FR2535856A1 - Colour selection filter for single-tube colour TV camera - Google Patents

Abstract

The filter is designed for colour TV camera with a single camera tube and has a mosaic image of cyan, yellow, white and green filter elements. A sum of values, corresp. to the wavelengths of the spectral permeability of the cyan and yellow filter elements, is equal to the sum of values, corresp. to the sum of the wavelengths of the spectral permeability of the white and green filter elements. The difference between the two wavelength level sums within an image generating wavelength range is pref. zero. The white filter element may be replaced by one with a partial screening characterising, thus partly screening the wavelength band and the photoenergy of at least one of the main colours. The filter prevents fading and colour mixture interference on the tube screen.

Description

 The present invention relates to a color separation filter, and more particularly to an improvement of a color separation filter for a color tube camera of the single sensor tube type.

 In general, in a single sensor tube type color television camera, which incorporates a line color separation filter having yellow light filtering elements serving as a complementary color in the spatial modulation of blue light. and cyan light serving as complementary color in the spatial modulation of the red light, a projection image of the filter is directly or indirectly formed on a photoelectric conversion surface or photoreceptor surface of the sensor tube. A charge pattern resulting from the projection image is explored by an electron beam. A chromatic signal is obtained according to the relation in time, due to the exploration pace and the spatial relation due to the separation filtering. colors of the charge pattern, and a luminance signal is obtained according to the charge pattern.

However, in a conventional color television camera of the type described above, there is an undesirable periodicity of a luminance signal which is due to imperfect characteristics of the color separation filter, and a flapping noise on the screen thus degrading the quality of the imagez
The present invention is based on the consideration of the conventional disadvantage and is intended to provide a color separation filter for reducing the beat noise occurring on a screen.

In order to achieve the above object of the present invention, a color separation filter is provided wherein an average of a component of the luminance signal corresponding to a series of filter portions
yellow and cyan is substantially equal to that of a component of the luminance signal corresponding to a series of green and white filter parts.

 According to the color separation filter, a light / dark beat noise in a luminance channel can be significantly reduced, thereby obtaining a high quality image.

The invention will be better understood, and other objects, features, details and advantages thereof will appear more clearly in the following explanatory description made with reference to the accompanying schematic drawings given solely by way of example illustrating a embodiment of the invention and in which
FIG. 1 is a plan view of line filtering elements for explaining a color separation filter according to the invention;
FIG. 2 is a graph showing the spectral transmittivity, on the y-axis as a function of wavelength, on the abscissa axis, in order to explain a color separation filter according to the prior art; and
FIGS. 3 to 5 show graphs of the spectral transmittivity as a function of the wavelength for explaining a color separation filter according to the invention.

 In order to better understand a color separation filter according to the invention, the principle of its operation will be described with reference to line filter elements shown in FIG. 1 before describing a preferred embodiment.

Figure 1 is a plan view of line filter elements for a color separation filter looking from the optical axis of the color separation filter. Referring to FIG. 1, reference numerals 1a to 1c designate elements of the yellow line filter; and 2a to 2c elements of the cyan line filter. The yellow line filter elements 1a to 7c and the elements of the cyan line filter 2a to 2c together constitute the filter portions 3
yellow, the cyan filter parts 4, the green filter parts 5 where the yellow and cyan elements overlap and the white filter parts 6. Parts 6 will not modulate any of the three primary colors.

Such a color separation filter is disclosed in Japanese Patent Publication Nos. 8698/70 and 8699/70.

 In the color separation filter having the construction described above, the magnitudes of the signals obtained by parts 3, 4, 5 and 6 are defined by Ye, Cy, Gr and Wh, respectively. A R-color signal based on red light is given by R = Wh + Ye-Cy -Gr; and a color signal B based on blue light is given by B = Wh + Cy - Ye - Gr.

A luminance signal L is the average of the color signals which is given by L = (Wh + Ye ± Cy + Gr) / 4.

In general, when the luminance signal has a period which is equal to or less than a horizontal period of a monarch pattern consisting of parts 3, 4, 5 and 6, no resolution according to the operating principle is required from the color television camera of the type to a single tube sensor. However, problems are often posed with a long periodicity of the monarch pattern in the use of the color separation filter of the type described above, giving rise to a beat noise. For simplicity of description, it is now assumed a series comprising parts 3 and 4 and a series comprising parts 5 and 6 in the mosaic pattern are parallel to the direction of horizontal scanning and an nth scanning electron beam is moving along the series of parts 3 and 4 in the direction of the extension of this series. Then, the series comprising parts 3 and 4 extends in the direction of the arrow Ail (phantom) and the series comprising parts 5 and 6 extends in the direction of the arrow A21, followed by the series in FIGS. direction of arrows A12 and A22, so that a periodicity of period P in vertical direction occurs. This periodicity is longer than a periodicity in the horizontal direction and is comparable to the range of the luminance resolution.

Thus, the difference between the luminance magnitudes along the directions A11 and A22 results in a wavy output. More particularly, the corrugated output LR is given as the difference between the luminance signal
L1 = (Cy + Ye) / 2 corresponding to the series of parts 3 and 4 and a luminance signal L2 = (Wh + Ge) / 2 corresponding to the series of parts 5 and 6. The difference appears in the form of a beat noise on the screen.

In addition, if the directions A11, A21, A12, A22 coincide substantially with the horizontal scanning direction, the periodicity of the charge causes a periodic bending of the electron beam according to the horizontal scan when the electron beam impacts the photo-electric conversion film, thus giving rise to a faulty pairing of the weft and to a faulty crawling due to an uneven surface potential.

By studying the corrugated output, the inventor of the present application found that the characteristics of the color separation filter according to the prior art were incomplete. More particularly, with reference to FIG. 2 showing the relationship between optical transmittivity and wavelength in the prior art color separation filter, it can be seen that in a shorter range WR1 of wave, the following relation is not exact W GN = + G x = + A + where W pk is the spectral transmittance of the blank represented by curve 14, G is the spectral transmittivity of green represented by curve 13, CN , is the spectral transmittivity of the cyan represented by the curve I1 and Y # is the spectral transmittivity of the
Yellow represented by the curve I2, but the term on the left is more important than the term on the right and furthermore, the curve 13 is shifted with respect to the curve I2. Such inequality and displacement are responsible for producing the wavy output. Even in the features of the prior art, the output of the corrugated output is suppressed in a wavelength range WR2.

 The present invention will be described in detail with reference to Figures 3 to 5.

où SX est le produit de l'énergie spectrale de la source de lumière des longueurs d'onde respectives entre #O et #n , de la sensibilité spectrale de la surface photoréceptrice et des composantes de transmitti vité spectrale à l'exclusion de celles du filtre de séparation des couleurs; C A , Y > , W pt , et G # sont des composantes de transmittivité spectrale du filtre de séparation des couleurs; et O > est le facteur de réflexion spectrale d'un objet à photographier.Par conséquent, les signaux de luminance L1 et L2 sont donnés comme suit

The signal levels Cy, Ye, Wh and Gr are given as follows

where SX is the product of the spectral energy of the light source of the respective wavelengths between # 0 and #n, the spectral sensitivity of the photoreceptive surface and the spectral transmittance components excluding those of color separation filter; CA, Y>, W pt, and G # are spectral transmittivity components of the color separation filter; and O> is the spectral reflection factor of an object to be photographed.Therefore, the luminance signals L1 and L2 are given as follows

 To eliminate the wavy output, it is necessary to establish C + Y A = W + G (that is, the average of a combination of the components of cyan and yellow is equal to that of a combination of white and green components) when using a filter where the yellow filter elements intersect the elements of the cyan filter or when using a filter matrix of the yellow, cyan, green and of white.

In order to obtain substantially the above results, there are typically four arrangements as follows:
1. Referring to FIG. 3, the white filter portion 6 (FIG. 1) has the same spectral transmittivity curve as an upper envelope curve (given by the points a1 S a2 and a3) given by a curve. of spectral transmittivity 7 (given by the points b1, b2, a2 and a3) of the yellow filter part 3 (FIG. 1) and a spectral transmittivity curve 8 (given by the points a1, a2, b3 and b4) while the green filter portion has the same spectral transmittivity curve as a lower envelope curve given by the points b1, b2, a2tb3 and b4.

 2. Referring to Fig. 4, when the yellow filter portion 3 has a spectral transmittivity curve (d1, d2, d3, d4, C4 and c5) and the cyan filter portion 4 has a spectral transmittivity curve ( c1, c2, d4, d6, d7 and d8), the white filter portion 6 must have a spectral transmittivity curve (C1, c2, C3, C4 and C5) beyond an upper partial envelope curve ( c2, d4 and c4) spectral transmittance curves of the yellow and cyan filter portions 3 and 4 with respect to any wavelength between # 1 and # 2.

In the same condition, the green filter 5 must have a spectral transmittivity curve (d3, d5 and d6) below a lower partial envelope curve (d3, d4 and d6) of the spectral transmittance curves of the filter parts. yellow and cyan 3 and 4 with respect to any wavelength between # 1 and A 2
At the same time, the spectral transmissivities in the bandwidth between # 1 and A 2 must satisfy the condition WX - C # = Y # - G.

 3. Referring to Fig. 5, when the yellow filter portion 3 has a spectral transmittivity curve (f1, f2, f3 'f5' f6 'f7, e5 and e6) and the cyan filter portion 4 has a spectral transmittivity curve (e1, e2, e3, e4, f7, f8, fg and f10), the white filter portion has a spectral transmittivity curve (12 and 14) which is below a partial envelope curve higher (e2, e3 and e4) spectral transmittance curves of the cyan and yellow filter portions 4 and 3 with respect to any wavelength between # 3 and # 4, and has a spectral transmittivity curve ( 14 and 1 which is above an upper partial envelope curve (14, f7 and e5) spectral transmittance curves of the cyan and yellow filter portions 4 and 3 with respect to any wavelength lying between # 4 and pX 5. Under the same conditions, the green filter portion 5 must have a spectral transmittivity curve (f3, f4 and f6) beyond a lower partial envelope curve (f3, f5 and f6) of the spectral transmittivity curves of the yellow and cyan filter portions 3 and 4 with respect to any wavelength-between # 3 and # 4 and have a spectral transmittance curve (f6 and f8) below a lower partial envelope curve (f6, f7 and f8) of the spectral transmittivity curves of the yellow and cyan filter parts 3 and 4 with respect to any wavelength lying between # 4 and # 5.

At the same time, the condition W, - C = Y Y - G, must be satisfied between # 3 and # 5.

 4. The conditions given in Articles 2 and 3 are mixed.

 When a color separation filter is designed, there are two types of color separation filters: a film filter using interference from a thin optical film; and a filter using staining (i.e., dye or pigment) by light absorption. In the latter type of filter, utility coloring filters are manufactured for mass production marketing so that the organic resin films are colored by an organic dye.

However, the spectral transmittivity characteristic of the color filter of this type is unsatisfactory for color reproduction in a color television. In particular, the color filter has low spectral transmittivity of the cyan filter component in a short wavelength range and the green filter portion is generally obtained by overlapping between the cyan and yellow filter elements. As a result, the spectrum transmittance curve. becomes continuous, so the characteristic similar to that of FIG. 4 is obtained. Moreover, the absorption characteristic of the cyan filter element of the organic filter is at a relatively short wavelength range, so there is degradation of color reproduction. In order to prevent this, it has been proposed to use a magenta filter component instead of the white filter component to absorb some of the green light in the relatively long wavelength band as disclosed in the publication. of Japanese Patent No. 85009/82. In general, the magenta filter component has a partial protection feature that partially protects the wavelength band and the light energy of at least one of the three primary colors.

This feature is shown in Figure 2 and has the disadvantages described above.

In order to establish substantially the condition
In the case shown in FIG. 4, a surface (d3, d5, d6, d4 and d3) defined by the lower partial envelope curve (d3, d4 and d6) spectral transmittivity curves of the yellow and cyan filter portions 3 and 4 and the spectral transmittivity curve (d3, d5 and d6) of the green filter portion 5 are substantially equal to a surface (c2, d4, c4, d3 and c2) defined by the upper partial envelope curve (c2, d4 and c4) of the spectral transmittivity curves of the yellow and cyan filter portions 3 and 4 and the spectral transmittivity curve (c2, 3 and c4) of the 6. Moreover, the above surface equality can be set between / -1 and X 2 by weighting the surfaces with the spectral sensitivity of the camera tube, thus achieving the effect sensitive.

 According to one experiment, between itO and X (for example 400 to 700 nm) when a white object is photographed, with a ratio of the mean level of the luminance signal L = (Wh + Ye + Cy + Gr) / 4 at the corrugated output level LR = L1 ~ L2 = t (Wh + Gr) rV (Cy + Ye)} / 2 of about 1.0 to 1.2%, substantial improvement can be achieved. However, when the ratio increases to 1.5% or more, the quality of the image deteriorates.

 It has also been found that it is preferable that the ratio does not exceed 3% in practice when bars of red, blue, green, cyan, magenta and yellow color (having an average width of wavelength in the distribution of the signal, i.e., 60 to 70 nm image-forming wavelength range) are photographed as reference color bars for evaluating color reproduction of a color television . The choice of the wavelength range of image formation appears to be a design issue but in the foregoing embodiments, it has been confirmed that a range of 60 to 70 nm was satisfactory, in the practical, for general purpose television cameras.

According to the embodiments described above, since the effective spectral transmittivity of the cyan or yellow filter (ie the spectral transmittivity with respect to that of a filterless part) can change, the reproduction fidelity of the colors of a color television camera for the separation of complementary colors such as cyan and yellow can be improved. For example, referring again to FIGS. 3 and 5, the reproducibility of red is mainly determined by the average wavelength width of the cyan wave. When the average wavelength widths of FIGS. 4 are compared, the average width
The wavelength of FIG. 2 is a wavelength at which the spectral transmittance of the portion of the cyan filter decreases by half while the transmissivity of the white filter is substantially constant.

Referring to Figure 5, the white filter portion has a relatively low spectral transmittance in a central portion (green band having a considerably long wavelength) while the average wavelength width of the portion of the cyan filter is shifted to the side of the longer wavelengths. Therefore, without significantly lowering a red signal level, the average wavelength width can be shifted, thereby improving the reproducibility of the colors.

 In the above embodiments, a color separation filter of a carrier-wave system is adopted where the pitch of the single filter is given along the horizontal scanning direction. However, the present invention is not limited to the above arrangement. For example, a color filter of the dual carrier system as disclosed in US Patent No. 3,291,901 may be used to achieve the same effect as in the above embodiments.

 As described above, the color separation filter according to the invention makes it possible to substantially suppress the production of beat noise on the luminance channels, thus producing high quality images.

Claims (3)

 1. A color separation filter for a color television camera of the single sensor tube type, said filter having a mosaic pattern of cyan, yellow, white and green components, characterized in that a sum of corresponding values at the wavelengths of the spectral transmissivities of the cyan (C A) and yellow (Y t) components is substantially equal to a sum of values corresponding to the wavelengths of the spectral transmissivities of the white (WA) and green (G p) components in a wavelength range of forming the image of an object.  2. A filter according to claim 1, characterized in that the difference between the sum of the cyan and yellow signal levels and the sum of the green and white signal levels is integrated to be substantially zero in said range of wavelengths. image formation.  3.- Filter according to any one of claims 1 or 2, characterized in that the component of the white filter is replaced by a component having a partial protection characteristic which partially protects the wavelength band and the energy of the light of at least one of the three primary colors.