠光(G),因為對該色光較為不敏 感,則全部保留使用其發光點並混合計算顯示。 (c)根據所需之顯示應用面,可針對四個實施選取所需 彩色濾光片之配列,如:實施例一對圖片的顯示效果較文 字顯示佳之特點,請再參閱「第2圖」,當驅動1C針對所 搭配彩色濾光片之配列先對原晝素10之子晝素r、g、b 取樣後,因為經由畫素再分配,達到降低解析的不同,雖 然驅動1C的通道需求數減少,但也因此損失了部分顯示 資訊,也因損失程度不同,所以新配列所產生的色散度亦 會不同。所以驅動1C需先對取樣後之兩相鄰晝素做判斷, 判斷兩相鄰晝素的内含差值是否大於設定值,如果兩相鄰 1252465 晝素的内含差值大於預定的設定值’即損失的顯示資訊, 再由相鄰之同色晝素做權重比例的再分配。 (d)該權重比例的再分配,係根據一般顯示,晝素與晝 素之間存在著一定的相鄰關係,因此取樣後損失的色光元 素,可以由相鄰的晝素補償,以加強顯示效果。請參閱「第 7圖」,係以取樣後差值的晝素為一中心晝素R(x,y)、G(x,y) 或B(x,y),以該中心晝素R(x,y)、G(x,y)或B(x,y)為主, 與周邊相鄰之同色晝素(以中心畫素R(x,y)為例,其座標 方位之周邊相鄰之同色晝素為、R(x,y_l)、 R(x+l,y_l)、R(x-l,y)、R(x+l,y)、R(x-l,y+l)、R(x,y+1)、 R(x+l,y+l))之權重比例補償值合等於1做相鄰的晝素補 償0 即 R(X-l,y-l) + R(X,y-l) + R(X+l,y-l) + R(X-l,y) + R(x,y) + R(x+l,y) + R(x-l,y+l) + R(X,y+l) + R(x+1,y+1)= 1 ° G(x-l,y-l) + G(x,y-1) + G(x+l,y-l) + G(x-l,y) + G(x,y) + G(x+l,y) + G(x-l,y+l) + G(x,y+1) + G(x+l,y+i) = i。 B(x-l,y-l) + B(x,y-l) + B(x+l,y_l) + B(x-l,y) + B(x,y) + B(X+l,y) + B(x-l,y+l) + B(X,y+l) + B(X+l,y+l)=。 (e)驅動IC再將經過取樣與權重比例再分配之晝素 R、G、B訊號分配到搭配之彩色濾光片,作為影像顯示之 發光訊號。 (0俾藉取樣與方式權重比例再分配,晝素尺、G、b 訊號分配到搭配之彩色濾光片做共享式的影像顯示,藉 11 1252465 此,可使顯示區晝素R、G、B對驅動1C之訊號通道需求 的減少。 如前實施例一、二、三、四所述之原須九個通道 (cl〜c9),使用本發明之共享式晝素顯示方法只須使用三 個通道(C1〜C3)(實施例一),及原須六個通道(cl〜c6), 使用本發明之共享式畫素顯示方法只須使用四個通道 (。1〜。4)(實施例二),或三個通道(。1〜。3)(實施例三、 四),該通道數的相對減少,意味著談驅動1C個數將可減 少,如是可以減少液晶顯示對驅動1C的需求數量,降低 驅動1C方面的成本。 惟上述僅為本發明之較佳實施例而已,並非用來限定 本發明實施之範圍。即凡依本發明申請專利範圍所做的均 等變化與修飾,皆為本發明專利範圍所涵蓋。 【圖式簡單說明】 第1圖,係一般線條紋狀之配列示意圖。 第2圖,係本發明之共享式晝素顯示方法方塊圖。 第3圖,係本發明之晝素取樣實施例一示意圖。 第4圖,係本發明之晝素取樣實施例二示意圖。 第5圖,係本發明之晝素取樣實施例三示意圖。 第6圖,係本發明之晝素取樣實施例四示意圖。 第7圖,係本發明之權重比例再分配之示意圖。 【主要元件符號說明】 原晝素10 子晝素r、g、b 12 1252465 畫素 R、G、B 通道 cl〜cl8、Cl〜C8The low-resolution image display method is for displaying the original high-resolution image of the original element 10, driving the 1C to first sample the sub-pixels r, g, b of the original element 10, and sampling the color of the sub-pixels r, g, b. The elements of the filter are arranged in R, 〇, and b. Wherein, the sampling rule is that when the color filter matched with the display is a halogen R, the sampling of the original halogen 10 is mainly sub-element r; when the color is matched; the light film is displayed as a halogen G , the sampling of the original pixel 1 则 is dominated by the sub-sputum g, when the color filter of the match is shown as alizarin B, the sampling of the protopin 10 is mainly sub-pixel b . For the sampling method, the following is an example. Please refer to the third drawing, which is a schematic diagram of the sample sampling method of the present invention. As shown in the figure, the three primary elements 10 arranged in a line stripe shape are respectively taken out. Prime r, sub-pixel g, sub-pixel b, and then placed in the color filter corresponding to the position of the alizarin R, alizarin G, alizarin B, wherein the niobium ruler > (} The arrangement of the 6-series and the two-corner shape, that is, the arrangement of the alizarin R, the alizarin, and the pixel B into a triangle, if the original three primitives are taken, respectively, the sub-pictures and sub-crystals are taken out. S, sub-small b must use nine channels (cl~c9), in this embodiment only need to use three channels (Cl~C3). Take out the four sub-small elements r, g on the optical film The pixels R, G, and P^l are referred to the "Fig. 4" for the purpose of sampling the second embodiment of the present invention. As shown in the figure, the two elements of the line stripe arrangement are as shown. 10 respectively g, g, b, and then separately placed into the position of the color t R, alizarin G, alizarin b, where G, B are the upper and lower left and right non-same color strips And 1252465 昼 宽度 width is a large and a small (proportion 1:2) strip staggered, if so, the conventional line stripe configuration of the two original elements 10 respectively take out its four sub-salmon r, sub The six channels (cl~c6) to be used for the pixel g and the sub-pixel b, in this embodiment, only four channels (Cl~C4) are required. The sampling method of this embodiment is considered in the color vision. On the selection of the original color number, the part of the pixel R and the pixel of the halogen B are lost, while the green light (G) which is low in the color perception of the human eye, because the color is not If it is sensitive, then all the light-emitting points are retained. Please refer to Fig. 5 for a schematic diagram of the third embodiment of the sample sampling of the present invention. As shown in the figure, the two original pixels 10 arranged in a line stripe shape are respectively taken out. The primes r and b are then placed in the position of the pixel R and the halogen B corresponding to the color filter matched with the color filter, and the two elements of the original element 10 are subjected to the operation of "addition and division 2". Place the position of the element G on the matching color filter, where the elements R, G, and B are the same color of the upper, lower, left, and right sides. Arrangement method, and the width of the pixels is one-to-one (1:2) strips staggered, and the same color filter arrangement as in the second embodiment, but the display lines are different, but adjacent The two columns of the width of the halogen column C2 are in a one-phase series mode. If so, the conventional line stripe is configured to take out four sub-pixels, respectively, and the four sub-pixels r, the sub-salmon g, and the sub-salmon b. The six channels (cl~c6) used are only required to use three channels (C1 to C3) in this embodiment. The sampling method of this embodiment selects the number of light colors in the consideration of color vision. Loss of some of the pixel R and the light point of the halogen B, while the green light (G) with low sensitivity to the human eye color color, because it is less sensitive to the color light, all retains its light-emitting point and mixes the calculation display. . 1252465 Please refer to FIG. 6 again for the fourth embodiment of the present invention. As shown in the figure, in the same manner as in the third embodiment, the two original pixels 10 arranged in a line stripe shape respectively take out the sub-small elements r and b, and then do not put the pixel R corresponding to the matched color filter. The position of the element B, and the sub-pixels of the two original elements 10 are subjected to the operation of "addition and division 2" and then placed on the color filter corresponding to the position of the pixel G, wherein the element R, G, and B are stripe arrangement modes of the upper, lower, left, and right non-identical colors. The difference from the third embodiment is that the color filters of the present color filter have the same width. If so, the conventional stripe-like arrangement of the two original elements is 10 The six channels (cl~c6) to be used for the four sub-halogens r, the sub-salm g, and the sub-salm b are respectively taken out. In the present embodiment, only three channels (Cl to C3) are required. The sampling method of this embodiment is the same as the foregoing embodiment 3 in the selection of the color chromaticity in the consideration of the color sensation, and the light-emitting point of the halogen element R and the halogen element B is lost, and the color perception of the human eye is felt. The low green light (G), because it is less sensitive to the color light, all retains its light-emitting point and mixes the calculated display. (c) According to the required display application surface, the matching of the required color filters can be selected for the four implementations. For example, the display effect of the pair of pictures in the embodiment is better than that of the text display, please refer to "Fig. 2" When the driver 1C samples the color filters of the matched color filter, the samples of the raw elements 10, s, r, and b of the original sinus 10 are sampled, because the pixels are redistributed to reduce the difference in resolution, although the number of channels required to drive 1C is required. The reduction, but also the loss of part of the display information, but also due to the degree of loss, so the new arrangement will produce different dispersion. Therefore, driving 1C needs to first judge the two adjacent pixels after sampling, and determine whether the difference between the two adjacent pixels is greater than the set value, if the difference between the two adjacent 1252465 elements is greater than a predetermined set value. 'that is, the display information of the loss, and then the redistribution of the weight ratio by the adjacent homochromogen. (d) The redistribution of the weight ratio is based on the general display that there is a certain adjacent relationship between the element and the element. Therefore, the color light elements lost after sampling can be compensated by adjacent elements to enhance the display. effect. Please refer to Figure 7 for taking the difference between the samples as a central element R(x,y), G(x,y) or B(x,y) to the central element R ( x, y), G(x, y) or B(x, y) is the main color, and the homochromatic element adjacent to the periphery (taking the central pixel R(x, y) as an example, the vicinity of the coordinate orientation The homochromatic elements are, R(x, y_l), R(x+l, y_l), R(xl, y), R(x+l, y), R(xl, y+l), R(x , y+1), R(x+l, y+l)) The weight ratio compensation value is equal to 1 to be adjacent to the pixel compensation 0, ie R(Xl,yl) + R(X,yl) + R( X+l,yl) + R(Xl,y) + R(x,y) + R(x+l,y) + R(xl,y+l) + R(X,y+l) + R( x+1,y+1)= 1 ° G(xl,yl) + G(x,y-1) + G(x+l,yl) + G(xl,y) + G(x,y) + G(x+l,y) + G(xl,y+l) + G(x,y+1) + G(x+l,y+i) = i. B(xl,yl) + B(x,yl) + B(x+l,y_l) + B(xl,y) + B(x,y) + B(X+l,y) + B(xl, y+l) + B(X,y+l) + B(X+l,y+l)=. (e) The driver IC then distributes the pixel R, G, and B signals that have been sampled and weighted and redistributed to the matched color filter as the illuminating signal for the image display. (0) by sampling and mode weight ratio redistribution, the pixel scale, G, b signal is assigned to the matching color filter for shared image display, by 11 1252465, the display area can be R, G, B reduces the demand for the signal channel driving 1C. As in the previous embodiments 1, 2, 3, and 4, the original nine channels (cl~c9) are used, and the shared pixel display method of the present invention only needs to use three Channels (C1 to C3) (Embodiment 1), and original six channels (cl~c6), using the shared pixel display method of the present invention, only four channels (.1 to .4) are used (implementation) Example 2), or three channels (.1 to 3.) (Examples 3 and 4), the relative reduction in the number of channels means that the number of driving 1C will be reduced, and if it is possible to reduce the liquid crystal display to drive 1C The number of requirements is reduced, and the cost of driving 1C is reduced. However, the above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the practice of the present invention. It is covered by the scope of the patent of the present invention. 1 is a schematic diagram of a general line stripe arrangement. Fig. 2 is a block diagram of a shared pixel display method of the present invention. Fig. 3 is a schematic view of a sample of a sample of the present invention. The schematic diagram of the second embodiment of the present invention is shown in Fig. 5. Fig. 6 is a schematic view of the fourth embodiment of the sample of the present invention. Fig. 7 is a schematic view of the fourth embodiment of the present invention. Schematic diagram of redistribution of weight ratios [Description of main component symbols] Protopin 10 Subunits r, g, b 12 1252465 pixels R, G, B channels cl~cl8, Cl~C8