DE6603578U - TELEVISION EARNS - Google Patents

Description

DR.-ING. HANS-DIETRICH ZELLER MOO HAMBURG 1,

PatenUnw.lt Menckebe ^ «ti» Be 7

Telephone: 339221 Telegraph:

N 18 288/21 a Gbm.;:. aüu d

NV Philips ¹ Gloeilampenfabrieten My file: PHN 1201

TV pickup tube

The innovation relates to a television pickup tube for converting image-generating radiation in the visible part of the spectrum into electrical signals, which contains a translucent front wall made of glass - on the side of which a photosensitive layer is applied, and the innovation is particularly important in relation to the vidicon pickup tubes -Iyp, ie receiving tubes in which the photosensitive layer is a photoconductive layer whose I ₃ surface facing away from the end wall can be scanned by an electron beam generated by an electron gun installed in this tube.

When viewing color television pictures, one often sees that certain areas of the image have an unnatural hue that is different from the color of an adjacent one colored area with dimensions that are not too small. This effect, which is easiest to see with

on flesh-colored areas is noticeable, the more disturbing the closer the color rendering of the picture comes to reality. With black and white television you can

(O

a similar effect can be found in the form of graying, but this effect is generally less disturbing if at least no places with a high level of light are present are. By increasing the black level, the probability

λ -5 4- * 3 -i λ rt Λ r ~ » " $ 7Ώ Vl "PQ Vl Viii Vi r» £ 3 Ä "f * · ί * £ * Ί **" ί * ^ CS Vl AV »ö TlCS A 4 "Π? D Vl A VvCk Vl

this is at the expense of rendering the white areas.

The fact that when using Vidicon tubes with one consisting essentially of lead oxide, in particular to a considerable extent from its tetragonal, redder Modification, an existing photoconductive layer such unnatural tint was likely to occur to a greater extent, while such tubes were otherwise than proved particularly suitable for a true-to-life color reproduction in color television processes ^ gave rise to the assumption Reason that this effect could be attributed to halation, i.e. to false light due to internal reflection in the glass front wall of the tube. In this case, the fact that the tinting effect could result in a vidicon with a photoconductive layer of lead oxide could easily be explained by that such a lead oxide layer, if you pass it through the glass front wall of the tube under normal daylight— conditions, offers a more or less intense orange-red sight, which suggests that this Layer a not inconsiderable part of it, especially in this area of the visible spectrum received light reflected.

Liehthofbildung is known and became in the photography already twenty or more years ago also with cathode ray tubes for picture reproduction, in which an electron beam strsML hits a fluorescent screen attached to a glass front wall of the tube, perceived, in the form of the light of the resulting light spot where there are wrinkles that are approximately equal to the

03578

■ angles of total reflection or even greater, on the Outer surface of this wall falls, is reflected to the screen and a circle of light surrounding the light spot, which as Haloring is called, generated. At the time, several proposals were made for overcoming halation such cathode ray tubes made, but when, not all but most of them have not found their way into practice. One of these suggestions was the optical one Thickening of the glass front wall, either in that the tube was provided with a sufficiently thick front width, or in that on the outside a relatively thick layer of a material was applied to the end wall, which has a refractive index that differs only slightly from that of the glass from which the end wall is made. Such an additional Layer could be made of a translucent liquid or a plate or the like. made of solid translucent Material, e.g. glass or plastic.

The above assumption has proven to be correct and The innovation consists accordingly in the fact that the HaIo effects in the glass front wall of the television recorder- tube in a manner entirely acceptable in practice in this case by a sufficient increase in thickness of the optical material in front of the photosensitive layer can be reduced »

According to the innovation, a television pickup tube for converting image-generating radiation in the visible part of the spectrum into electrical signals with a translucent glass front wall, on the inner surface of which a photo-sensitive layer is applied, characterized by the presence of a body of translucent solid material, which is attached to the The outer surface of this front wall is attached and in the projection a considerable part of the mentioned photoempf l ml! ielien layer covered, this body with a lentabsorbielenden on the circumference

Material is provided, while the total thickness of this end wall and this body is so large that light, which passes through the body and the end wall, enters the tube and comes on the mentioned photo-sensitive layer is reflected if it is at angles that are the critical angle of the total reflection approach, falls on the surface of the body facing away from the end wall, from this surface in such a way Directions that it is reflected from the peripheral surface of the body is intercepted.

The innovation is particularly advantageous for overcoming unnatural color tone effects when using pick-up tubes with a semiconducting target Lead oxide; therefore, according to the innovation, in a preferred embodiment thereof, the body is on the outer surface attached to the glass end wall of a tube of the Vidicon type, this tube being on the inner surface this end wall is provided with a photoconductive layer, which essentially consists of tetragonal red lead oxide exists and. an orange-red appearance in normal daylight! shows. j

: The innovation is shown below using the accompanying drawing

: tion explained in more detail, in dtr schematically a longitudinal section

by an example of a television pickup tube according to FIG Hiring shown in the form of a vidicon-type tube is,

The distance shown in the single figure of the drawing

J vision tube has a vented cylindrical glass

! piston 1, which at one end through a glass bottom 2 and at the the other end is closed off by a flat front wall 4 made of glass. closed lsi ;. Ia floor 2 siaad electrical connec- s-tif-te 3 added, inside the tube with the different Elements of a slectron radiation suction system 5 Tmfl of an ElekiD? Odengebil ies 6 terirands are. The system "consists of an indirectly heated cathode 7, ice control

3378

-S-

electrode r unc a perforated anode 9. The electrode structure 6, which forms a second anode, consists of a hollow, essentially cylindrical part 11, which is an the end facing the end wall 4 with a conductive Ring 12 is provided on which a wire mesh electrode 13 is attached. The various elements of the electron gun generating system 5 and the second anode 11 are aligned by glass support members 10 with respect to one another.

The inner surface of the end wall 4 is provided with a thin 1 " ^x htpermeable electrode 15, which forms the signal electrode of the tube. This electrode 15», which can consist in a known manner of a thin layer of conductive tin oxide, is provided with a connecting wire 16 made of platinum extending through the cylindrical part 1 of the tube. Outside the tube, the wire 16 is connected to a conductive ring-like coating 17, for example a burned-on silver coating, which is applied to the part of the tube on which the end wall 4 enters the cylindrical Part 1 skips.

Inside the tube is one extending over the inside surface the end wall 4 applied signal electrode 15 extending photoconductive layer 18 attached, the can be scanned by an electron beam 19 which focuses on this layer 18 and by the beam generation system 5 is generated. The scanning movement and the focusing of the electron beam 19 are carried out by the Pipes 1 surrounding, not shown, focusing and scanning spouts.

The photoconductive layer 18 consists essentially of lead oxide (PbO), a considerable part of which is present in the form of the red, tetragonal modification. The proportion of this red tetragonal modification in the impact layer 18 can be in the vicinity of 90 <$> . the

* ύ ti ¹ ^ i

O O ί

Layer 18, which can have a uniform thickness of the order of magnitude of 5 to 30 microns, preferably 20 microns, is preferably applied to the inside of the end wall 4 by condensation of vaporized lead oxide. When the layer 18 is viewed through the end wall 4, it has an orange-red ™ appearance under normal lighting conditions, Wu.s means that for this part of the visible spectrum the layer 18 has a considerable part of the light falling on it reflected. The television tube described is essentially the same as that under the "Plumbicon" brand from Ή. Y. Philips' Gloeilampenfabrieken, Eindhoven, The Netherlands, manufactured and placed on the market.

The above-mentioned relatively high reflectivity the photoconductive layer 18 can bring about a halo effect with the usual thickness of about 1.2 mm of the end wall 4, which is clearly reproduced in the image that is reproduced with the aid of the signals obtained by means of this pick-up tube is noticeable. This HaIo effect is due to that on the photoconductive layer 18 reflected Lieh '; if it is at angles which are the critical angle of the Approach total internal reflection, on the outer surface of the front wall 4 falls, is reflected to the photoconductive layer 18 .. The radius of the Ilalo ring is known to be

R = '.lh tg sin n' ^where h is ^the thickness of the glass front wall and η is the refractive index of the glass. When η is about 1.5,

is;? in η about 45 and thus R about 2h. For the mentioned Wall thickness of about 1.2 µm is about 2.4 mm, so that a large amount of the outer surface of the end wall is totally reflected Light reaches the photoconductive layer again within the image area, i.e. within that of the electron beam 19 scanned area of the photoconductive layer 18, which is 16x12 mm in the tube described.

TJm such a disruptive halo effect at least in

It · «1 B

To avoid significant dimensions, the tube is provided with a circular disc 20 made of translucent Glass with a refractive index of about 1.5 is made. This disk 20 is central with respect to the end wall 4 arranged and by means of a thin layer 21 of a clear translucent putty of a kind as they generally is used for cementing the components of an optical lens system, with the front surface of the end wall cemented. The layer 21 is preferably made of one under the trademark "Lensbond type M 62" from Summers Laboratories Inc., Port Washington, Pennsylvania, V.S., manufactured and placed on the market, the under low temperature conditions, such as those that occur Can be done if the tube is airborne over the North Pole is conveyed, maintains a desired compliance. The peripheral surface of the disc 20 and the part of the front surface the end wall 4, which is not covered by the disk 20 and the opaque ring-like coating 17 are provided with a layer 22 of light-absorbing material, e.g. with blackboard lacquer or a lacquer, which is commonly used for blackening the inner parts of photo cameras. Preferably, the circumferential surface the disk 20 matted, for example by etching. The front surface of the glass pane 20, i.e. that facing away from the end wall 4 Surface, is covered with a standard anti-reflective coating 23 provided, which preferably maximally reduces the reflection of the light originating from the scene to be recorded. The coating can be such that for pick-up tubes To maintain the red, green and blue television signals, a maximum reduction in reflexes in the red, green and blue part of the spectrum is achieved. The diameter D of the disk 20 must of course be so large that the disk the area of the photoconductive layer 18 which must be scanned by the electron beam 19 and, as mentioned,

ο
in the case described is 16 χ 12 mm, effectively covered. In the exemplary embodiment described, D is about 22 mm (but it can of course be larger) and is thus

with the same, about three \ quarters of the inner diameter of the Tube 1. The total thickness d of the disc 20, the cement layer 21 (the thickness of which is normally negligible) and the glass end wall 4 is such that the greater! part of the image area of the photoconductive layer 18 and then the light reflected on the front surface of the pane 20 does not reach the photoconductive layer again, v / eil this light through the circumferential surface of the disk 20 is intercepted and absorbed.

In the embodiment described, the thickness is the glass pane 20 6 to 7 mm, but it can of course be made slightly larger. It was found, that a thickness of 6 mm is very satisfactory in practice. Since the thickness of the end wall 4 is about 1.2 mm the total thickness is d. about 7 »5 mm, which means that the radius of the halo ring is about 15 mm, i.e. almost equal to the length of the scanned area of the photoconductive Layer 18, is.

The pane 20 is preferably made of clear, i.e. colorless, glass. It should be evident, however, that the disk may optionally consist of colored glass, so that they as an optical filter acts, which only lets through a certain part of the spectrum.

In the embodiment described is the glass pane 20 circular. Obviously it can be a different shape Are used if the pane in the projection less to the east covers the part of the photoconductive layer 18, which is scanned by the electron beam 19. The disc 20 ka ^ n e.g. viewed from the front, rectangular or hexagonal or any other suitable ^ m to have"

S 2 ^ Ji 5 ans grüche - 9 -

Claims (1)

BR-iNG. HANS-DISTRICH ZELLER 2000 HAMBURG 1, May 21, 1969 __. . "Mönckebergstrasse 7 ^ r / _i PatwtamaH Phone: 339221 Telegraph: 23Β »ΰΧ fyfoffigX ^ 2-16 24 ^ S A., j d H 18 288 / 21a Gbm My files: PHN 1201 NV Philips ¹ Gloeilampenfabrioken - Q _ Claims for protection: 1. Television to convert an image generating Radiation in the self-^ oaren part of the spectrum into electrical Signals with a translucent front wall made of glass, on the inner surface of which a photosensitive layer is applied is characterized by the presence of a body of translucent solid material that is exposed to the The outer surface of this end wall is cemented and in the projection a significant part of this photosensitive Layer covered, this body being provided on the periphery with a light-absorbing material, while the total thickness the end wall and the body is so large that light that passes through this body and this end wall into the Tube enters and is reflected on the photosensitive layer if it is at angles that are different from the critical angle approach the total reflection, falls on the surface of this body facing away from the front wall, on this in such a way Directions that it is reflected by the peripheral surface of the body is intercepted. 2. TV recording tube according to claim 1, characterized in that the body on the outer surface of the glass End wall of a tube of the Vidicon type is cemented, this tube on the inner surface of this end wall with a photoconductive layer is provided which consists v / esönt- loan AUC Tetragons' ¹ em> red lead oxide, and shows in normal daylight an orange-red appearance. 5. television recording oil according to claim 1 or 2, characterized in that the peripheral surface of the body is slightly roughened so that before the light absorbing material is applied to it, it has a matted appearance shows. 4. Television pick-up tube according to one of the preceding claims, characterized in that that of the mentioned The surface of the body facing away from the glass front wall is provided with a reflection-reducing tension. 5. television pickup tube according to claim 1, characterized by a substantially circular light-permeable glass end wall, which is verseh.en on the inner surface with a light-permeable conductive electrode, on which a substantially consisting of lead oxide photoconductive layer is deposited, the end wall of this facing away surface of this photoconductive layer can be scanned by means of an electron beam generated by an electron gun mounted in the tube, while on the outer surface of this end wall in a central position a transparent, essentially circular disc is cemented, which is made of a glass with a refractive index of about 1 , 5 and has a diameter which is not smaller than two thirds of the diameter of the mentioned inner surface of the end wall, wbei the circumferential surface of this disk and the Te-I of the outer surface of the end wall, which is not through this "- ^ _P : Lfo _e is covered with a layer of a iiuhtauSör- uie ^^ ii Material are coated while the 3e3arr.tdickness of the style wall and the disk is at least one third the diameter of the disk.